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thesis entitled

PHOTOIONIZATION MASS SPECTROMETRY:
IONIZATION AND FRAGMENTATION OF

CH3CN AND CDBCN

presented by

David M. Rider

has been accepted towards fulfillment
of the requirements for

Ph . D . degree in Chemistry

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Date February 11, 1980

 

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PHOTOIONIZATION MASS SPECTROMETRY:
IONIZATION AND FRAGMENTATION OF

CH3CN AND CD3CN

BY

David M. Rider

A DISSERTATION

submitted to
Michigan State University
in partial fulfillment of the requirements

for the degree of

DOCTOR OF PHILOSOPHY

Department of Chemistry

1980

‘4‘.

‘f‘

L? //’Ll:‘

ABSTRACT
PHOTOIONIZATION MASS SPECTROMETRY:

IONIZATION AND FRAGMENTATION OF

CH3CN and CD3CN

BY

David M. Rider

Photoionization mass spectrometry (PIMS) is a powerful
technique for investigating ionization processes and fragmenta-
tion of molecular ions. Accurate ionization and fragment ion
appearance potentials can often be determined and ion frag-
mentation pathways and mechanisms elucidated. In this disser-
tation a PIMS investigation of acetonitrile (CH3CN) and
acetonitrile-d3(CD3CN) is reported.

Photoionization of acetonitrile with 5843 (21.2 eV)
photons causes extensive fragmentation of the parent ion. The

following ions are produced with sufficient intensity to be

+
2 2 2 3

Photoionization efficiency (PIE) curves of these ions and

studied: CH3CN+, CH CN+, HC N+, H CN+, CH , and CH2+.

their deuterated counterparts from the onset of ionization
(~1016 A, 12.2 eV) to 600 R (20.7 eV) have been measured.

The parent ion PIE curves (CHBCN+ and CD3CN+)demonstrate
that direct ionization and autoionization both contribute to
the production of ions in the region studied. Autoionizing
Rydberg series converging to the first and second excited

electronic states of the parent ions are observed and assigned.

David M. Rider

Jahn-Teller interactions in the ground state of the parent
ion are indicated by the observation of the threshold for one
quantum of excitation of the doubly-degenerate CCN bending
mode (v8). The measured ionization potentials are
12.194 1 0.005 eV for CH3CN and 12.235 i 0.005 eV for CD3CN.
Appearance potentials for the fragment ions listed above
are determined, and where a more reliable heat of formation
is not available in the literature,one is calculated. At
their thresholds CHZCN+ and CDZCN+ are found to be produced
exclusively from parent ion states which are populated by
autoionization. The experimental appearance potentials and
relative intensities of the remaining fragment ions indicate

that H-atom migrations in the parent ion are important in

the fragmentation mechanisms.

To Sasha

ACKNOWLEDGMENTS

Words are not sufficient to express my thanks and grati-
tude for help from the many individuals who made the completion
of this dissertation possible. First and foremost I thank my
wife, Sasha, for her loving care, devotion, and understanding
throughout our stay at Michigan State University.

I thank Professor G. E. Leroi for his guidance, encourage-
ment and patience as my advisor and for his perspective on the
human aspects of research.

Dr. Edward Darland's contributions were unmeasurable. He
was always willing to help solve instrumental problems and was
a wonderful teacher and friend. I also want to acknowledge
his help in generating several of the computer-drawn figures
in this thesis.

Naomi Hack I thank for many stimulating discussions about
nonscientific things, for her willingness to listen and her
outlook which helped to keep problems in perspective.

Marty Rabb was a tremendous help in solving electronic
problems. He was always willing to listen and provided many
useful suggestions.

The support of Ron Haas, Scott Sanderson, Steve Veile and
Dick Johnson of the electronic shop, and Russ Geyer, Len Eisele,
'Dick Menke and Deak Watters of the machine shop is gratefully
acknowledged.

Rose Manlove I thank for the thankless job of typing the

thesis.

iii

Financial support from the Office of Naval Research, the
National Science Foundation and the General Electric Co. are

gratefully acknowledged.

iv

LIST OF

LIST OF

CHAPTER

CHAPTER

A.

B.

TABLE OF CONTENTS

TABLES. . . . . . . . . . .
FIGURES . . . . . . . . .

I. INTRODUCTION. . . . . .
II. AN OVERVIEW OF PIMS . .
The PIMS Experiment . . . .
Photoionization Processes

1. Direct Ionization . . .
2. Autoionization. . . .

Fragmentation Processes . .
1. Small Molecules . . . .

2. Statistical Theory of
Mass Spectra. . . . . .

Complementary Experimental
Techniques. . . . . . . . .

1. Photoelectron Spectroscopy.

2. Electron Impact Energy
Loss Spectroscopy . . .

CHAPTER III . EXPERIMENTAL APPARATUS

A.

B.

AND PROCEDURES. . . . .
Introduction. . . . . . . .
The Instrument. . . . . . .
1. Light Source. . . . . .
2. Monochromator . . . . .
3. Ionization Region . . .

4. Mass Spectrometer and
Ion Optics. . . . . . .

V

Page No.
- vii
- viii
. . 1
. 4
. 6
. . 10
. . 10
. . 20
. . 28
. . 29
. . 31
. . 39
. . 40
. . 41
. . 44
. . 44
. . 44
. . 44
. . 56
. . 58
. . 58

Page No.

5. Ion and Photon Transducers. . . . . . . . . . 59

6. Vacuum System . . . . . . . . . . . . . . . . 61

7. Data Collection . . . . . . . . . . . . . . . 62

C. Experimental Details. . . . . . . . . . . . . . . 59

1. Samples . . . . . . . . . . . . . . . . . . . 63

CHAPTER IV. RESULTS AND DISCUSSION. . . . . . . . . . . . 66
A. Previous Studies. . . . . . . . . . . . . . . . . 66

B. The Photoelectron Spectrum. . . . . . . . . . . . 66

C. The Photoionization Mass

Spectra of CH3CN and CD3CN. . . . . . . . . . . . 71

D. Parent Ion Curves . . . . . . . . . . . . . . . . 75

1. General Observations. . . . . . . . . . . . . 75

2. Autoionization Structure:
1040 — 940 R. . . . . . . . . . . . . . . . . 80

3. Autoionization: 900 - 800 A . . . . . . . . . 92

4. The Threshold Region:
1000 - 1040 A . . . . . . . . . . . . . . . . 97

E. Fragment Ion PIE Curves . . . . . . . . . . . . .113

1. CHZCN+, CD2CN+. . . . . . . . . . . . . . . .116

2. CHCN+, CDCN+. . . . . . . . . . . . . . . . .121
+ +

3. CH2 , CD2 . . . . . . . . . . . . . . . .125
+ +

4. CH3 , CD3 . . . . . . . . . . . . . . . . . .128
+ +

5. HZCN 'DZCN . . . . . . . . . . . . . . . . .134

CHAPTER V. CONCLUSIONS AND SUGGESTIONS
FOR FURTHER WORK. . . . . . . . . . . . . . .140

APPENDIX A. DIGITAL MASS SCANNER. . . . . . . . . . . . .145

LIST OF REFERENCES. . . . . . . . . . . . . . . . . . . .162

vi

LIST OF TABLES

Page No.

11-1. Photoionization Processes. . . . . . . . . . . . . ll
IV-l. Vibrational Modes and Frequencies

of CH3CN+ and CD3CN+ Excited in

the Photoelectron Spectra Compared

to the Frequencies of the Neutral. . . . . . . . . 69
IV-2. CH3CN and CD3CN Photoionization

Mass Spectra . . . . . . . . . . . . . . . . . . . 73
IV-3. Rydberg Series Converging to the

First Excited State of CH3CN+ and

CD3CN+......................84
IV-4. Rydberg Series Converging

to the Second Excited State of

CH3CN+...........-..........96
IV-S. First Ionization Potentials of

CH3CN and CD3CN. . . . . . . . . . . . . . . . . .107
IV-6. Heats of Formation of some Neutral

Species and some Useful Conversion

Factors. . . . . . . . . . . . . . . . . . . . . .117
IV-7. Calculation of AHfO of CHZCN+ and

CD2CN+ . . . . . . . . . . . . . . . . . . . . . .122
IV-8. Summary of Appearance Potentials

and Heats of Formation . . . . . . . . . . . . . .139

vii

II-l.

11-2.

11-3.

III-1.

III-2.

III-3.

III-4.

IV-1.

IV-2.

IV-3.

IV-4.

IV-5.
IV-6.

IV-7.

IV-8.

IV-9.

IV-lO.

IV-ll.

LIST OF FIGURES

Block Diagram of a Photoionization
Mass Spectrometer . . . . . . . .

Effect of the Franck-Condon Factor
on Direct Ionization Thresholds of
Diatomic Molecules. . . . . . .
Krypton PIE Curve . . . .

The MSU PIMS Instrument . .

Rare Gas Lamp High Power Switching
Circuit I O O O O O O O O O O O 0

Spectral Distribution of The Helium
Continuum and Hydrogen Pseudo-continuum

Lamps . . . . . . . . . . . . .

Channeltron (CEM 4816) Wiring Diagrams

for Positive and Negative Ions. .

Photoelectron Spectrum of CH3CN

21.2 eV Photoionization Mass Spectra

of CH3CN and CD3CN. . . . . . .
CH CN+ and CD3CN+ PIE Curves:

603 - 1040 A. . . . . . . . .
Total PIE of CH3CN. . . . . . . .

CH3CN+ PIE Curve: 940 - 1040 A.

CD3CN+ PIE Curve: 940 - 1040 8.
Transition Energy Diagram for
Excitation from the 5al Orbital .

CH CN+ and CD3CN+ PIE Curves:
80 - 900 A . . . . . . . . . .

CH CN+ and CD3CN+ PIE Curves:
1000 - 1040 A . . . . . . . . . .

The Effects of a Triangular-Slit
Function on a Step Function . .

Integration of a Gaussian
Transition Probability. . . . . .

viii

Page No.

15

27

. . 67

72

76

81

93

. olOl

. .104

IV-12.

IV-l3.

IV-14.

Fit of the CH CN+ and CD CN+

PIE ThreShOldgo C O . . § 0 O C O C O
CHZCN+ and CD CN+

2
PIE Curves. . . . . . . . . . . . .

CHCN+ and CDCN+ PIE Curves. . . . .

CH2+ and CD2+ PIE Curves. . . . . .
+ +

CH3 and CD3 PIE Curves. . . . . .

H CN+ and D CN+ PIE Curves. . . .

2 2

Block Diagram of Digital Mass
Scanner . . . . . . . . . . . . . .

Scanner Computer Interface. . . . . .
Scanner Computer Interface. . . . . .
Computer Interface Board Layout . . .

Main Logic Board Opto-Isolator
Line Receivers. . . . . . . . . . . .

Main Logic Board Time Base Circuit.
Main Logic Board Scan Time Multiplier

Main Logic Board Twelve-Bit Counter
and Multiplexer Circuit . . . . . . .

Thumb Wheel Circuits. . . . . . . . .

Manual Control Circuits and
Counter Enable. . . . . . . . . . . .

Main Logic Board Layout . . . . . . .

Analog Circuit. . . . . . . . . . . .

ix

.105

.118

.123

126
.129

.135

.146
150
.151

.152

.153
.154

.155

.156

.157

158
.160
.161

CHAPTER I

INTRODUCTION

Although acetonitrile (CH CN) is a relatively small and

3
simple molecule, the ionization and consequent fragmentation
of CH3CN has not been accurately and completely studied. The
recent detection of acetonitrile in the comet Kohoutekl and in
interstellar space in the region of the constellation
Sagitarius2 has rekindled interest in its ion chemistry. Fur-
thermore, acetonitrile has been found in discharge chambers
simulating rare-earth conditions, suggesting that an investi-
gation of its ion chemistry might be relevant to an understand-
ing of abiogenic synthesis.3’4
A wide range of molecular species has been discovered in
interstellar clouds of gas and dust, and the question of how
these molecular species are synthesized remains unanswered.5
The temperatures of interstellar gas clouds are generally in
the range 4-25° K, and occasionally as high as 1000 K.6 At
these low temperatures most neutral-neutral reactions which
could account for the observed molecules proceed at negligible
rates due to kinetic reaction barriers. Reactions between ions
and molecules often have very low activation barriers, and it
has been suggested that many interstellar molecules are synthe-
sized via ion-molecule reactions. Interstellar gas clouds are

bathed in a flux of cosmic radiation which can account for the

presence of ions in these environments; a quantitative model

1

99 .
«Ha

2

based on ionization by cosmic radiation and subsequent ion-
molecule reactions has been proposed to account for many of
the observed molecules.7 Much of this model is based on the
thermochemistry of the species involved in possible ion-
molecule reactions, and for the theory to be further tested
there is a need for thermochemical parameters such as heats of
formation, bond dissociation energies, electron and proton
affinities, etc., of the relevant neutrals and ions.

Photoionization mass spectrometry (PIMS) has become a
viable experimental method in recent years.8 The most success-
ful and important application of the technique has been to
determine thermochemical parameters of ions. Indeed, PIMS is
generally recognized as the best and most accurate technique
for such investigations.9 With the above comments in mind,
acetonitrile was selected as a good candidate for a PIMS inves-
tigation.

PIMS is primarily a spectroscopic technique in which the
yield of ions from a sample gas is measured as a function of
ion mass and photon energy. Thus, relative photoionization
and fragmentation cross sections are measured, and they pro-
vide a wealth of information about the ions. Such quantities
as ionization and appearance potentials, vibrational and elec-
tronic energy level spacings, and relative rates of various
ionization and fragmentation processes can often be directly
determined from PIMS experiments. From these, thermochemical
parameters, fragmentation mechanisms and a variety of other
information can be deduced. PIMS, coupled with a few other

techniques, can often fully characterize molecular ionization

and fragmentation processes.

This thesis is a report of the photoionization mass spec-
trometry of acetonitrile. The objective was to learn as much
as possible about the photoionization and fragmentation of
this molecule, to derive thermochemical parameters where the
data merit such a calculation, and to elucidate fragmentation

pathways and mechanisms. The deuterated analog, CD CN, was

3
included to help in the analysis of the data and to determine
the isotopic dependence of various processes.

Chapter II of this thesis presents a general overview of
PIMS. It includes a brief description of the PIMS experiment
and contains a discussion of ionization and fragmentation
processes which are important in PIMS. The experimental
details of the acetonitrile experiments are presented in
Chapter III. This chapter also includes a brief description
of the MSU PIMS instrument along with a discussion of some of
the instrumental problems encountered during the course of
the investigation. The data are reported and discussed in

Chapter IV, and Chapter V provides a summary with conclusions

and suggestions for future experiments.

CHAPTER II

AN OVERVIEW OF PIMS

The experimental objective of PIMS is to measure the
yield of ions produced by the absorption of photons by a
neutral molecule, as a function of photon energy and ion mass.
Although the name PIMS emphasizes mass spectrometry, the more
important aspect of the experiment is the variation of the
photon energy. The experiments described in this thesis are
really vacuum ultraviolet absorption experiments in which the
mass spectrometer serves as a very special detector. The mass
spectrometer serves as a means for observing photon absorptions
that lead to the ejection of an electron from a molecule as
well as those absorptions in which sufficient energy is im—
parted to the ion to cause fragmentation.

A PIMS experiment,like other spectroscopic techniques, is
directed toward measuring transition energies, and the results
often allow one to infer properties of the initial and final
states. Due to the nature of photoionization processes, PIMS
often provides the most information about the ground states of
the ions; however, features in the spectra often yield informa-
tion about higher energy states, also. It is the purpose of
this chapter to present an overview of PIMS. Section A is a
brief description of the general experimental setup and is
followed by a discussion of photoionization processes in
Section B. Section C is a discussion of fragmentation of

4

polyatomic ions,and Section D is a very brief description of
photoelectron spectroscopy and electron impact energy loss
spectroscopy, two techniques which aid the interpretation of
PIMS data.

First reports describing mass spectrometric analysis of
ions produced by photoionization of gaseous samples were pub-
lished in 192910 and 1932.11 However, early investigators
were severely limited by the available vacuum and light source
technology, and only fairly recently has PIMS become a viable
experimental technique. In recent years it has been demon-
strated to be useful for the study of unimolecular reaction

kinetics of polyatomic ions?'12’13 the study of kinetics and

13,14,15

thermodynamics of ion-molecule reactions, and the

determination of ionization potentials of atoms and molecules

and of appearance potentials of fragment ions.8'9
Even though a wide variety of applications have been

found for PIMS, key references are somewhat scattered and in-

complete. No comprehensive reviews of PIMS have been published

since the one by Reid8 in 1971, which is now somewhat dated.

Nevertheless, that review, together with references 9,12,14,

16-19 , provide a useful introduction to the experimental

methodology of PIMS, photoionization and fragmentation

9,12,18-22 9,12,14

processes and applications of the technique.
Since the introduction to PIMS presented here is intention-
ally brief and is intended to serve only as a framework for

the discussion of the acetonitrile data, the reader is urged

to consult these references for more detailed information.

A. The PIMS Experiment

A block diagram of a photoionization mass spectrometer is
shown in Figure 11-1. The apparatus consists of a photon
source, photon monochromator, interaction region, ion optics
and mass spectrometer, and photon and ion detectors. The
output of the photon source is dispersed by the monochromator
and the output of the monochromator is passed through the
sample gas in the interaction region. The intensity of the
transmitted photons is converted to an electrical signal by
the photon detector. The ions are extracted at a right angle
to the photon beam with an electrostatic potential and are
focused onto the entrance of the mass spectrometer with
electrostatic ion lenses. The mass spectrometer allows ions
of only a single mass-to-charge ratio to impinge on the ion
detector, where the ion arrival rate is converted into an
electrical signal.

The experiment entails very simply the measurement of the
intensity of an ion of selected mass as a function of the
photon energy. Since the intensity of the available light
sources is not constant as a function of energy, the photon
intensity must also be measured so that the ion intensity can
be normalized. It would be most desirable to measure the
absolute photoionization cross section, but this quantity is
difficult to determine because then the absolute photon
intensity and the number density of neutral molecules in the

photon beam must be known. Instead, a relative quantity, the

 

I

 

SAMPLE

 

PHOTON
SOURCE

 

 

 

NONOCHRONATOR

 

 

 

 

 

INTERACTION

ooooooé)

 

”L .62"...

ION OPTICS
AND

NASS
SPECTROMETER

 

 

PHOTON
DETECTOR

 

 

 

 

 

ooooooé)

 

ION
DETECTOR

ION
\.

 

 

 

 

 

Figure

TON
NAL

WW
“I
GO

 

II-l. Block Diagram of a Photoionization

Mass Spectrometer.

/'
SIGNAL

photoionization efficiency (PIE), defined as:

 

= ion intensity (E) (II-1)
transmitted photon intensity(E) '

PIE(E)
is calculated. Although properly the incident photon inten-
sity should be used to calculate the PIE, under typical
operating conditions (low sample pressure) the amount of light
absorbed by the sample is sufficiently small that the PIE
calculated from the above relationship is directly propor-
tional to the partial photoionization cross section of the
ion being observed.23 The plot of the PIE of an ion as a
function of photon wavelength or energy is referred to as the
PIE curve.

The study of photoionization processes is experimentally
difficult due to limitations imposed by experimental technology
and the nature of the fundamental photoionization processes.
The most severe difficulties arise because of the region of
the electromagnetic spectrum in which the transitions of
interest lie. The lowest ionization potential of most atoms
and molecules is greater than 8 eV.,and therefore one is re-
quired to work in the vacuum ultraviolet region (VUV)
(2000-300 A). First of all, most substances, including oxygen
and nitrogen, absorb strongly in this region and as a result
the optical path must be maintained at pressures less than
10-5 torr. This in itself is not a severe restriction, but
it is complicated by the absence of suitable optical window

materials in the VUV. Below the short wavelength cutoff of

lithium fluoride (~1050 R, or 11.8 eV) there are no known

window materials which can be used to isolate the lamp or
sample gas from the rest of the instrument. Since most VUV
light sources are electrical discharges in a gas, the lack of
a suitable window material requires the light sources to be
"isolated" from the rest of the apparatus via high speed
pumping.

The fact that most substances absorb strongly in the VUV
also means that reflectivities are low. The best available
optical substrates have reflectivities on the order of 15-30%
at 1000 A, so that every reflection employed to disperse or
focus the light throws away a large fraction of the incident
light. This problem is further complicated by the lack of
intense light sources. The best available light sources in
the VUV region have peak intensities of only about 108-1010
photon sec.l 3-1. Thus it is imperative that reflecting
surfaces be kept to a minimum; normally a single diffraction
grating is the sole optical element employed.

Another serious problem stems from the necessity to use
low sample pressures in order to avoid scattering of the ions
and reactive collisions of the ions with the sample gas; these
processes decrease the intensity of the ions and introduce
artifacts into the data. Most experiments must be performed
with sample pressures of less than 10-3 torr.

Low sample pressures coupled with low intensity light
sources and the low reflectivity of optical elements result

in low ion count rates. In favorable circumstances, ion count

rates may be several thousand per second, but they are often

10

as low as only a few ions per second. Fortunately, the utili-
zation of ion counting techniques and digital computers allows
sufficiently long integration times that useable data can

often be obtained with such weak signals, but only at the cost
of very long experiments. Data runs for a single ion may last

as long as several days!

B. Photoionization Processes

When molecules are irradiated with high-energy photons,
processes such as photoexcitation, photoionization or some
combination of the two may occur simultaneously to produce a
multitude of final states. In the following pages of this
section,those processes which result in an ion and are there-
fore important to PIMS are discussed. Section 3.1 deals with
direct ionization and Section B.2 with autoionization.
Sections 8.3 and B.4 provide a discussion of fragmentation of
molecular ions resulting from photoexcitation of neutral
molecules. These processes are summarized in Table 11-1.

1. Direct Ionization

Irradiation of molecules with visible and ultraviolet

light may induce transitions of valence electrons to the
lowest excited states of the molecule. As the energy of the
radiation is increased,transitions to higher excited states
of the molecule become energetically possible and eventually
an energy is reached at which the excited valence electron is
no longer bound by the potential of the nuclei. The final

state is then described as the product of a quantized state

Table 11-1.

11

Photoionization Processes.

 

 

AB

AB

AB

AB

AB

AB+ + e'

+ -
AB* + AB + e
A++B+e-

+ —
AB* + A + B + e

.4. _
AB*+e + A+ + B + e

Direct ionization
Autoionization

Direct dissociation

Predissociation

 

12

of an ion core and a continuum state of a free electron. As
the radiation energy is further increased the molecules con-
tinue to absorb, leaving the ion in the same final state with
the electron carrying away the excess energy as kinetic energy.
The absorption is continuous. Further increasing the radi-
ation energy may make transitions to excited states of the ion
possible; the free electrons will be produced with a distri-
bution of energies, where the distribution will reflect the
difference in energy between that required to reach the final
states of the ion and the radiation energy. Transitions to
the various final states of an ion will occur simultaneously.
This is direct ionization.

Direct ionization is exactly analogous to an ordinary one-
electron transition observed in the visible or ultraviolet
region of the spectrum, except for the one important difference
that the electron is excited into a continuum state instead of
a bound state. The probability of direct photoionization is
proportional to the square of the dipole transition moment

integral:22
2 - 2
M =|<wf|n|wi>1 (II-2)

where fl is the dipole moment operator, 43 is the wave function
of the initial state of the neutral molecule, and wfis the
wave function of the ion and the photoelectron. From the
Born-Oppenheimer approximation and the assumption that the
electronic parts of the wave functions change negligibly in

the time it takes for a transition to occur, one findszz'24

13

that

2 " 2 2
M = | <wfe|u|wie>l |< wfvlwiv>l ' (”‘3’

Here wfe and wie are the electronic parts of the final and
initial state wave functions respectively, and wfv and wiv
are the vibrational wave functions of the ion and the neutral
molecule. The wave function wfe describes both the ion and
the free electron and may be represented as a linear combina-
tion of two Slater determinants -- one for the ion and the
other for the free electron.25 Rotational motion is tacitly
neglected since the experimental conditions required in PIMS
are generally insufficient to resolve rotational structure in
direct ionization, and the integrals of equation (II-3) are
to a good approximation independent of rotation.22
Qualitatively it is found, both theoretically26 and

experimentally,18 that the electronic part of (II-3),

I< ll’fe Ifilwie> I2, rises sharply to a maximum at the
ionization threshold and decreases to small values for exci-
tation energies much greater than threshold. In the region
accessible to PIMS ( 20 eV) the decrease is usually less than
50% of the maximum at threshold. Near the ionization
threshold -- up to one or two eV above -- the photoionization
cross section can usually be taken as a step-function which

27'28 However, as pointed out by

is constant above threshold.
Rosenstock,9 there is no guarantee that the range of validity
of this assumption is this large.

If one neglects the vibrational part of equation (II-3)

14

and considers a system in which several electronic states are
available, the photoionization cross section or PIE curve
would be a series of steps, each step corresponding to the
threshold for an ionic state. All ionic states with a thresh-
old energy less than a given photon energy will be populated
at a rate proportional to the cross section at that photon
energy. In the absence of competing indirect processes this
step-like behavior is indeed observed for atoms (see reference
18 for examples).

The vibrational part of equation (II-3) is the well-known
Franck-Condon factor. It is simply the overlap between the
vibrational wave function of the neutral molecule (wvi) and
that of the ion (va). The effect of the Franck-Condon factor
on the photoionization cross section is to attenuate the
electronic factor and to introduce additional step-like struc-
ture to the PIE curves. The threshold for an electronic state
of a molecular ion becomes a series of steps, where each step
represents a threshold for a different vibrational state.

The height of each vibrational step above the previous step
is proportional to the Franck-Condon factor for the corres-
ponding transition.

The overall shapes of the electronic thresholds can be
quite varied, depending on the differences in the bond lengths
between the neutral and the ion. This is shown pictorially
for a diatomic molecule in figure II-2. If the electron is
removed from a non-bonding orbital the interatomic distance

of the neutral and the ion will be nearly the same, and

15

  

 

 

 

 

/
I
I
I
\
> \ I
0 l/ \ ’ I ’
I / I
‘i’ I \/
2 M, = 012156 am y. = own an. r. = 0.14002 mu
:
2
3 \K////
v. = 0.1207: m.
1 1 L L 1 1 1 1 1 1
01° OJ? 0.“ 0 I0 0.12 0.14 0.30 012 01‘ 0J6 0.1.
c, an
42*
C
:8 2
:5:
‘Utb . I'll ,,...0lo ......
OI OlIJOS OIIICSOYOQlOHIII)
cl
3 l
)-

ENERGY

Figure 11-2. Effect of the Franck-Condon Factor on Direct
Ionization Thresholds of Diatomic Molecules
(from Reference 9.)

16

essentially only the ion vibrational ground state will be
accessible from the neutral ground state. The threshold for
the electronic state of the ion would be only a single step.
If the electron is removed from an orbital which is slightly
bonding or antibonding, in which case the internuclear distance
in the ion is a little greater or smaller than that of the
neutral, additional ion vibrational levels become accessible
and a vibrational progression will be observed, with an
intense (0 + 0) transition and progressively less intense
transitions to the higher vibrational levels. The threshold
will resemble a staircase with a large first step and progres-
sively shorter steps to higher energy. If the electron is
removed from an orbital which is strongly bonding or antibond-
ing the internuclear distance in the ion will be significantly
greater or smaller than that of the neutral and the (0 + 0)
transition may no longer be accessible. The threshold region
will exhibit a long progression of vibrational steps. The
Franck-Condon factor has the same effect for polyatomic mole-
cules except that many bond lengths may change and the thresh-
olds may be overlapping progressions of steps if more than

one vibrational mode of the ion is excited. The structure may
be very complicated. In the absence of competing processes
this step-like structure is often observed in the threshold

region of parent ion PIE curves. The PIE curves for NO,29

HCCH,3O and NH331 are good examples.

Resolved vibrational steps provide useful information

about the vibrational structure of the ion, and about the

17

orbital of the neutral molecule from which the electron is
removed. The energy spacings of vibrational steps are a
direct measure of the vibrational spacing of the excited
vibrational modes of the ion, and from them the excited modes
can often be identified. From the assignment of the excited
vibrational modes, the heights of the vibrational steps, and
the overall shapes of the vibrational progressions, deductions
can be made about the bonding characteristics of the orbital
from which the electron is removed and the geometry of the ion.

Although individual rotational transitions within a
vibronic photoionization transition are not resolved, they do
affect the direct ionization cross section curve shape by
producing some tailing at the onset of a vibronic step and
rounding of the top of the step. This is a result of the
spread of threshold energies of the individual rotational
transitions. The exact shape of the steps depends on the
thermal distribution of populated rotational states of the
neutral, the differences in the moment of inertia of the
neutral and the ion, and rotational selection rules.

The electronic selection rules for direct photoioniza-
tion are very much simplified compared to those for absorp-
tion and emission between two bound states. The most impor-
tant and most common direct photoionization transitions are
one-electron processes, and they are restricted by the usual
dipole selection rules. However, the final state of the
system is an ion plus a free electron,and the free electron

can carry away whatever angular momentum is needed to satisfy

18

the dipole selection rules. As a result all one-electron
direct photoionization dipole transitions are allowed.21’22
When spin-orbit interactions are small, the spin selection

21’22 The electron

rule AS=0 can also always be fulfilled.
spin of the final state of the system is the sum of the spin
of the ion and the spin of the free electron. The free elec-
tron can always leave the molecule with the spin it had in
the neutral so that AS=0. Most neutral molecule ground states
are singlets, and since the spin of a free electron is 1%, the
most common ionic states are doublets. The most common direct
photoionization transitions occur from singlet molecular
ground states to doublet states of the positive ion.22

The vibrational part of equation (II-3), the Franck-Condon
factor, puts some restrictions on the allowed vibrational
transitions within a direct photoionization transition. In
order for the Franck-Condon factor to be non-zero, the inte-
grand (vawiv) must be totally symmetric in the point group

21'22'24 The vibrationless

to which the molecule belongs.
ground state of a molecule is always totally symmetric and
therefore only totally symmetric vibrational modes of the ion
can be reached by direct photoionization. The ground vibra-
tionless states of the ion are likewise totally symmetric and
the (0 + 0) transition is always allowed. The vibrational

' wave functions of symmetric vibrational modes are totally
symmetric regardless of the vibrational quantum number, so
excitation of such modes is allowed with any number of quanta.

Antisymmetric modes are antisymmetric for odd and symmetric for

even vibrational quantum numbers, and such modes can be

19

excited in direct photoionization only in units of two quanta.

For polyatomic molecules belonging to point groups for
which the normal modes are not just symmetric and antisymmet-
ric, the vibrational selection rules must be determined by
the direct product of the symmetry species of the initial and
final vibrational levels. This product must contain the
totally symmetric representation for the transition to be
allowed. One still finds, when the neutral is in the ground
vibrational level, that for all point groups the transition
to the ground vibrational level of the ion is allowed. Also
totally symmetric modes can be excited with any number of
quanta and the single excitation of a single non-totally
symmetric mode is 33233 allowed. The allowedness of multiple
excitations and combinations of non-totally symmetric modes
must be determined by using the direct product.

Often one is most interested in measuring the energy of
the transition from the ground vibrational state of the neutral
to the ground vibrational state of the ion (the adiabatic
ionization potential). Although this transition is always
allowed by symmetry, there is no guarantee that it will be
observed in direct ionization. For a transition to be
observed not only must it be allowed by symmetry, but there
must also be overlap between the vibrational wave functions
of the initial and final states. Photoionization of N0232
is a good example of a case where, because of a large
geometry change, the ground vibrational state of the lowest
electronic state of the ion is not populated by direct ioniza-

tion.

20

2. Autoionization
Autoionization, in contrast to direct ionization, is

a two-step process. Molecules have bound, neutral states
corresponding to excitation of electrons of lower energy (more
tightly bound) than those in the highest occupied orbital.
Many of these excited states lie above the lowest ionization
potential of a molecule, and if they are populated by absorp-
tion of radiation they may interact with the continuum states
lying above the first ionization potential, leading to ejec-
tion of an electron. This is autoionization -- the absorption
of a photon to produce an intermediate, highly-excited discrete
state of the neutral which ejects an electron to form an ion.

Since radiation is absorbed in a transition to a discrete
state of the neutral, autoionization is a resonant process
and ions will be produced only at the energy of the transi-
tion. Autoionization will often appear as a sharp, peak-like
structure superimposed on the normally featureless direct
ionization continuum. However, autoionization exhibits a
great variety of asymmetrical line shapes and may appear as a
"window resonance" in which there is a decrease or dip in the
18,33,34 41

(e.g. see the COZPIE. )

The lifetimes of autoionizing levels can vary a great deal,
14

photoionization cross section,
ranging from ~10- seconds all the way to ~10.6 seconds;9

for states with short lifetimes, the autoionization structure
may be so broadened that it is indistinguishable from the con-
tinuum for direct ionization. Autoionization structure on a

PIE curve may also be broadened by emission and/or by

21

predissociation into neutral fragments, in which case it may
also be indistinguishable from the continuum.

Autoionization can occur from valence states lying above
the lowest ionization potential of a molecule, but generally
it originates from Rydberg states that are members of series
converging to the second, third and higher ionization poten-
tials of the molecule. The distinction between Rydberg
states and valence states is not always clear, but in the
molecular orbital framework, molecular Rydberg orbitals can
be thought of as being formed from atomic orbitals with
larger principal quantum numbers than those used to calculate

the valence shell orbitals.33

Being composed of atomic
orbitals of high principal quantum numbers, Rydberg orbitals
have a large spatial extent and in a somewhat naive but useful
approximation Rydberg states can be considered as a one-elec—
tron system in which the electron in the Rydberg orbital is
at so large a distance from the remaining ion core that the
core appears as a point charge (H-like atom.)33
The above picture is reinforced by the fact that nearly
all transitions to Rydberg states(visib1e in PIMS experiments
as autoionization structure) can be fit to a series described
by the Rydberg equation:

R

E = IP - ——z . (II-4)
hv (n-d)
Here Ehv is the energy difference of the transition and IP is

the ionization potential of the molecule to which the series

converges as n, referred to as the principal quantum number,

22

runs serially to<n. R is the Rydberg constant (13.605 eV),
and 6 is called the quantum defect, which is essentially a
fudge factor which accounts for penetration of the Rydberg
orbital into the ion core.

Molecular Rydberg orbitals of the same n but different
orbital angular momentum will, in general, not penetrate the
ion core to the same extent and will be split into components
of differing 6. The general rule for molecules composed of
second row atoms is that ns orbitals are highly penetrating
and require a 6 of about 1, np orbitals are less penetrating
and so have values of 6 near 0.6, and nd orbitals are nearly
nonpenetrating and have 6 very close to zero.33’35

The ion core of a molecule with an electron in a Rydberg
state will never appear as a spherical charge distribution to
the Rydberg electron, and this dissemmetry of the ion core may
cause further splitting of degenerate Rydberg orbitals of a
given orbital angular momentum. For example, an np Rydberg

orbital for which the ion core has C symmetry may be split

2v
Into A1 (pz), Bl (px), and 82 (py) components due to a d1f—
ference in the penetration of the Rydberg electron for dif-
ferent orientations of the Rydberg orbital with respect to
the ion core. Such a splitting is indeed observed in the

36,37

lowest 3p Rydberg state of H O.

2
For linear molecules, where the component of the orbital
angular momentum directed along the molecular axis is

quantized, Rydberg orbitals are conveniently labeled with the

quantum numbers (n11) (e.g. 4pn). Although the meaning of A

23

becomes ambiguous, the same terminology is often used for
non-linear molecules which are linear when hydrogens are
excluded (e.g. CH3C1). In this case 1 refers to the orienta-
tion of the Rydberg orbital to the remaining molecular frame—
work. In other molecules the Rydberg orbitals are labeled
with n and the symmetry species of the orbital in the symmetry
group of the molecule.

Fano,38 and Fano and Cooper34 have presented a theoretical
treatment of autoionization in atoms which has been extended
to molecules by Berry.39 Their findings lead to several
important conclusions. For atoms only Rydberg states lying
above the ground state of the ion can autoionize and therefore
be observed by PIMS. These Rydberg states will be members of

series converging to excited states of the ion. It is found

that the average absorption coefficient of these Rydberg

series converges smoothly into the direct ionization continuum.
That is, there will be no discontinuity on a PIE at the thresh-
olds for excited states of atomic ions as there would be if
direct ionization was the only process contributing to the

10,34 However: if the Rydberg

photoionization cross section.
series are well resolved, one can determine the convergence
limit of a series by fitting the series members to the Rydberg

formula (equation 11-4) and solving for IP.

For molecules the situation is fundamentally the same:
the average absorption coefficient for Rydberg series conver-

ges smoothly into that of the continuum and no discontinuity

24

will be observed in the absorption cross section at the limit

10’39 However, in molecules there may be several

of a series.
possible channels for the release of the energy contained in
the highly excited Rydberg state other than autoionization.
Predissociation into neutrals is often energetically possible
at photon energies above the lowest IP of a molecule, and if
a sufficient number of Rydberg states decay by this channel
not all absorptions will lead to autoionization and a dis—
cintinuity may well be observed in the PIE curve at the con-
vergence limit of a series. The threshold for excited states
of the ion may be directly observable.lo

An interesting and important conclusion from the work of
Berry39 is that there are several possible modes of auto-
ionization from molecular Rydberg states. One mode, electronic
autoionization, is possible only when the total electronic
energy of a Rydberg state is greater than the lowest ioniza-
tion potential of a molecule. In this case the electron in
the Rydberg orbital was promoted from a ground state orbital
lower in energy than the highest occupied ground state orbital.
Autoionization occurs when the ion core of the Rydberg state
relaxes to a lower energy configuration. The perturbation
causing the relaxation and the subsequent ejection of the
Rydberg electron is electron-electron repulsion.39

A Rydberg state in which the molecule-ion core is vibra-
tionally excited may eject the Rydberg electron by vibrational

relaxation of the core. This is called vibrational autoioni-

zations, being caused by a coupling of the oscillating

25

multipoles of the ion core with those of the Rydberg electron.
The electronic energy of a Rydberg state undergoing vibrational
autoionization does not necessarily have to be greater than

the lowest IP of the molecule; it is only necessary that the
sum of the vibrational and electronic energy be greater than
the lowest IP. It is interesting to note that vibrational
autoionization, which is believed to be the predominant

39’40 constitutes a breakdown of

mechanism in small molecules,
the Born-Oppenheimer approximation.

Autoionization may also be induced by the relaxation of a
rotationally excited ion core. Rotational autoionization
arises from the coupling of the rotational angular momentum
of the ion core with the orbital angular momentum of the
Rydberg electron. The role of rotational contributions to
autoionization is not well understood due to the paucity of
experimental data where rotational structures can be resolved.

All parent ion PIE curves contain contributions from both
direct ionization and autoionization. In cases where Rydberg
transitions are broadened by very fast autoionizing rates,
predissociation into neutrals, or spontaneous emission of
photons, autoionization may be indistinguishable from the
direct ionization continuum. In fact, it has been recently
proposed that direct ionization be theoretically treated as
very fast autoionization.42 The PIE curves of diatomic
molecules, where few channels for predissociation may be open,

are often dominated by autoionization (e.g. H2,40 02,43

44

N2 ),

26

However, for larger polyatomic molecules, where several
channels for predissociation are often open and many changes
in geometry are possible, PIE curves are often featureless,
showing only hints of autoionization (e.g. dimethyl ether45

and the halogenated methaneslg’46

).

Many of the general ideas discussed in this section and
the preceeding one are nicely demonstrated in the (essentially
ideal) rare gas atom PIE curves. The PIE curve of krypton is
shown in Figure 11-3. The ground state of Kr+ corresponds

to the removal of a 4p electron from the neutral atom and is

spin-orbit split into 2P3/2 and ZPl/2 levels. The threshold

for the 2P3/2 level at 885.6 2 (14.00 eV) is quite sharp, and
above this threshold are two Rydberg series converging to the
2

Pl/Z level. Only the lowest two members of the two series
are resolved in Figure II-3. The odd line shapes that are
often exhibited in autoionization are demonstrated in the
Kr+ PIE curve by the first two peaks. The decrease in the PIE

just above the 2P threshold (884 A) is actually part of

3/2
the 6d line, as is the sigmoidal decrease of intensity
(871-879 A) on the high energy side of the 6d line. The two
Rydberg series join smoothly onto the continuum of the 2Pl/2
level of the ion and the threshold for this level (845.4 8,
14.67 eV) is several Angstroms beyond where the PIE appears

to become continuous. (The threshold for the 2P level is

1/2
indicated with the arrow in Figure II-3.) The PIE is rela-

tively constant beyond the series limit.

.m>uso mHm :oummux .mIHH ouswflm

 

 

27

 

 

 

 

 

 

 

 

 

a:
00m 0mm 00m 0V0 ONQ Com
_ _ _ _ _
mawxw

.H.
“3*, w:

nu

1. I
B m .. s so._.... ...
m: .o m o.. ...«._m_._. mo

 

28

C. Fragmentation Processes

Fragmentation processes can be very complex, and therefore
they are often more difficult to analyze on a detailed level
than direct ionization or autoionization. As an example, con-
sider the four-atomic molecule, ABCD. When a parent ion is
detected, the overall process: ABCD + hv + ABCD+ + e- has
occurred. The energy of the photon (hv) is precisely deter-
mined by the monochromator setting, and the internal energy of
the parent ion is easily calculated by subtracting the elec-
tron's kinetic energy from the photon energy. Thus, the
energetics and composition of the system are well character-
ized.

If the fragment ion A+ is detected, then

ABCD + hv + A+ + (BCD) + e-. The ion mass and photon

energy may be accurately measured and even the kinetic energy
of the electron can be measured, but this is only part of the
system. The neutral fragment or fragments are not detected
with PIMS and their composition may be uncertain (they could
be BCD, B+CD, BC+D or B+C+D). Moreover, the ion and the
neutral fragments may also carry away kinetic and internal
energy. The total system is thus not easily characterized
compositionally or energetically. The appearance potential
of the fragment ion, the lowest photon energy at which the
particular ion is detected, may well correspond to the produc-
tion of neutral and ionic species having significant internal
and kinetic energy, which are not simply related to the known

energies of the incident photon and ejected electron.

29

Fortunately, thermochemical information is often helpful in
reducing the complexity of the process; on this basis many
fragmentation pathways can be eliminated, and kinetic energy
releases can be estimated. However, accurate estimates require
accurate thermochemical data, which may not be available for
all species of the system.

1. Small molecules (diatomic or triatomic)

For small molecules it is often useful to consider
fragmentation as the result of processes which are directly
analogous to direct ionization and autoionization, where a
neutral molecule undergoes a transition (directly or indirectly)
to a repulsive potential energy surface or a repulsive region
of a bound potential energy surface of an ion.

Direct dissociation results from a direct transition to
a respulsive surface and follows the same principles as direct
ionization. The probability of the transition is determined
primarily by Franck-Condon overlap of the initial neutral
state and the continuous states of the unbound ionic surface.
Direct dissociation is very fast (on the order of a vibrational
period) and most of the excess energy will be carried away
as translational kinetic energy of the products.21 The
products may, however, be formed in excited electronic states
if the dissociative surface does not correlate with the ground
state of the ion.

Predissociation, sometimes referred to as preionization
or autoionization when ion fragments are formed, implies an

intermediate undissociated excited state. Two possibilities

30

arise:

Case (1). The intermediate state is an excited state of
the neutral that undergoes a further transition
to a repulsive surface of the molecular ion.
This is directly analogous to autoionization
as discussed in the previous section.

Case (2) The intermediate state is an undissociated
ionic state which undergoes a radiationless
transition to a repulsive ionic surface or
redistributes vibrational or rotational energy
such that energy in excess of a dissociation
limit ends up in a particular vibrational mode
or rotational degree of freedom. The bound
ionic state may be populated by direct ioniza-
tion or autoionization.

Although these two modes of predissociation are concep-
tually distinct, it is often not possible to separate them
experimentally. While peak-like structures in a parent ion
PIE curve is a sure indication of autoionization, the same
structure in a fragment ion PIE curve only means that a dis-
crete state of the neutral was populated on the pathway to
the ion fragment. The dissociation may have occurred by
Case (1) or Case (2) predissociation.

Whether predissociation occurs by Case (1) or Case (2),
the fragments may fly apart with a considerable amount of
vibrational or rotational energy since the intermediate state

. may be produced with internal excitation.12'14'24

32

discussion that follows is adapted from Forst.

In RRKM theory dissociation is treated as a vibrational
phenomenon. That is, dissociation will occur when sufficient
energy is available in a vibrational mode such that a bond is
extended beyond some critical value, leading to rupture. The
probability of dissociation is then the probability that at
least some critical amount of energy, the energy just needed
to rupture a particular bond, is found in that bond. The pri-
mary assumption of RRKM theory is that this probability is
purely statistical. It depends only on there being sufficient
vibrational energy available among all the normal modes of
the excited molecule, and the ratio of the number of ways
that the vibrational energy of a molecule can be distributed
to put at least the critical energy into the dissociating bond
to the total number of ways that the vibrational energy can be
distributed within the molecule. For the dissociation to
behave statistically, vibrational energy must flow freely and
randomly throughout the molecule.

RRKM theory considers energy randomization on only a single
potential energy surface. STMS makes a second important assump-
tion. STMS assumes also that electronic energy is freely and
randomly converted into internal energy of just one low-lying
state, usually the ground state of the ion (although it need
not be the ground state). The theoretical and experimental
evidence for and against randomization of electronic energy
is fully discussed by Forst48 and need not be repeated here;

it is concluded that in the great majority of cases the

33

assumption appears valid. In any case, the utility of STMS
lies in its ability to predict the general features of frag-
mentation of polyatomic molecular ions.

STMS implies that only Case (2),described above, pre-
dissociation, will be important. A dissociation is considered
to be a unimolecular reaction of a parent ion which is formed
with sufficient energy to enable the rupture of a bond. Fur-
thermore, time is required for the energy to flow into the
rupturable bond or bonds. Thus, STMS emphasizes the temporal
aspects of PIMS. The interaction region (the ion source) of
a photoionization mass spectrometer (or any mass spectrometer)
is located a fixed distance from the mass analyzer. Any
parent ion that fragments in the time it takes to travel from
the interaction region to the mass spectrometer will be detec-
ted as a fragment ion. The intensity of a fragment ion will
depend on the number of parent ions formed with energy above
the critical energy, the rate constant for the fragmentation
channel, and the flight time from the interaction region to
the mass analyzer. Some types of mass analyzers, e.g., mag—
netic sector and time-of—flight instruments, may allow one
to observe fragmentations that occur in the analyzer.

The rate constant (k(E)) for one channel of fragmentation

is given by:12'48

k (E) = 0 E < E , (II-5)

34

= aG*(E-Eo)
HN(E) for E 2 EO ,

k(E)
where k(E) is the rate constant at a total excitation energy E
(with respect to the ground state of the ion), N(E) is the
density of states at energy E, and G*(E-Eo) is the density of
states of the activated complex (i.e., essentially the parent
ion minus the fragmenting bond) integrated from the critical

energy, E to the excitation energy E. The constant a is

o'
of the order of magnitude unity and takes into account degen-
erate fragmentation channels due to the symmetry properties

of the dissociation, and h is Planck's constant. Note that
N(E) is essentially the number of ways that energy E can be
distributed in the molecular ion and G*(E-EO) is the sum of
all the ways that energy E can be distributed so as to leave
at least energy E0 in the dissociating bond.

Potential energy surfaces for dissociating ions rarely
have a reverse energy of activation. That is, a fragmenting
molecular ion usually does not pass over a hump in a potential
energy surface, but only over a ledge. This means that,in
general,fragments produced at the critical energy will be
formed with no internal or translational kinetic energy. If
a fragment ion is produced at a detectable rate at the criti-
cal energy (E0), then the appearance potential (AP) of the
fragment (the minimum photon energy at which the fragment is
detected, assuming the neutral is in its ground electronic,
vibrational and rotational state) will be at a photon energy

equal to the ionization potential of the neutral plus the

thermochemical threshold for the dissociation. Under these

35

conditions an accurate heat of formation can be calculated for
the fragment ion. For example, if AB + hv + A+ + B + e-
and AP = Aern, then AHf(A+) = AP(A+) + AHf(AB) - AHf(B).

Under what conditions will it be possible for the experi-
mental AP of a fragment ion to correspond to the thermochemical
threshold? There are several points to note. First, in a
PIMS experiment the PIE is measured at some fixed time after
the ionization (usually 10.5-10-6 5.9). Second, the rate
constant will have a non-zero value at the critical energy

given approximately by:12'51

1
k(EO) :h—NTEET . (II-6)

Third, in general,it is found that k(E) is a monotonically,
rapidly-increasing function of E above E0.12'51
Assume for the moment that parent ions are formed with

a suitable distribution of energy greater than the critical

energy for a dissociation such that the dissociation is not

limited by this factor. Three cases can be distinguished.

Case (1). k(EO) is sufficiently large that all or nearly

all parent ions formed with excitation energy
E 2 Eo will be dissociated within the flight
time to the mass analyzer. The rate at which
the fragment ions arrive at the mass analyzer
is then the rate at which the parent ions are
produced with internal energy greater than E0.
The dissociation rate constant will have no

effect on the shape of the fragment ion PIE.

In this case an accurate heat of formation of

Case (2):

Case (3):

36

the fragment ion can be determined from the AP.
k(EO) is not large enough for a detectable
number of fragment ions to be formed during

the flight time. Only at energies above E0
would the fragment ion be detected, and the PIE
would depend on k(E) and the rate at which the
parent ions are formed with internal energy
greater than BC. In general as the photon
energy (Ep) is reduced from Ep > E0 toward E0
the fragment ion PIE asymptotically approaches
zero. The apparent AP would lie at an energy
greater than the critical energy and would
serve as only an upper limit to the thermochemi-
cal threshold. The shift of the experimental
AP above the critical energy due to a low
fragmentation rate constant is often referred
to as the kinetic shift.

k(EO) is sufficiently large for a detectable
number of fragment ions to be produced at E0,
but this process competes with one or more
other fragmentation channels for which E0 is
lower. Since fragmentation rate constants in-
crease rapidly with energy, the rates for
channels of lower critical energy may well be
sufficiently fast at the critical energy of a
higher energy channel that all parent ions dis-

sociate by one of the lower energy pathways

37

and no parent ions survive sufficiently long to
dissociate by the newly-available pathway. As
EF is increased above E0 for this higher energy
pathway the rate constant will increase such
that it can compete with those for lower energy
channels, and the fragment will be detected.
The fragment ion PIE curve will be similar in
shape to those of ions falling in Case (2) and
the AP will yield only an upper limit for the
thermochemical threshold. The shift from the
thermochemical threshold of the measured AP
due to competition with other fragmentation
pathways is frequently referred to as the com-
petitive shift.

The quantity N(E) in equations 11-5 and 11-6 is a rapidly
increasing function of E48 and therefore k(EO) (equation II-6)
will be smaller the higher the critical energy and the more
likely it is that the corresponding fragmentation channel will
fall into Case (2). The function G*(E-Eo) is also a rapidly
increasing function of E (G*(E-EO) increases more rapidly than
N(E)48), and at a given energy a fragmentation channel with
a higher critical energy will in general have a smaller rate
constant than a dissociation with a lower critical energy.
This results because N(E) will be the same for both channels
whereas G*(E-EO) will be smaller for the higher critical energy
channel due to the smaller energy range for the integration

which determines G*(E-Eo). The lowest energy fragmentation

38

process is the one most likely to yield an accurate fragment
ion heat of formation. The APs of higher energy fragmentation
pathways are almost always shifted above the thermochemical
threshold due to kinetic and (more generally) competitive
shifts; they are useful only for determining upper limits for
the heat of formation of the fragment ions involved.12

To this point in the discussion, little has been said
about the rate at which the parent ions are produced. The
rate at which a fragment is detected can never exceed the
rate at which parent ions are produced with internal energy
above the critical energy for the fragmentation process. (The
rate at which a fragment is detected, however, may be greater
than the rate at which the parent ion is detected if the frag-
mentation is fast and more parent ions are produced with
internal energies above the relevant critical energy than
below it.) All fragment ion intensities are eventually
limited by this rate. Insufficient production of parent ions
with internal energy equal to the critical energy for a frag-
mentation channel could, like the kinetic effects, delay the
detection of a fragment ion until well above its thermochemical
threshold. Often this possibility can be eliminated from con-
sideration since many fragment APs are observed in regions
where states of the parent ion are known to be populated by
direct ionization and autoionization. However, when a fragment
ion AP coincides with the threshold of an upper state of the
parent ion this source of error should be considered.

Methane and ethane are good examples of smaller polyatomic

39

molecules that fragment as predicted by STMS. The PIE curves
of methane and its fragment ions can be found in Reference 52
and those of ethane in Reference 53 . In order to make a
comparison between the theoretical predictions of STMS and

the results of a PIMS experiment one would need to calculate
the rate constants for each fragmentation channel and to know
the distribution of internal energies in which the parent ions
are formed at a given photon energy. The calculation of the
rate constants is fairly straightforward and can be accom’

12'48 The more

plished with modest computational effort.
severe problem is the need to know the distribution of internal
energies with which the parent ions are formed. If direct
ionization is the predominate process and if the direct ioniza-
tion cross section approximates a step function, then an
estimation of this distribution can be made by taking the first
derivative with respect to photon energy of the total (parent

50

plus fragments) PIE. This approach was used by Chupka on

methane52 and ethane,53 and the results showed reasonable
agreement with theory. Most of the differences could be
attributed to contributions to the PIE by autoionization. The
agreement between theory and experiment was later confirmed

by Stockbauer54 in a threshold electron-photoion coincidence
experiment, where only fragments produced from parent ions

of known internal energy are detected.

D. Complementary Experimental Techniques

Since the results of a PIMS experiment depend on the

properties of the electronic and vibrational states of ions

40

and the properties of neutral states above the lowest ioniza-
tion potential of a molecule, other techniques which provide
information about these states often prove useful and comple-
mentary. Results from two of these techniques, photoelectron
spectroscopy (PBS) and electron impact energy loss spectroscopy
(EIELS), have been invaluable for interpreting the acetonitrile
PIMS data and will be referenced often in the discussion of
acetonitrile in Chapter IV. A brief description of these two
techniques follows.

1. Photoelectron Spectroscopy

PES, like PIMS, utilizes ionization by photons to

investigate ions. In PBS the kinetic energy of the ejected
photoelectron is measured, but there is no attempt to observe
the ions directly. A gaseous sample is irradiated with fixed-
energy, monochromatic VUV light; most often, 21.21 eV photons
produced from an electric discharge in helium are utilized,
but other rare gas resonance lines have been employed. The
kinetic energies of the photoelectrons are measured with an
electron spectrometer and a plot is made of the intensity of
the electrons as a function of the difference in energy
between the monochromatic photons and the photoelectrons.
Since energy and momentum are conserved, this difference is
the excitation energy of the product ion with respect to the
neutral molecule. The photoelectron spectrum displays the
distribution of ionic states that are populated upon ioniza-
tion.

Photoelectron spectra are usually obtained at a photon

41

energy where autoionization does not significantly contribute
to the photoionization cross section, and since direct ioniza-
tion cross sections vary little with energy above threshold,
PES is useful for judging the contribution of direct ionization
to a PIE curve. Indeed, if autoionization did not contribute
to the total PIE, the first derivative with respect to photon
energy of the total PIE would closely approximate the photo-
electron spectrum.

The vibrational frequencies of an ion, as well as relative
Franck-Condon factors for the transitions, may often be deter-
mined directly from the vibrational structure in a photoelec-
tron spectrum. These in turn are useful for determining
changes in geometry between the neutral molecule and the ion.
On the other hand, the photoelectron spectrum reveals little
or no information about fragmentation of ions. Sometimes
fragmentation may be inferred from broadening of or the absence
of vibrational structure in a photoelectron spectrum; however
this type of evidence is uncertain. Photoelectron spectro-
scopists most often rely on PIMS for direct evidence of frag-
mentation. More details of PBS are given in References 21,

22, and 55.
2. Electron Impact Energy Loss Spectroscopy
Ordinary optical absorption spectra in the energy
range of the ionization continuum are often useful for locating
Rydberg states which might autoionize. However, because of the
experimental difficulties of working in the VUV,very limited

data are available. EIEL spectra provide much the same

42

information without many of the experimental constraints of
VUV absorption spectroscopy.

EIELS is an inelastic electron scattering technique in
which a gaseous sample is irradiated with a beam of mono-
energetic and fixed-energy electrons, and the kinetic energies
of the scattered electrons are measured with an electron
spectrometer. In a fashion similar to that used for PBS,
the electron intensity of the scattered electrons is plotted
as a function of the initial electron energy minus the scat-
tered electron energy. The incident monoenergetic electrons
induce transitions in the neutral sample molecules and will
leave the scattering complex with an energy equal to the
incident energy minus the transition energy. The EIEL
spectrum will display peaks at the electron energy differences
corresponding to the induced transitions.

EIEL.spectra are most useful for locating Rydberg states
which may autoionize and thus be observed in a PIE curve,
however, they may display more transitions to Rydberg states
than can be observed in an optical experiment, due to the
relaxed selection rules of electron-induced transitions. The
advantage over PIMS for observing transitions to Rydberg
states is that transitions to states below the lowest IP of a
, molecule can be observed. These transitions are often help-
ful for assigning autoionization structure in a PIE curve
for which a limited number of Rydberg series members are
observed through autoionization and for which lower members

of the series are located below the IP. EIEL spectra, however,

43

provide little information about ionic states since the Rydberg
series join smoothly onto the ionization continuum. More

details of EIELS can be found in References 20, 56 and 57.

CHAPTER III

EXPERIMENTAL APPARATUS AND PROCEDURES

A. Introduction

The purpose of this chapter is threefold: to present a
brief description of the MSU PIMS instrument, to document the
experimental conditions under which the data presented in
Chapter IV were recorded, and to discuss experimental problems
which were encountered in the course of this work. The instru-
ment has been described in considerable detail elsewhere,19’58
and the brief overview is included here for completeness and
to facilitate the discussion in this chapter. A diagram of
the apparatus is shown in Figure 111-1. The instrumental
problems encountered during the course of this investigation
were innumerable, many of them due to lack of experience with
the instrument, whose construction was completed just prior
to the start of the acetonitrile experiments. Many of these
problems have been resolved; however, some are likely to occur
again,and it is hoped that the following discussion will be of
help to future users of the instrument.
B. The Instrument

1. Light Source

The light source is a Hinterregger-type windowless

discharge lamp with water-cooled anode and cathode. The dis-
charge tube is a 25 cm long x 4 mm I.D. water-jacketed quartz

capillary to which the discharge gas is admitted at the anode

44

45

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Figure III-l. BA-baffle; EN-entrance slit; EX—exit slit; GR-grating;
IS-ion source; IT—ion transducer; LP-lamp; Pl-first
differential pumping port; P2-second differential pump-
ing port; P3—monochromator pumping port; P4-sample
chamber pumping port; PS-quadrupole chamber pumping port;
PT—photon transducer; QP—quadrupole; QS-quadrupole
support; LE-Ion Lense.

46

after it has passed through a molecular sieve trap immersed
in liquid nitrogen. A small differential pressure is main-
tained down the length of the discharge by pumping on the
cathode end of the lamp; this stabilizes the discharge and
helps eliminate sputtering of the cathode onto the mono-
chromator entrance slits. The cathode vacuum pump is
throttled with a needle valve.

The rare gas continua can be produced by a high-power
pulsed discharge in the pure gas. The MSU instrument utilizes
a home-built, single vacuum tube, high-power switching circuit
to pulse the output of a high voltage d.c. power supply.

The switching circuit is in turn driven by a Cober A model
605P high-power pulse generator. A schematic diagram of the
switching circuit is shown in Figure III-2.

The hydrogen many-line pseudo continuum is produced by a
d.c. discharge in pure hydrogen at a pressure of 2-4 torr.
The d.c. high voltage power supply used in the switching cir-
cuit, from which it is disconnected in this application,
powers the hydrogen discharge. A 15009, 1500 W resistor
limits the current drawn from the supply.

The ionization potential of acetonitrile falls in a
region of overlap between the helium Hopfield continuum,
hereafter referred to as the helium continuum, and the hydro-
gen pseudo continuum; however, neither light source is very
intense in the overlap region. The output of both lamps is
shown in Figure III-3. Preliminary data were taken with both

lamps and the helium continuum was found to be the better

47

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48

RELATIVE INTENSITY

 

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Continuum (top) and Hydrogen Pseudo-
continuum (bottom) Lamps.

49

light source for the acetonitrile experiments; all PIES
presented in this thesis were taken with that source. The
hydrogen continuum with its large variation in intensity as
a function of wavelength made it impossible to tell if struc-
ture in the PIEs was real or an artifact caused by scattered
light.* The smooth intensity variation of the wavelength
output from the helium source, plus the few sharp lines from
impurities in the lamp gas, made it relatively easy to dis-
tinguish real structure from artifacts and to properly correct
for scattered light. However, to minimize artifacts a great
deal of effort went into reducing impurities to a minimum
by always using a clean gas trap and a leak-free lamp gas
plumbing system.

The intensity of the helium continuum is controlled by
several variables: helium pressure and purity, pulse width
and frequency, d.c. high voltage, Cober pulse generator peak
output voltage, and the condition of the lamp electrodes.

The highest helium pressure possible, which is limited
by the differential pumping between the lamp and monochromator
and by the pumping speed of the monochromator pump, produces
the highest intensity. Under current instrumental conditions
the maximum pressure is about 70 torr with lOOu entrance slits,
and about 130 torr with 500 entrance slits.

The pulse frequency, pulse width and Cober high voltage

 

*
A discussion of such artifacts appears in Reference 21, p.319.

50

are adjustments made on the Cober pulse generator. The
capabilities of the Cober and the limitations and require-
ments of the switching circuit constrain these parameters.
The best set of parameters are a pulse width of 0.4203 a
frequency of 33.3 kHz and a Cober high voltage setting of

1.3 kV d.c. A narrower pulse width would allow a higher fre-
quency to be used and would increase the lamp intensity.
However, the pulse width is limited to 0.42us by the turn-on
time of the switching circuit. The Cober's d.c. high voltage
is set (1.3 kV) for a peak output voltage of 1 kV, which
should not be exceeded since doing so may cause damage to the
switching tube.

With the above setting on the Cober and 70 torr of helium,
the maximum intensity is attained with the switched high
voltage at 10 kV d.c. At this voltage a current of 90-100 mA
are drawn from the supply when the lamp gas is pure and the
lamp electrodes are clean. Increasing the voltage above 10 kV
increases the current drawn from the supply, but has no effect
on the lamp intensity.

A current from the high voltage power supply of less than
90 mA at 10 kV is a fairly good indicator of a dirty lamp
cathode or impure lamp gas, both of which decrease the inten-
sity of the lamp. After several months of operation the
surface of the cathode on which the discharge occurs becomes
blackened by deposits of unknown composition. The cathode
is easily restored by removing the deposits with emery cloth

and steel wool or by sand blasting, after which the cathode

should be thoroughly cleaned with l,l,l-trichlorethane fol-
lowed by methanol to remove any oil and debris.

Impurities, primarily air, in the discharge gas not only
cause a large number of very intense emission lines to be
superimposed on the continuum, but also limit its intensity.
The impurity level is most easily determined by recording a
lamp output spectrum. Excessive impurities, indicated not
only by many intense emission lines but also by absorption
lines of nitrogen, are usually due to a leak in the lamp
plumbing system. When the lamp plumbing is adequately leak-
free it can be pumped down to 100 and the pressure will remain
below about 3000 when the closed system stands overnight.

Another source of impurities can be the compressed helium
cylinders and the lamp gas manifold. When helium tanks are
changed the lamp gas manifold should be thoroughly pumped out
to remove any air that was admitted during cylinder change-
over. Once the helium pressure is restored the manifold
poses no problem, since it is considerably above atmospheric
pressure. The quality of the helium gas varies from tank to
tank, even though it has a stated purity of 99.99% (Airco,
Inc.). Usually the molecular sieve trap will clean the helium
sufficiently, and its use can increase the intensity of the
lamp by as much as a factor of two. If one is working in a
region where the continuum intensity is low and intense
emission lines are a problem, a tank that is sufficiently
free of impurities can usually be found by trying several

tanks. Higher purity helium would alleviate this problem

52

but probably is not worth the extra cost since helium of
reasonable purity is always available in the chemistry depart-
ment, and a good clean trap usually provides sufficient
cleanliness.

The helium 584 A line, (182p)1P + (152)18 transition,
is often useful for acquiring mass spectra since it can be
produced with high spectral purity and intensity. It was
used as the ionization source for the mass spectra presented
in this thesis. The 584 A line is generated by a low pressure
d.c. discharge. Maximum intensity is obtained with helium
pressures just less than 1 torr and the maximum d.c. power
supply current available. The high voltage d.c. power supply
from the switching circuit, with the addition of a current-
limiting resistor, is used to power the helium line lamp and
the maximum current available from the supply is 800 mA.
However, for reliable operation a current of 750 mA should be
used; at 750 mA the voltage is 1500 V.

The lamp and its power supplies were the biggest instru-
mental bottleneck of the acetonitrile project. Most of the
problems were with high voltage devices. Future operators of
the instrument should carefully note that all of the lamp

circuitry is potentially lethal even when it is unplugged!

 

 

Strict precautions must be taken to insure that all devices
are disconnected from their powerlines and all capacitors are
discharged before checking or troubleshooting the system.

If one lacks experience with high voltage devices, help should

be obtained from an experienced person whenever there is a

53

problem. Never work on the high voltage circuits alone, and
be sure that someone who knows what to do in case of electro-
cution is present.

The vacuum tube switching circuit is prone to two
problems: arcing and breakdown of the rectifier diodes in
the screen power supply. The arcing problem, now that all
sharp points have been eliminated, is caused by accumulation
of dust on the circuit shown in Figure III-2. The circuit
is enclosed in a Plexiglas box, but air is forced through
the box to cool the tube. Even though the air entering
the Plexiglas box is filtered, after several years of

operation enough dust can accumulate to cause problems.

On the only circuit board in the Plexiglas box is an opto-
isolator -- part of the interlock system -- which insures that
the screen supply is not on unless the control grid supply is
also on. Arcing causes the opto-isolator to turn off, which
in turn (through an interlock circuit) shuts off the screen
power supply, the Cober pulse generator and the d.c. high
voltage power supply. The problem is symptomized by the
screen, Cober and d.c. high voltage shutting off as the d.c.
high voltage is turned up. Arcing can be diagnosed as the
problem by removing the tube and disconnecting the Cober at
its terminating resistor, as well as the secondaries of the
screen, control grid, and filament transformers. Once this
has been done the d.c. high voltage can be turned up to 10-15 kV

and if arcing is the problem arcs will be observed at several

54

locations on the circuit. One should look especially closely
at the circuit board containing the opto-isolator. The arcs
are very dim and can be seen only in absolute darkness; it
takes several minutes for the eyes to acclimate to a point
where the arcs can be observed. If arcs are confirmed to be
the problem the circuit must be disassembled and all the com-
ponents thoroughly cleaned. Methanol is a suitable cleaning
solvent; acetone is not recommended because it dissolves the
paint and labels on the components.

Breakdown of the screen's rectifier diodes can occur when
there is input from the Cober while the d.c. high voltage is
off. This has happened in a variety of situations and causes
current from the filament to be collected by the screen instead
of at the tube anode; the screen's rectifier diodes are damaged
by this current. The 2000 resistor in series with the recti-
fier and the screen was added and the primaries of the trans-
formers were fused to protect the diodes, but they are still
damaged occasionally. When the rectifier diodes have been
ruined the fuses on the screen transformer primary will blow
immediately when the screen is turned on. Damaged diodes are
most easily confirmed as the problem by removing the circuit
board on which they are located from the Plexiglas box and
measuring the forward and reverse resistance of the diodes.
This is most easily done with an ordinary ohmmeter, but the
meter must use a high enough voltage to measure resistance to
make a good diode conduct in the forward direction. For an

ohmmeter which uses 1.5 V to measure resistances on the x 100

55

scale the forward resistance of a good diode should be about
2509 and the reverse resistance infinity. If any one diode

in the bridge does not conform to these standards all diodes
in the bridge should be replaced. (It is wise to have a
reserve set on hand.) When the diodes are replaced the solder
connections must be well beaded to eliminate any sharp points
which can cause corona which in turn can cause the opto-iso-
lator to shut off.

The Cober pulse generator is quite reliable, but since it
is primarily a vacuum tube circuit its performance degrades
with extended use. If it is suspected that the Cober is not
performing up to the standards outlined in its manual, its
performance may be checked under a dummy load. The output is
most easily and safely monitored with an oscilloscope at the
a 1000 output connector on the front panel. The load should
be a 2500, 250 W noninductive resistor. The rise and fall
time of the output pulse should be checked as should the peak
shape and peak height as a function of the d.c. high voltage
and the repetition rate.

If the Cober is not operating up to specification one of
its vacuum tubes is probably weak. A tube in good condition
will operate properly with the filament voltage reduced to
90% of its normal value whereas a weak tube will not. A
Cinch-Jones two-pronged connector has been spliced into the
primary side of the filament transformer, allowing one to
insert a variac with which the filament voltage can be reduced.

To test the tubes one first makes sure that the high voltage

56

is off and then observes the wave forms with an oscilloscope
at the output of each tube under normal filament voltage. The
schematics in the manual indicate the location of the test
points and the correct wave forms. The observations are then
repeated with the filament voltage reduced to 90% of its
normal value. If the wave forms change the tube responsible
for the change can be isolated and should be replaced. All
the tube circuits are potentially lethal and since this testing
process requires attaching an oscilloscope probe to the test
points, the power should always be disconnected when the probe
is moved. Again, it is also important that someone else be
present in the room when these tests are performed.

2. Monochromator

The monochromator is a McPherson model 225, l-meter,

near-normal-incidence instrument. The dispersing element is
a concave, magnesium fluoride overcoated aluminum grating,
ruled with 1200 lines/mm and blazed at 1200 A. The grating
has a reciprocal dispersion of 8.4 A per mm.

Three fixed entrance slits: 100m, 500m, and 1000m, and
four fixed exit slits: 100m, 50pm, lOOum, and 3000m, are
mounted on moveable slit plates. The slits can be changed
without breaking vacuum via knobs located outside of the
vacuum chamber. The wavelength is driven with a stepping
motor which can be operated manually or with a computer.

After several months of use the diffraction grating accumu-
lates a thin coating of diffusion pump oil, which significantly

reduces its reflectivity in the vacuum ultraviolet and

57

increases scattered light in the ultraviolet and visible
regions of the spectrum. This condition is most easily
detected by observing the scattered light intensity in the
100-500 A range, by using the helium continuum as the light
source and a sodium salicylate light detector. The helium
continuum produces no light in this region, and with a clean
grating no significant amount of scattered light will be ob-
served. However, if the grating is coated with oil a large
hump in the light intensity will be observed in this region,
with a maximum at about 250 A. The scattered intensity varies
depending on the amount of oil on the grating and its
near 250 A can exceed the true intensity maximum near 800 A
Oil on the grating will be polymerized by VUV light and
therefore the grating should be promptly cleaned whenever
scattered light is observed. The grating must be removed
from the monochromator and its mask taken off. To remove the
oil, the grating is first rinsed with Freon ll (CFC13), fol-
lowed by a high purity methanol rinse. The methanol rinsing
is best done by simultaneously applying the methanol with a
squeeze bottle and drying the grating with low pressure, clean,
compressed air, working from top to bottom. Great care must
be taken not to touch the ruled surface of the grating. When
the grating is reinstalled in the monochromator it will have
to be realigned and focused, by following the procedure in the

monochromator manual.

58

3. Ionization Region
The ion source is a cubical, stainless steel box, one

inch per side, located one centimeter beyond the exit slit
of the monochromator. It has two rectangular apertures on
opposite sides to enable transmission of the photon beam; on
the horizontal perpendicular to the optic axis is a one-fourth
inch diameter ion exit hole. The ion aperture is covered with
a fine wire grid to minimize penetration into the source of
electric fields from ion focusing lenses located just outside.
An electrically-insulated, stainless steel plate, the repeller,
is positioned inside the source, across from the ion exit
aperture. An adjustable voltage is applied to the repeller to
accelerate the ions from the source.

The sample is admitted through a tube located behind the
repeller and the sample pressure is measured through a tube
in the top of the ion source. The sample pressure is controlled
with a Granville-Phillips model 203 leak valve and measured
with a Datametrics model lOl4-A barocell capacitance manometer.
The manometer and leak valve are outside of the high vacuum.

4. Mass Spectrometer and Ion Optics

The ions are guided from the ion source and focused

onto the quadrupole mass filter with four electrostatic
aperture lenses. The quadrupole mass filter is an Extranuclear
model 324-9 with 1.9 cm diameter x 22 cm long rods and is
powered by a model 311 power supply, equipped with a model E
high-Q head. The ion lenses were supplied with the mass filter.

The transmitted mass is controlled by a dial on the front

59

panel of the quadrupole power supply or by a voltage applied
to a connector on the back of the power supply. When measur-
ing a PIE curve the mass filter is used in the fixed mass
mode, the mass being selected with the front panel dial.
However, to obtain a mass spectrum the transmitted mass is
scanned by applying a voltage ramp to the connector on the
back panel. Part of this thesis research included the design
and construction of a digital ramp generator that allows
manual or computer control of the transmitted mass. Details
of the circuit are given in Appendix A.
5. Ion and Photon Transducers

The ion transducer, located on-axis at the exit hole
of the quadrupole, is a Channeltron continuous-dynode electron
multiplier supplied by Galileo Electro-optics. Most of the
acetonitrile data were collected with a model CEM 4028 Channel-
tron, but unfortunately in the course of modifications it was
broken; it has been replaced with a CEM 4816 Channeltron The
CEM 4816 has the advantage of being linear up to higher count
rates; it has a lower gain than the CEM 4028, although the dif-
ference in gain is very small. The CEM 4816 has been used for

both positive and negative ion detection and the circuits used

for each mode are shown in Figure III-4.

The Channeltron output is measured either as direct
current or pulse—counted. In the former mode the output is

amplified with a Keithley model 417 electrometer. However,

since the direct current method has several disadvantages

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compared to pulse counting when the output current is small,59

it was used only for setting up an experiment. All data were
collected with the pulse counting technique, where the output
pulses are amplified and discriminated with a circuit developed

at MSU,60 and the counts are accumulated with a computer-

interfaced counter.19 In the negative-ion mode pulse counting
must always be used due to the need for a high voltage block-
ing capacitor on the Channeltron output.

The photon transducer is a sodium salicylate phosphor
whose emission intensity is measured with an RCA 8850 photo—
multiplier tube. Sodium salicylate is superior to ordinary
(bare) photomultipliers because it possesses a nearly constant
quantum yield throughout the helium continuum. The sodium
salicylate emission band does not shift with the exciting
wavelength and the emission intensity can be accurately
measured with a standard photomultiplier. The output current
of the photomultiplier is amplified with a Keithley 1800
current amplifier, and the output voltage is digitized with a
voltage-to-frequency converter and a computer-interfaced
counter.19

6. Vacuum System

The monochromator is isolated from the discharge lamp
with two stages of differential pumping. The first stage is
a 300 l/sec four-inch diffusion injector pump. The mono-
chromator chamber is pumped with a six-inch, 2400 l/sec dif-

fusion pump, as is the sample region. The quadrupole region

is pumped with a six-inch 1800 l/sec diffusion pump.

62

The pumping speeds quoted are for untrapped pumps; however,
all four diffusion pumps are trapped with Freon-cooled
baffles which reduce the pumping speeds somewhat. All the
pumps can be isolated from the experimental vacuum chamber
with pneumatically-operated gate valves.
7. Data Collection

Once an experiment is set up, data collection and
storage are controlled with a PDP 8/M or PDP 8/I minicomputer.
The data are collected by using a variable integration time
technique which permits recording data of the desired quality
in an optimum amount of time.59 The monochromator wavelength
is stepped in preset intervals, and at each wavelength ion
and photon counts are accumulated until the datum has the
desired signal-to-noise ratio. Photon and ion count rates,
wavelengths and integration times are stored on a floppy or
hard disk. The course of the experiment is continuously
monitored via a computer-interfaced, stepped, stripchart
recorder on which the real-time PIE is plotted. Periodic
measurements of "light" and "dark" photon and ion count rates
are made at a reference wavelength so that the data can be
corrected for sample pressure and instrumental drift. Approxi-
mate corrections for stray light are made by measuring the
light intensity at two wavelengths where the helium continuum
does not emit. Final corrections of the data for sample
pressure, instrumental drift and stray light, as well as the
final plot, are done with the MSU Chemistry Department's

Cemcomgraph computer facility.61

63

C. Experimental Details
1. Samples

Reagent grade protonated acetonitrile (CH3CN) was
obtained from the Aldrich Chemical Co. and acetonitrile-d3
(CD3CN) from Stohler Isotope Chemicals. The deuterated com-
pound had a stated atom purity of 99.5% D. Air was removed
from the samples through the freeze-pump-thaw technique; the
samples were frozen with a dry ice-methanol bath. No further
purification was done on the protonated compound; however, the
deuterated material was contaminated with sufficient quantities
of D O and HDO that OD+ was observed in the CD+ PIE. For col-

2 3

lection of the CD;

sieves and calcium hydride.

PIE the sample was dried with molecular

The samples were contained in pyrex bulbs which were con-
nected to the leak valve via a glass-to-metal seal and a
short length of copper tubing. The temperature of the room
in which the instrument is located varies by as much as 50 F
over a period of several hours. To minimize the effects of
temperature variation on the sample vapor pressure the sample
containers were placed in a half-liter Dewar flask filled with
water. The data were collected with sample pressures between
4.5 - 5.5x10"4 torr, and the pressure varied by less than 10%
throughout an experiment.

CN+)

Proton transfer from the acetonitrile parent ion (CH3

to neutral acetonitrile to form CH3CNH+ is an exothermic

reaction with a large cross section at low relative kinetic

62

O l O I + o
energies. The relative IntenSIty of CH CNH With respect

3

64

to CH CN+ is strongly dependent on the conditions in the ion

3
source. With small potential differences between the repeller
and the ion source (less than 1 volt) and a sample pressure

of 5 x 10"4

torr the intensity of CH3CNH+ is nearly half the
intensity of CH3CN+. Because first-order processes were of
primary interest and the proton transfer reaction significantly
reduced the intensity of the parent ion, the reaction was sup-
pressed by using a rather large potential difference between
the repeller and the ion source (:10 V). This reduces the
residence time of the ions in the ion source and therefore
decreases the chance of a reactive interaction with the neutral
compound. For the work reported here the repeller was main-
tained at +13.8 V and the ion source at +3.8 V. The remaining
ion lenses -- the extractor, lenses 1, 2 and 3, arranged in
that order as the ions pass from the source to the quadrupole--
were set at -18.4 V, -44.8 V, —6.12 V and -5.4 V, respectively.
This combination reduced the intensity of CH3CNH+ to less

than 19% of the CH CN+ intensity, maximized the CH CN+ signal

3

and provided good mass spectrum peak shapes.

3

The mass filter was always set to the minimum resolution
possible to just prevent overlap of ions that differed in
mass by l u.

Monochromator entrance and exit slits of 100 um, which
give 0.84 A fwhm band pass, were used for all the PIE measure-
ments reported here, except for the threshold regions of the
parent ions; these were also measured with 500m entrance and

exit slits, providing a 0.42 A fwhm band pass. Data recorded

65

with lOOum slits were taken in steps of 0.25 A, whereas 0.15 A
steps were used with 500m slits.

Integration and experiment times varied considerably
depending on the intensity of the ions and photons in the
region of interest, the slit width, the size of the wavelength
step, and the desired quality of the data. An attempt was
always made to record the data with a signal-to-noise ratio
of at least 100. For the PIE curves reported here, this re-

quired experiment times ranging from 12-48 hours.

CHAPTER IV
RESULTS AND DISCUSSION

Photoionization of Acetonitrile

 

A. Previous Studies

Prior to the investigation reported here, studies of photo-
ionization of acetonitrile had been reported by Watanabe, et
al.,63 Nicholson,4 and Dibeler and Liston.65 The data obtained
in references 63 and 64 were recorded without mass analysis
and therefore only the total ionization efficiency could be
measured. In both papers it was correctly assumed that the
observed threshold was that of the parent ion; in neither

paper were PIEs reported. Dibeler and Liston used mass anal-

ysis and measured the ionization potential of acetonitrile as
+0
2 2'

ever, again no PIES were published. The results of these

well as appearance potentials of CH CN+, CHCN+ and CH how—
three publications are gathered in Table IV-5 together with
the results of this investigation, and will be discussed along
with the data reported here.
B. The Photoelectron Spectrum

The photoelectron spectrum (PBS) of acetonitrile has been

reported.55'66’67

The PES of CH3CN from reference 55 is reproduced
in Figure IV-l. The conclusions are as follows. The first
band, with its origin at 12.21 eV in Figure IV-l, results

from the removal of an electron from the C s N n-orbitals,

66

67

L000—

 

ol22l
,l3 l4

Count sec"
3

 

 

 

 

 

 

 

 

 

 

Figure IV-l.

Photoelectron Spectrum of CH
(from Reference 55.)

3CN

 

68

as indicated by the vibrational structure of the band. The
observed vibrational modes and their frequencies in the parent

ion are compared to those of the neutral in Table IV—l. Three

modes are excited in the ground state of the ion: the C N

stretch (02), the symmetric CH deformation (v3), and the C—C

3

stretch (04). This assignment is supported by the CD CN spec-

3

trum. When compared to the ground state neutral molecule, the

frequencies of the C _ N stretch and the C—C stretch decrease
in the ion, while the CH3 symmetric deformation frequency in-
creases. This indicates that the orbital from which the elec-
tron is removed is C—N and C—C bonding, but C—H antibonding,
thus a n-orbital of the C E N bond. This n-orbital has E

symmetry in the C
68,69

3v point group and can be labelled as the 3e
orbital.
The second band, with its origin at 13.14 eV, has very
little vibrational structure. The band has been assigned to
the removal of an electron from the nitrogen lone pair, and

the single vibrational excitation observed to the CH symmetric

3

deformation (v ). Since the nitrogen lone pair participates

3
little in the bonding, loss of one of the electrons should
have little effect on the structure of the molecule, as is
indicated by the paucity of vibrational excitation in the
photoelectron band. The nitrogen lone pair can be labelled
as Sal. The assignment of the remaining PE structure, in the
region from 15-21 eV, is considerably less certain, but it

55

must result from ionization of C—C and C—H 0 bonds. Turner

identifies the vibrational structure at the head of the band

Table IV-l. Vibrational Modes and Frequencies of CH

3

compared to the Frequencies of the Neutral.

69

3

CN+ and
CD CN+ Excited in the Photoelectron Spectra

 

Frequency (cm-

 

Frequency (cm-

 

 

State Vibrational + a +
of ion mode exc1ted CH3CN CH3CN CD3CN CD3CN
i 02 c N stretch 2010 2267 1990 2278
v3 symm. CH3 def. 1430 1385 1070 1110
04 c—c stretch 810 920 810 831
E 03 symm. CH3 def. 1290 1385 970 1110
E 03 symm. CH3 def. 1440 1385 ——b 1110
v4 c—c stretch 860 920 ——b 831

 

aVibrational frequency in the ground electronic state of the

neutral; taken from reference 88.

bnot determined.

70

as arising from the CH3 symmetric deformation (03) and the

C—C stretch (04); the changes in these frequencies from the
neutral molecule suggests that the orbital ionized is C—H
antibonding and C—C bonding. Frost, et a1.,66 does not even
attempt an analysis. However, it is clear that in this region
there are two bands: one centered at about 16 eV, the other

at 17.5 eV, and that ionization from orbitals that are involved
with C—C and C—H bonding is implicated in both cases. The
absence of a strong transition at the origin indicates that

at least some bond lengths have changed considerably. (The
band centered at about 20 eV in Figure IV-l may be an instru-
mental artifact.55)

It can be concluded that there are two well defined states
and at least two poorly defined states of the acetonitrile
parent ion that will be accessible by direct ionization in a
PIMS experiment. The ground state of the ion has several
bond lengths and vibrational frequencies that differ from
those of the neutral molecule, while the vibrational frequen-
cies and bond lengths of the first excited state of the ion
are probably very similar to those of the neutral molecule.

The PES ionization potentials reported for CH3CN in ref-
erences 55,56, and 67 are listed in Table IV-5, along with

the photoionization data. Although these PES investigations
A indicated that the spectrum of CD3CN was recorded, only Lake

and Thompson67 reported IPs for CD3CN.

71

C. The Photoionization Mass Spectra of CH3CN and CDBCN

The 584 A (21.2 eV) photoionization mass spectra (PMS) of
CH3CN and CD3CN,recorded in the present study, are shown in
Figure IV-2. Relative intensities and assignments are presen-
ted in Table IV-2. The electron impact mass spectrum (EIMS)
of CH3CN 62’70’71 shows slightly more fragmentation than the

PMS, but the overall agreement between the two spectra is

good, and the small differences can be attributed to the higher
ionizing energy (50-80 eV) used in the El experiments.

Most of the assignments of the PMS and EIMS are straight-
forward even though the deuterated compound was slightly
proton contaminated; however, some of the assignments deserve
comments. Gray62 suggested that m/e=15 from CH3CN might con-
tain some contribution from NH+ since a small amount of NH:
(m/e=16) is detected. Therefore the peaks assigned as CD:
and CD; (m/e=l6,l8) might also have some contribution from ND+
and NDE, respectively. However, thermochemical calculations
show the thresholds for NH+ and NH: to be considerably above
those for CH: and CH3,
probably not contribute significantly to the 21 eV PMS. Indeed,

so that NH+(ND+) and NH:(ND;) would

no peak is observed at m/e=16.

The high resolution EIMS‘70 of CH3CN shows that m/e=26 and
27 are multiple peaks (m/e=26 is 60% CN+ and 40% C2H+, and
m/e=27 is 85% HCN+ and 15% C H+ at the unstated, but probably

2 3

>50 eV ionizing energy). However, this need not be of concern

in this investigation, since the intensity of these ions is

72

 

 

 

 

 

 

 

 

 

 

 

 

 

c 03c N
1 ._ 11
10 2'0 31) 70 5'0 Jo 230
m /0 .
CH3CN
1. _ 1
H0 Ab JP 40 9% 6b 75

'"V5

Figure IV-2. 584 A (21.2 eV) Photoionization Mass Spectra
of CH3CN and CD3CN. (Quantitative Relative
intensities should not be measured from these
spectra.)

73

Table IV—2. CH3CN and CD3CN Photoionization Mass Spectra.

(Ionization energy = 21.2 eV.)

 

 

 

 

CH3CN CD3CN
intensity Intensity
Relative Relative
to CH3CN+ to CD CN+
m/e (m/e=4l) Assignment (m/e= 4) Assignment
14 18.2 CH2+
15 4.4 CH3+ <1 CHD+
16 27.6 CD2+
l7 <1 CHD2+
+
18 6.8 CD3
+ +
26 <1 CN 'C2H2
+ +
<
27 1 HCN ,C2H3
+ + + + +
28 5.2 HZCN ,N2 <1 DCN ,N2 ,c202
+ +
30 8.1 DZCN ,c203
38 1.2 C2N+ 1.2 CZN+
39 23.0 HC2N+
+ + +
40 78.7 HZCZN 22.7 DCZN ,(HZCZN )
41 100 H c N+ 2 3 HDC N+(H c N+)
3 2 ° 2 3 2
+ + +
42 13.3 H4C2N 80.4 DZCZN ,(H4C2N )
+
> 43 6.0 HDZCZN
+
44 100 D3C2N
+
45 3.2 HD3C2N
46 19.0 D c N+

 

4 2

74

too low below 21 eV for a PIE curve to be measured. The peak

at m/e=28 in the PMS of CH CN does contain some contribution

3

from N3, but it is quite small as can be ascertained by com-
parison with the CD3CN PMS. However, the N; PIE curve is

quite distinct and N; did interfere with the HZCN+ PIE curve.

(See section IV-E5.)

The small differences in the CH3CN and CD CN PMSs are

3
mostly attributable to a difference in the sample pressure
(if contributions from the protonated impurity in the CD3CN
sample are neglected). The CH3CN PMS was recorded with a
sample pressure of 4.9 x 10.4 torr and the CD3CN with a pres-

4

sure of 5.2 x 10- torr. This 6% descrepancy was uninten-

tional, but it serves to demonstrate the pressure dependence
of the reaction of the parent ion with the neutral sample to
produce CH3CNH+ (CD3CND+). Due to the higher pressure of

CD CN, the relative intensity of the reaction product is

3
greater in the CD CN PMS. Thus more of the parent ions

3
initially formed are detected as P+2 in the CD3CN PMS which
accounts for most of the higher relative intensities of the
fragment ions in the CD3CN PMS compared to the CH3CN PMS.
CH3CN+, CHZCN+, CHCN+, HZCN+, CH; and CH3, as well as
their deuterated analogs, are produced with sufficient inten-
- sity to enable PIE curves to be recorded. Pressure-depen-

dence studies show that all of these are primary ions. The

absolute intensity of CH3CN+ and CD3CN+ in the mass spectra

are about 3500 ions/sec, which is more than twice the

 

75

intensity that they are produced at the maximum (~800 A,
15.5 eV) of the helium continuum.

A search was made for negative ions and CN- and CHZCN-
ions were detected; however, their intensity was much too low
for PIE curves to be recorded.

D. Parent Ion PIE Curves
1. General Observations

The PIES of CH3CN+ and CD3CN+ are presented in Figure
IV-3. On the scale of the figure the two PIEs should be, and
are, identical. There is a distinct threshold at about 1015 A
(12.2 eV), followed by an autoionizing Rydberg series converg-
ing to the first excited state of the ion. From the photo-
electron spectrum, the threshold of the first excited state
should be about 944 8 (13.1 eV) and the jump in the PIE at
approximately 944 A is the threshold for this state. The dis-
tinctness of the feature at 944 A indicates that the Rydberg
states converging to the first excited state of the ion are
strongly predissociating into neutrals, as well as auto-
ionizing, since no ion fragments are observed in this region.
If the Rydberg states were not predissociating the Rydberg
series would join smoothly onto the direct ionization continuum
of the first excited state.9 Acetonitrile is known to pre-
dissociate into neutral fragments at energies considerably
less than 13 eV.70

The region between 944 A (13.1 eV) and 820 A (15.1 eV)
corresponds to a blank region in the PES spectrum, and thus

additions to the PIE from direct ionization to new states are

.m oeoaucoc ”nosuso med +zomoo poo +zommo .mu>H ousoam

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p—nhEP—nh-P—bF-prh-p—thP—nbblrhppbbPPPPn—Phth

 

76

 

0111:

 

 

a
3
mm
m..
on.’
J
m
M
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m
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+
q q q — q 4 q u u d d N d — q q u d u - a q: —- 11:4..-—«Judd-q:qq—uq-u-udd-—-uandH4-d—Jd-uq-d-du-qq-u--quq
up n.» I. m.» Q. Nu m. 2. ON

36> cocoon: GEE

77

not expected. Nevertheless, as the photon energy rises fol-
lowing the threshold of the first excited state, the PIE
increases. This could be due to an increase in the direct
ionization cross section to the first excited state of the ion,
but it is most probably due to autoionization. The evidence
for autoionization is the onset of fragmentation in this region.
Therefore states above the first excited state of the ion are
populated following photon absorption, but they must be popu-
lated by autoionization since the photoelectron spectrum indi-
cates that there are no ionic states in this region available
for direct ionization. Moreover, in the CH3CN+ PIE there is
some structure in the 885-800 A range which can only be attri-
buted to autoionization. The leveling-off of the PIE at about
885 A (14.0 eV) correlates well with the fragmentation thresh-
old for the first fragment, CHZCN+, and the decrease in the
PIE from 885 A to 820 A (15.1 eV) is due to cessation of the
autoionizing Rydberg series caused by fragmentation. That is,
the parent ion states populated by autoionization in this
region fragment and are not detected as parent ions. This is
demonstrated in Figure IV—4 in which the dashed line is the
total ionization PIE, the sum of parent and fragment ions.

The total PIE actually increases.

From the PES spectrum, the threshold for the second excited
state of the ion is at approximately 820 A (15.1 eV). However,
there is no discontinuity in the PIE near 820 A. This is due
to a combination of two factors. First, there are Rydberg

states converging to this ionic state and the autoionization

A.mHo Hou0u 0:» mouooaoca mama omnmooc .zommo mo mHm Hobos .eu>H owsmam

«meotmocé 1823.05;
omo. ooo. omm ooo omo ooo own ooh ono ooo

p—-up»—+L-p—LLbDP-pTP—anP—hppP—b-h-bnhbrlrb-b!

 

78

 

OI

(snun 001119111) 31.1

 

 

 

q-q-(dw.-qqfi—udfiq-q4-q-fidlfiq—qfiuq_d1dqd.l—-idd114#q44

79

may join smoothly onto the continuum and hide the threshold.
Second, and probably more important, is the likelihood that

all, or nearly all, of the parent ions formed in the second
excited state are dissociated into ion fragments on the time
scale of the PIMS experiment. No discontinuity would be ex-
pected because no parent ions formed in this state would be
detected as P+. It is a general observation for polyatomic
molecules that most, if not all, ions formed with internal
energies above the first fragmentation threshold dissociate.l3’l4
The first fragmentation threshold for acetonitrile is at
approximately 885 A (14.0 eV), well below the threshold of
the second excited state. In acetonitrile some ions formed
with internal energies just above the first fragmentation
threshold do not dissociate, otherwise the autoionization
beyond 944 A would not be observed in the CH3CN+ PIE. How-
ever, the second excited state is more than 1 eV beyond the
onset of fragmentation and is, most surely, nearly completely
dissociated.

The region beyond 820 A in the parent ion PIE, to 600 A
(20.7 eV), then, would show no evidence of ionic states above
the second excited state. The PIE in this region thus reflects
the cross sections for direct ionization to the ground and
first excited states of the ion. As would be expected in this
case, the PIE slowly and smoothly decreases with increasing
photon energy.22

Upon close examination, however, there are some small, but

very important, differences in the PIE curves for CH3CN+ and

80

CD3CN+. In the following sections a more detailed examination
of the autoionization structure and the threshold regions of
these curves is presented.

2. Autoionization Structure: 1040 A - 940 A

The CH3CN+ and CD3CN+ PIEs between 1040 A (11.9 eV)

and 940 A (13.2 eV) are shown in Figures IV-5 and IV-6. Mem—
bers of two Rydberg series are readily apparent and are indi-
cated on the horizontal line near the top of the figures.
Only two members of the weaker series are resolved; this is
due to the broad line widths of the series members and not to
instrumental resolution. Fridth72 has reported the electron
impact energy loss (EIEL) spectrum of acetonitrile and has
also observed these two series. In the following pages the
assignment of the series type and the series limit are dis—
cussed.

The PES provides an initial estimate of the series limit.
The location of the first excited state of the ion is known
from the PES. From inspection of Figures IV-5 and IV-6 it
can be seen that the series are converging to this state, and
therefore the Rydberg series arise from excitation of the 5al
orbital of the neutral molecule. The quantum defect, which
is a primary consideration in the assignment of a Rydberg
_ transition,can then be calculated by using the photoelectron

ionization potential of the 5al orbital in the Rydberg equation:

Ehv = IP _ R . (II-4)

(n - 0)2

However, another option is to fit a series to the Rydberg

81

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«62.8.8.5 Eozmdés

 

 

 

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pub-prPPPb-pppbbPP—pr--ppu—ppupphhpp—pnpup-pub——-~b-pPP_-npnpprPPh—ppppbhp—bb-PEPnpb—bP-Lb-pr
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+
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dud‘dqfiqd-fiqfififiJl-q—qqq-—11-u—u1W.—qudddqqqd-qdqq—q-11-1141-d-1d
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36> cotton» SEE

(swan Mommv) 3Id

83

equation with the ionization potential and the quantum defect
as adjustable parameters. Very accurate ionization potentials
can be determined by this method.73

The more intense of the two series observed in the CH3CN+
and CD3CN+ PIE curves was fit to the Rydberg equation by means
of KINFIT 4, a general non-linear, least-squares curve-fitting
computer program.72 The series limit and the quantum defect
were taken as adjustable parameters. The quantum defect was
assumed to be constant as a function of n. Although this is
not strictly correct, the error that results for n 2 5 for a
molecule composed of second row atoms is negligible.73
Fridth's EIEL data72 were also fit for comparison with the
photoionization data. The results of the fits are given in
Table IV-3 along with the experimental locations of the ob-
served series members.

First consider the series limit. The photoelectron ioniza-

tion potentials reported for the 5al orbital are 13.11 eV66

and 13.14 ev.55'67

Although no error limits were published,
the PES spectra were probably recorded on instruments with
about 50 meV resolution, as will be shown when the lowest
ionization potential is discussed. With 50 meV resolution
peak positions can usually be measured to within about 10 meV.
Fridth's EIEL data were also collected with an electron
energy analyzer having about 50 meV resolution.

The PIE data were obtained with a photon bandwidth of
0.84 A; at 980 A this corresponds to an energy bandwidth of

11 meV. It was possible to locate the autoionization peak

ct . an
Ml CU 1

PH
a

 

1:”

84

 

 

 

 

 

Table IV-3. Rydberg Series Converging to the First Excited

State of CH3CN+ and CD3CN+.

CH3CN CD3CN

This work Fridth72 This work
Series a b
limit(eV) 13.133 i .004 13.135 1 .006 13.136 1 .004
~6(nso) .93 i .04 1.01 r .004 .92 i .04

Experimental energies (eV) and 6 calculated from series

limits derived from Fits

 

n energy(eV) 6 energy(eV) 6 energy(eV) 6
n50 3 9.713 1.01b
4 11.594 1.03
5 12.295 0.98
6 12.601 0.94 12.596 0.98 12.606 0.93
7 12.775 0.84 12.759 0.99 12.775 0.86
8 12.864 0.89 12.854 1.03 12.868 0.88
9 12.924 0.93 12.92 1.05 12.925 0.97
10 12.964 1.03
11
12 13.020 1.03 13.023 1.03
ndo 12.180 0.23
12.542 0.22C 12.534 0.24 12.550 0.182
6 12.724 0.23 12.706 0.37 0

-_

12.732

aErrors are linear estimates of the standard deviation.

.200

bResults of this investigator's fit of Fridth's po series.

CQuantum defects for the ndo series were calculated from

limits of nso series.

85

centers to within r 0.5 A or t 6 meV at 980 A. Furthermore,
the photoionization data have a built-in calibration — the
atomic emission lines in the light source output — which the
photoelectron and electron impact data lack. If the fit is
reliable the photoionization data should provide a more
accurate value for the 5al ionization potential. The series
limits obtained from the fit to the photoionization data are

13.133 1 0.004 eV for CH CN and 13.136 : 0.004 eV for CD CN.

3 3

The estimates of the standard deviation indicate that the fit
is quite good. However, because the Rydberg series fit is an
indirect method it could be argued that the small difference

between the Rydberg series limit and the photoelectron ioni-

zation potential is not significant.

However, the PIES present a very fortunate situation. If
the step at 944 A is indeed the threshold for ionization from
the 5a1 orbital, then an independent measure of this orbital
ionization energy is available. Generally, when a step cor-
responding to the threshold for direct ionization to a vibronic
state of an ion is observed, the point on the step correspond—
ing to the peak center in a resolved photoelectron line, the
ionization potential for the vibronic state, will be at the
inflection point or midpoint of the rise of the step.75 This
assumes that autoionization does not significantly contribute
to the step. Because the autoionization intensity in CH3CN+
and CD3CN+ is low in this region, and because there is a fairly
sharp break at the foot of the step, autoionization probably

does not significantly contribute in this case, and the step

86

should yield an accurate ionization potential. The photo—
electron ionization potentials for the 5a1 orbital (13.14 eV
and 13.11 eV) are marked on the PIEs in Figures IV-4 and IV-5.
Also marked are the limits derived from the Rydberg series
fits. The Rydberg series limits are closer to the midpoints
of the steps than are the photoelectron results. Consider-
ing the smaller error limits of the photoionization data, the
series limits derived from the fits, and the step at the
limit, it is concluded that the photoionization result is
indeed a more accurate determination of the 5al nitrogen lone
pair orbital ionization potential.

The difference between the CH3CN+ and CD3CN+ limits could
be real, due to a difference in the change of the zero point
energy between the neutral and the ion in the isotopic mole-
cules. However, since the difference is small — within the
error limits — and since 13.133 eV appears to be a better
estimate of the center of the step rise in the CD3CN+ PIE,
it can be concluded that CH3CN and CD3CN have the same 5al
ionization potential: 13.133 1 0.005 eV.

It is worth noting that some members of the more intense
series are missing in the PIE curves, based on the quantum
defect and the series limit. For example, the n=5 member
should provide an intense peak at 1005 A, but no distinct
peak is observed there. Probably an unbound potential surface
of the neutral molecule crosses the n=5 Rydberg series surface,
allowing it to be nearly completely dissociated. This member

is clearly observed in Fridth's72 EIEL spectrum, and there are

87

remnants of it in the PIE. The n=10 member of CH3CN+, and

n=10 and 11 of CD3CN+ are also missing, presumably for the

same reason. The n=4 member of the less intense series was

also observed by Fridth;72 it is located below the first ioni-

zation potential and therefore would not contribute to the PIE.
Consider next the series assignment. Remembering that

s-type Rydberg series have quantum defects of about 1.0, p-type

28’35 it would be reason—

of about 0.6, and d-type of near zero,
able to assume that the more intense series is an s—type with
6:0.92 and the less intense series a d-type with 6:0.2. On
the basis of the photoionization data alone, little more can
be said. However, Fridth72 was able to observe several series
members converging to the second ionization potential in the
spectroscopic range inaccessible to PIMS (below the first
ionization potential), as well as some members above the first
ionization potential. Moreover, several series converging to
the first ionization potential were observed. With the addi-
tion of these data, more definitive assignments are possible.

68,76

Two optical studies in the vacuum ultraviolet and

another EIEL investigation77 of CH3CN have been reported, but
in all three publications either the data were not recorded
to high enough energy or were obtained with inadequate reso-
lution to be of much use.

Fridth has assigned all the prominent features in the EIEL
spectrum,72 including the two series observed in this study.

The series corresponding to the weaker autoionization in the

PIES was designated do with 6:0.23, and this assignment is

88

in good agreement with the photoionization results. However,
the more intense series was assigned as pa with 6:0.97. AS
pointed out by Fridth, this assignment is somewhat questionable
and this investigator believes that it would be more correctly
assigned as an So series.

Fridth assigned the series in CH3CN by analogy with HCN.
The EIEL Spectrum of HCN has been reported by Fridth and
Asbrink,78 and they observed two series corresponding to exci-
tation of the nitrogen lone pair. These two series were
assigned as so (6:0.91 for the higher energy members of the
series) and do(6=0.4). Later, however, Asbrink, Fridth and

79

Lindholm published results of a HAM/3 calculation of HCN.

(HAM/3 is a semi-empirical technique for calculating valence

80) From the results of

transitions, developed by Lindholm.
the calculation it was concluded that some structure in the
EIEL spectrum of HCN, which had originally been interpreted
as Rydberg transitions, was really due to valence transitions.
The Rydberg transitions then needed to be reassigned. As a
result only one series, corresponding to excitation of the
nitrogen lone pair, was identified. It was assigned as po

with 6=0.80.79

It was suggested that the quantum defect was
larger than is typical for a pa series due to penetration of
the p Rydberg orbitals into the H—C—N bonding orbitals.

For CH3CN, Fridth reported three series, all correspond-
ing to excitation of the nitrogen lone pair and converging to

the second ionization potential, and four series corresponding

to excitation from the C E N n-bond and converging to the first

89

ionization potential. The upper series were assigned as
p0 (6:0.97), pn (o=0.60), and do (6:0.23); the lower series
as so (6:0.97), p0 (6:0.76), pr (6:0.61) and d0 (6:0.23).72

Two points need to be made. First, a very important ob-
servation in the spectroscopy of Rydberg states is that members
of the same types of series, converging to different states
of an ion, have very nearly the same term values.33 (A term
value is the difference between the series limit and the
energy of the transition to the Rydberg state, i.e., R/(n-6)2
in equation II-4). Thus, a po series converging to the first
excited state of an ion should have nearly the same quantum
defect as a po series converging to the ground ionic state,
and likewise for other series. The implication is that the
molecular orbital from which the electron is excited has very
little effect on the energy of the Rydberg orbital;33 this is
a reasonable conclusion when one considers the large spatial
extent of the Rydberg orbitals.

Second, when the EIEL data for CH CN are compared to the

3
photoionization energies (as in Table IV-3), it is noted that
the EIEL values are systematically lower than corresponding
photoionization values by an average of 10 meV. Considering
that the photoionization data were taken with higher resolu-

_ tion and, most importantly, were calibrated with several atomic
emission lines in the lamp output, the error most likely lies
in the EIEL data. This type of systematic error is common for
electron spectrometers due to changes in contact potentials,

caused by contamination of electrodes in the spectrometer.21’22

90

Although this error is small, it has a significant effect on
the quantum defects calculated for series members with large
n. However, for series members with small n, the EIEL quantum
defects should approach the photoionization values. For
example, from the Rydberg equation and an assumed IP of 13.00eV,
for n=8 a transition energy of 12.758 eV gives 6=0.500, while
transition energy of 12.748 eV gives 6=0.652. For n=4, a
transition energy of 11.889 eV yields 6=0.500 whereas ll.879<§J
gives 6=0.516. The quantum defects calculated from Fridth's
data continue to differ from the photoionization values as n
decreases. It appears that some of the lower members of
Fridth's p0 series may have been assigned incorrectly. This
is further exemplified by the limit calculated from the data
in reference 72, which agrees very well with the photoioniza-
tion limit, yet should be about 10 meV lower.

The above ideas are represented schematically in Figure
IV-7. Figure IV-Ladepicts the transition energies from the
ground state nitrogen lone pair orbital to Rydberg orbitals
as measured and assigned by Fridth.72 Also included are n+w*
transitions assigned in that work. In Figure IV-7b are hypo-
thetical transition energies to Rydberg states converging to
the second ionization limit, calculated from the quantum
defects reported in reference 72 for series converging to the
first ionization potential of CH3CN. The photoionization data
are shown in Figure IV—7c; the dotted lines were calculated

from the photoionization quantum defects.

91

 

I 3.0

l2.5 '—

Energy (eV)
17>
<3
I

".5—

 

990

8pc

790
660

Spa
560

So?

590

460

4pn

1n>n’

Thrfl'

490

7hbfl'

n-brr‘

(o)

(b)

080

9808‘“,-

do
7pc

660

Spn
Spa

650
560

Spn
Spa

550

41:10-

4px

490

450

300

7px

990'

Si

Odo

600

Odo-

------- 40:

(c)

 

".00

Figure IV—7.

 

Transition Energy Diagram for Excitation from the 58
(a) EIEL transition energies from
Reference 72; (b) Hypothetical Rydberg transitions cal-
culated from the quantum defects of Reference 72 for
series converging to the ground state of the ion;

(C) Photoionization data of this work.

Orbital of CH3CN.

92

From Figure IV-7a and IV-7b it is easily seen that Fridth's
p0 series converging to the second ionization potential is in-
consistent with the series converging to the first ionization
potential. The small discrepancy between the calculated
series and the photoionization series is not unreasonable (see
reference 33). Moreover, it seems that the highest energy
transition labeled w-n* by Fridth would be better assigned as
4pc, and the third n-n* component is more likely 450. These
changes would make the EIEL results self-consistent as well
as consistent with the photoionization results. The series
with 6=0.92 is therefore assigned as so. Figures IV-5 and
IV-6 and Table IV-3 have been labeled accordingly.

3. Autoionization: 900-800 A

PIE curves for CH CN+ and CD CN+ from 800 to 900 A

3 3

are shown in Figure IV-8. The structure in CH3CN+, which as
noted earlier is weak, but prominent, would appear to be auto-
ionization; yet the CD3CN+ PIE in this region is smooth and
structureless. No optical or EIEL spectra have been pub-
lished of this region with which to compare the photoioniza-
tion data. In general, one would not expect so much difference
between a protonated compound and its deuterated analog. If
autoionization structure is observed in one, it Should also

be observed in the other, although any vibrational structure
may be different. This leads one to wonder if the structure
in the CH3CN+ PIE curve is an artifact. The PIES in Figure

IV-8 are reproducible and therefore it is unlikely that a

difference of this type is an instrumental artifact; the

93

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94

only parameter which is different for the two PIE'S is the
mass setting.

+ . .
The m/e of CH CN 15 41; the most intense or second most

3
intense peak in the mass spectra of many longer-chain ali-

71 However, the possibility

phatic nitriles falls at m/e=4l.
that the structure in the m/e=4l PIE is caused by another
aliphatic nitrile is unlikely for three reasons. First, there
is no evidence in the mass spectrum of the acetonitrile used
in this investigation of longer chain aliphatic nitriles.
Second, it is unlikely that a longer chain aliphatic nitrile
would introduce autoionization structure which is so sharp as
the observed structure. The photoelectron spectra of longer
chain nitriles81 show only broad and featureless bands for
states to which Rydberg series in this region would converge.
Rydberg states, being very similar in structure to the ionic
states to which they converge,33 would exhibit autoionization
which is also broad and featureless. Third, the same auto-
ionization structure is also observed in the CHZCN+ fragment
PIE at m/e=40. Other aliphatic nitriles also have a fragment
at m/e=40, but its intensity is so low (3-5% of m/e=4l)71
that it could not account for the structure in the CHZCN+ PIE.
(Consistent with the observations for the deuterated parent,
this autoionization is also absent in the PIE curve for CDZCN+J
Another possible source of the structure in the 800-900 A
range is reaction with, or Penning ionization by, excited

argon. This would have to arise from argon in the background

air. This might seem to be a very remote possibility, but

95

(1) much of the structure corresponds with optically popu-

latable argon states;82 (2) with a background air pressure

of 10..5 torr, 107 argon atoms are in the light beam at any

one time (argon is 0.033% of air) and the structure represents
variations of only about 30 ion counts/s on a background of
about 1500 counts/s; and (3) Ar+ is known to react with mol-

83 Interference

ecular hydrogen to produce ArH+ (m/e=4l).
from ArH+ was also considered in the ion cyclotron resonance
ion-molecule reaction study of acetonitrile by Gray.62

There are three reactions that could account for ions at

m/e=40 and 41:

(1) Ar* + CH CN + ArH+ + CHZCN

3
(2) Ar* + CH3CN + Ar + CH3CN+
(3) Ar* + CH3CN + Ar + CHZCN+ + H.

Ar+ is not responsible because the structure lies below
the ionization potential of argon. Reaction (1) alone would
not account for structure in the CHZCN+ PIE, and reactions (2)
and (3) should be just as probable for the deuterated compound
as for the protonated compound. Thus, argon would not seem
to be the cause of the structure. However, to be absolutely
sure, the PIE at m/e=4l was measured for a 1:5 argon: acetoni-
trile mixture. The argon pressure was l.0><10—4 torr, a 3Xl04
fold increase over the highest possible background pressure.
There were no significant changes in the CH3CN+ PIE. The
structure in question can thus be assigned to autoionization

from Rydberg series converging to the second excited state of

the acetonitrile parent ion.

96

 

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97

From Turner's55 ionization potential and vibrational

assignments for the second excited state of CH CN+, four

3
series converging to four different vibrational states can
be identified. The series are shown in Figure IV-8 on the
bars near the top of the figure and are listed in Table IV—4.
From the quantum defects the series is assigned as an So type.

The same Rydberg states are expected to autoionize in

CD3CN; however if the vibrational frequencies are sufficiently

closer in CD3CN the autoionization structure may be so over-
lapped that the series are unidentifiable. Indeed the vibra-
tional structure of the second excited state in the photo-
electron spectrum of CD3CN is much less distinct and more over-
lapped than in CH3CN;66 the same should be expected of the
Rydberg series converging to this state.
4. The Threshold Region: 1000-1040 A

In order to precisely determine the adiabatic ioniza-
tion potentials, and to resolve as much structure as possible,
PIES of the parent ions in the threshold region were acquired
with a monochromator bandpass of 0.42 A (5 meV at 1010 A);
they are presented in Figure IV-9. Recall from Chapter II that
in the absence of autoionization a PIE would be a series of
steps, each step being the threshold for a transition to a

- new state of the ion. The threshold region of CH CN+, for

3
which there are two well defined steps at 1016 and 1012 A,
demonstrates this nicely. Judging from the high intensity

and location of the first peak of the photoelectron spectrum

98

 

 

 

 

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‘3 ° ‘
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TerjjijTjIIIUIjjITjIl'TIIIjIIIIr

 

1000 1010 1020 1030
WAVELENGTH (Angstroms)

Figure IV-9. CH3CN+ and CD3CN+ PIE Curves: 1000-1040 A.

n:

99

of CH3CN, there is little doubt that the first step is the
threshold for the transition to the ground vibrational state
of the ground electronic state of the ion (the adiabatic
ionization potential). The second step must be a vibronic
transition to an excited vibrational state of the ion, and is
a transition which has not been resolved from the 0+0 transi-
tion in the photoelectron spectrum. It is only because Rydberg
states converging to excited vibrational states of the ion are
strongly predissociated that these steps are so distinct.
The third very small step at 1010 8 is in all probability due
to autoionization, as will be discussed below.

The CD CN+ PIE in this region is significantly different

3

from that of CH3CN+. There is only one poorly defined step
at 1012 g, followed by an increase in intensity which, like

the third step in the CH CN... PIE, can be attributed to auto-

3
ionization. Close examination shows also that the initial
step in the CD3CN+ PIE is at a slightly shorter wavelength
than the corresponding rise in the CH3CN+ PIE. It appears
that the first ionization potential of CD3CN is higher than
that of CH3CN. Indeed, one photoelectron study67 has reported
a difference in the first ionization potential of CH3CN and
CD3CN, in the same direction indicated by this work.

The adiabatic ionization potential is unambiguously de-
fined as the difference in energy between the neutral mole-
cule in its electronic, vibrational and rotational ground state

and the ion in the lowest vibrational and rotational level of

a particular electronic state.22 Since it is certain, by

100

comparison with the photoelectron spectrum, that the initial
step of the acetonitrile PIE is the transition from the ground
vibrational state of the neutral to the ground vibrational

state of the ion, the problem remains to determine the loca-
tion of the rotationless transition on the step. This

requires an approximation since the resolution of the instru-
ment is far from sufficient to resolve rotational structure.

The 5 meV bandpass is equivalent to 40 cm—l. Before discussing
the rotational structure of the steps, the effect of the instru-
ment function should be considered.

The effects of the instrument function have been discussed
in the literature,84 and the results are presented in Figure
IV-lO. A step function is assumed for the photoionization
cross section for a single transition from the neutral to the
ion and is convolved with a triangular slit function, which

85 The result is

has been shown to be a good approximation.
a sigmoidal curve whose inflection point is at the true
threshold and for which a line drawn tangent to the inflection
point intercepts the energy axis at 6/2 (6 is the slit width)
below the true threshold. Application of this result to the
threshold PIES shows that the slit width accounts for about
half the breadth of the rise of the steps. The remainder,
then must be due to the rotational envelope within the vibronic
transition.

The rotational structure within a vibronic photoionization

transition has not been well characterized experimentally or

theoretically. In only a very few cases has some rotational

101

PIE

 

 

 

Figure IV-lO. The Effects of a Triangular-Slit Function on
a Step Function. (a) Triangular-Slit Function;
(b) Triangular—Slit Function convoluted with
a Step Function.

102

structure been experimentally resolved (the photoelectron
spectra of H2,86 HF and DF87), and the theoretical deriva-

tion of the applicable selection rules is complicated by
coupling of the ejected electron's angular momentum, which

can take on several values, with the total angular momentum

of the ion.22 However, the selection rules for bent ABz—type
molecules have been worked out,22 and it is clear that rota-
tional transitions in P, Q and R branches are allowed. It is
likely that at least P- and R-branch, and perhaps even Q-branch,
transitions will be allowed in acetonitrile.

Because the PIEs were measured at room temperature, the
thermal distribution of populated rotational states of the
neutral molecule is available for ionization. Therefore a
photoionizing vibronic transition will be accompanied by a
rotational envelope. An approximation is needed for the tran-
sition probabilities within the rotational envelope which in-
cludes the thermal distribution of rotational states of the
neutral. The transition probability then can be convolved
with the slit function and a step function to obtain a model
PIE which could be used to fit the experimental data in order
to arrive at an accurate ionization potential.

The model chosen to approximate the transition probability
‘ within the rotational envelope, convoluted with the slit

function was a Gaussian distribution centered at the ioniza-

tion potential. The choice of a Gaussian distribution is

easily checked by fitting the data, and it will be shown that

103

it is a good approximation to the transition probability.
The assumption that the rotationless transition is at the
center of the rotational envelope is somewhat less certain.
However, a survey of ordinary absorption spectra24 supports
this assumption within the limits of resolution of these
experiments. Moreover, this is the same assumption that is
used in photoelectron spectroscopy, where the maximum of the
lowest energy vibronic peak of an electronic band is assigned
as the ionization potential.

For a Gaussian transition probability within the rotational
envelope, the PIE (Ep), the photoionization efficiency at

photon energy E ,is calculated by integrating the Gaussian

P
from -0 to E

E _ _ 2
I p e b(B IP) dE, (IV-l)

PIE 03) = a
p 0

where E is the excitation energy above the ground state of the
neutral, IP is the ionization potential, 9 determines the
width of the step and 3 represents the height of the step. An
example of this model is given in Figure IV-ll; the ionization
potential is at the inflection point on the rise of the step.
To test this model and to locate the inflection points as

accurately as possible, the thresholds were fit by means of
74

'_ KINFIT 4 with a, b, and IP chosen as adjustable parameters.

The results of the fits, which demonstrate that a Gaussian is
indeed a reasonable approximation, are presented in Figure
IV-12. For CH3CN+ the second step was also included in the

fit by integrating the sum of two Gaussians, one for each step,

Energy
(0)

 

1
El
Energy
(b)

Figure IV-ll. Integration of a Gaussian Transition Proba—
bility. (a) Gaussian function; (b) The
integrated Gaussian function.

105

Jlllllllllllllllllllllljllllllllll

 

PIE (Arbitrary Units)

 

 

 

 

l I l I I I I ' l l I l l l‘ 'I ' I 1 I ‘7“ l I I 1 I I I I T
1000 1010 1020 1030
WAVELENGTH (Angstroms)

Figure IV-12. The Pit of the CH3CN+ and CD3CN+ Thresholds.

106

with different parameters a, b, and IP. In this way the funda-
mental vibrational frequency of the excited vibrations can be
obtained.

The ionization potentials arising from the fits are indi-
cated with arrows in Figure IV-12, and are listed and compared
with values reported by other investigators in Table IV—S.

In general the agreement is good, but merits some comment.

For CH3CN note that all the values, except those of references
65 and 66, are higher than the ionization potential determined
in this work. Probably the reason is that the vibronic transi-
tion corresponding to the second step of the PIE was not
resolved, which would cause one to arrive at a higher ioniza-
tion potential. This is definitely the case for the photo-
electron results for which spectra werepublished, and
although neither instrumental resolution nor PIE curves were
reported, this was probably the case with the previous photo-
ionization results too, judging from other publications of

the investigators. The ionization potential of reference 66
is obviously too low.

The limits of error reported for this work are realistic.
The PIE curves can be calibrated to better than i 0.1 R with

atomic emission lines in the light source output, and differ-
ences in the ionization potential of i 0.3 3 were clearly
discernible in the quality of the fit. The propagated sum of
these two errors is i 3.6 meV at the ionization potential.
The error limits reported in Table IV-S, r 5 meV, reflect the

uncertainty that the ionization potential is at the center of

107

Table IV-S. First Ionization Potentials of CH3CN and CD3CN.

 

 

 

Reported Value (eV) Methoda Reference
CH3CN 12.194 i 0.005 PIMS This work
12.19 i 0.01 PIMS 65
12.205 i 0.004 PI 64
12.22 i 0.01 PI 63
12.20 : 0.01 PE 67
12.21 PE 55
12.12 PE 66
CD3CN 12.235 : 0.005 PIMS This work
12.23 i 0.01 PE 67

%

aPIMS-—Photoionization mass spectrometry; PI-Photoionization
without mass analyses; PE-Photoelectron spectroscopy.

108

the Gaussian transition probability assumed for the fit.

The ionization potential of CD CN is indeed higher than

3
the ionization potential of CH3CN by approximately 41 meV.

This difference agrees with the results of reference 67, the

only published ionization potential of CD3CN, and is further
substantiated by a shift to higher energy in CD3CN (compared

to CH3CN) of Rydberg series converging to the ground state of

the ion.72 This isotope shift must be the result of a differ-
ence in the difference of zero-point energies between the neutral
and the ion in the two molecules.

1

The second step in the CH CN+ PIE is 53 meV (427 cm- )

3
above the ground vibrational state of the ion. From a com-
parison of this energy difference to the vibrational frequencies
of the neutral molecule, the most likely assignment for the

step is the transition from the ground vibrational state of

the neutral to the vibrational state of the ion with a single
quantum of excitation in the CCN bend (v8). The vibration V8
has a fundamental frequency of 362 cm.1 88 in the neutral and

is the lowest frequency normal mode in acetonitrile. The only
other remotely possible assignment would be the transition to
v=l of the next lowest frequency vibrational mode of the ion,
the CC stretch (v4), for which the frequency in the neutral is
920 cm-1.88 It is extremely unlikely that the CC stretching
frequency in the ground electronic state of the ion would be
less than half that in the neutral molecule.22

The ratio v8(CH3CN):v8(CD CN) in the neutral molecule is

3

109

1.094, and from this ratio one would predict V8 in CD3CN+ to
be approximately 390 cm”1 (48 meV). This would put the mid-
point of a step in the CD3CN+ PIE for the threshold for a
single excitation of V8 at 1009.4 3. However, the midpoint
of the second step in the CD3CN+ PIE curve is at 1010.3 fl,

the same wavelength as the third step in the CH3CN+ PIE. If

the second step in the CD3CN+ PIE is the vibronic threshold
for the single excitation of v8 it would require the frequency

of V8 in CD3CN+ to be 295 cm_l, which is much smaller than

the predicted value. The autoionization in this region is
from Rydberg states converging to the first excited state of
the ion and is not isotope dependent. Because the second

step in the CD CN+ PIE is at the same wavelength as the third

3
. +
step in the CH3CN PIE, and because assigning it as the

vibronic threshold for the single excitation of v8 would re-
quire an unreasonably low frequency for V8 in CD3CN+, the

second step in the CD3CN+ PIE and the third in the CH3CN+ PIE

are most reasonably attributed to autoionization. The vibronic

threshold for the single excitation of v8 in CD3CN+ is most

likely hidden under the autoionization as a consequence of
CD3CN's higher ionization potential.

The transition in CH3CN+ to the first excited level of v8,
.the CCN bend, has important consequences for the structure of
the ground electronic state of the ion. In general, photo—
ionization transitions are adequately described by the Frank-

21,22

Condon principle. The Franck-Condon principle assumes

that the electronic and nuclear motions of a molecule are not

110

coupled, and therefore a transition probability can be resolved
into electronic, vibrational and rotational factors. The
intensity of a vibrational band in an electronically allowed
transition is then proportional to the vibrational factor,

commonly called the Franck-Condon factor, 2, where

 

 

<wvlwv>

I
wv and wv are the vibrational wavefunctions of the lower and

24 For the Franck-Condon factor to

upper states respectively.
be non-zero the product (0; 0;) must be symmetric with respect
to all symmetry operations common to the final and initial
electronic states; that is, F(w;) x F(w;) = I (totally
symmetric).

point group;88 its photoelectrcn

CH CN belongs to the C

55,56,57

3

spectrum

3v

as well as the Walsh diagram of CHBXZ type

predict that the ground electronic state of CH CN+

3
is also C3v' The CCN bend is an "e" vibration88 and therefore

molecules89

the first excited vibrational level (v=l) belongs to the E
representation. The ground vibrational level (v=0), as always,
belongs to the totally symmetric representation Al. The

product E x A = E and the vibronic transition from the ground

1
vibrational level of the neutral to the first excited vibra-
tional level of V8 in the ion is not allowed within the assump-
tions of the Franck-Condon principle. It appears that the

Franck-Condon principle is not a good approximation for transi-

tions to the ground state of CH3CN+

However, this is not completely surprising. The ground

electronic state of CH3CN+, which results from the removal of

111

a n electron from the CEN bond, is orbitally doubly degenerate
(a 2E state) and is therefore subject to Jahn-Teller distortion.
The Jahn-Teller theorem states that if a non-linear molecule
(not Cmv) has an orbitally degenerate electronic state when the
nuclei are in a symmetrical configuration, then the molecule

is unstable with respect to at least one asymmetric displace-
ment of the nuclei that may lift the orbital degeneracy.2

In other words, there can be a coupling of the electronic
motion with at least one of the non-totally symmetric vibra-
tions such that the vibronic levels which were degenerate by

24 '

way of the orbital degeneracy are split.

The "E" vibrations of an E electronic state of the C
21,22,24

3v

molecule are Jahn—Teller active. That is, they may

interact with an E electronic state to split its degeneracy.

If vibronic coupling of V8 with the 2E state of CH3CN+ is

invoked, the transition in question is allowed. To demon-

strate this the vibronic wavefunction wev and the dipole

24 The probability of a

l 2

transition moment MeV must be used.
'2

fl

0 o 0 I I ' M = A >
Vlbronlc tranSltlon is given by I ev I<wevlul¢ev I
where fl is the dipole moment operator. For a component [Mevl2

I
to be non-zero P(wev) x F(wev) must belong to the same species

as a component of 0. The initial state vibronic wavefunction

wev (the ground vibrational level of the ground electronic
state of the neutral) belongs to the Al representation. The
species of the final state are found by the product

0' '
F(¢e) x F(wv)24 which is ExE, and three vibronic levels result:

112

A A and E. The product T(¢ev) x F(wev) is then

1' 2

(A1+A2+E) x A = A +A +E. The 2 component of 0 belongs to the

l l 2

Al representation and the transition to the Al vibronic level
is allowed by 02. The x and y components of fi belong to the
E representation so that the transition to the E vibronic
level is also allowed.

The magnitude of the energy splitting of the vibronic
levels is impossible to determine from the PIE curve, since
only one step for the transition to the v8 vibronic levels is
evidenced in the PIE curve. It is possible that the splitting
is not resolved. However, it could also be that only one of
the two allowed transitions has sufficient intensity to be
observed. The completely analogous situation exists in the
high resolution photoelectron spectrum of HCN.78 The photo-
electron band of the ground electronic state of HCN+, which
corresponds to the removal of a CEN n electron, has a vibra-

tional component assigned to the single excitation of v2, the

HCN bending vibration. The ground electronic state of HCN+

is doubly degenerate (a n state), as is v2. Thus transitions
to the first excited level of v2 in a n electronic state of
22,78

the ion are allowed only if there is vibronic interaction
(the Renner-Teller effect in the case of linear molecules).
When vibronic interactions are considered, transitions to two
vibronic levels of v2 are allowed. However, only a single
transition is resolved.

By analogy with HCN it is reasonable to assign the second

step in the CH3CN+ PIE curve as a transition to a vibronic

113

level of the singly-excited CCN bend. It should be noted that
the above arguments apply equally well to CD3CN+. The DCN
bending vibration has also been observed in the photoelectron
spectrum of DCN,78 thus supporting the contentions that the
analogous transition in CD3CN is obscured by autoionization.
There are several other possible vibronic transitions to
the ground electronic state of the ion as is demonstrated by
the photoelectron spectrum (Figure IV-l). There is the hint

of a step at ~994 A in the CH CN+ PIE curve (~993 A in the

3

CD CN+PIE curve; see Figures IV-S and IV-6) and by comparison

3
with the photoelectron spectrum this feature probably corres-
ponds to a single excitation of the CN stretch (v2). 02 is
an Al mode and the transition to 02 is allowed by the selec-
tion rules imposed by the Franck-Condon principle. Although
all the vibronic transitions observed in the photoelectron

spectrum will contribute to the PIE curves, the tresholds are

hidden by autoionization structure.

E. Fragment Ion PIEs

Fragment ion PIEs are most often smooth and featureless
and reveal little information about the structure of the parent
ions or the fragments. The most important piece of informa-
tion to be gleaned from a fragment ion PIE is the appearance
potential (AP). Ideally, one would like to determine the 00K
AP — the energy of the transition from the ground rotational
vibrational and electronic state of the neutral to the state of

the parent ion from which fragments are produced in their

114

ground rotational, vibrational and electronic states with no
kinetic energy. This is the 00K thermochemical threshold
for the fragmentation. However, as discussed in Chapter II
the observation of fragmentation at the true thermochemical
threshold depends on the formation of parent ions with the
necessary internal energy, which dissociate sufficiently
rapidly that a detectable number of ions are produced.

Another complicating factor is the thermal distribution
of populated rotational and vibrational states of the neutral.
Neutral molecules in excited rotational and vibrational states
will be available for fragmentation at lower photon energies
than molecules in the ground rotational and vibrational state.
Experimentally, the most obvious effect of the thermal energy
is to introduce a low intensity, slowly-rising onset —— a
"thermal tail" -- to the fragment ion PIEs. If one scans from
high to lower photon energy, the "thermal tail" approaches the
base line asymptotically, and if the data are acquired with a
sufficiently sensitive instrument, the tails will continue for
several hundred millielectron volts below the thermochemical
threshold.

The effects of thermal energy of the neutral has been con-

sidered in the literature and suitable corrections have been

‘. devised. Guyon and Berkowitz,84 have shown that the internal

thermal energy of the neutral shifts the fragment ion PIE
curves to lower energy by an amount equal to the average thermal

energy of the neutral.

115

In essence the thermal energy ET of the neutral adds to
the photon energy with an intensity proportional to the number
of neutral molecules at ET. When the fragmentation rate is
not kinetically limited, the fragment PIE curves are often
linear above threshold. In this case, the experimental AP is
found by extrapolating the linear region of the curve to the
base line. The 00 AP is then calculated by adding the average
thermal energy of the neutral to the experimental AP. It has
also been shown that in this case the departure from linearity
at the foot of the PIE occurs at the 00K AP.49’84 This is im—
portant because it serves as a check for the value found by
adding the thermal energy.

When fragmentation is kinetically limited, the tail is
more prominent and often extends to lower energies with more
intensity than can be accounted for by the thermal energy of
the neutrals. In this case, the tail is due to both the thermal
energy of the neutral and a slowly increasing fragmentation
rate. The onsets are gradual and the threshold regions are
often curved. The best way to determine the AP is to extrapo-
late the upper regions of the PIE curves. This method will
yield an AP which is greater than the thermochemical threshold
and should be considered only as an upper limit.14

Early PIMS investigators often assigned the AP as the
lowest energy at which a fragment could be detected, i.e. some-
where on the low energy tail. This procedure is obviously

49,84

incorrect when kinetic effects are not important, but it

could have some merit when the fragmentation rate is kinetically

116

limited since it would yield a lower value for the AP than
that determined by extrapolation. However, since it is impos-
sible to determine how much of the tail is due to thermal
energy of the neutral and since the experimental AP would
depend strongly on the sensitivity of the instrument with
which the data were taken, this method yields an unreliable
result. The experimental AP could be to higher or very much
lower energy than the thermochemical threshold; the extrapo-
lated value is preferred.

In the following sections the acetonitrile fragment ion
PIE curves are presented and discussed. The experimental AP's
are summarized in Table IV—8 at the end of this chapter. The
heats of formation of several neutral species will be useful
for the following discussion. These are listed in Table IV-6
along with several unit conversion factors.

1. CHZCN+,CD2CN+

The lowest energy fragmentation process in acetonitrile

is loss of a hydrogen atom (deuterium atom) to produce CH2CN+
(CDZCN+). The PIE curves of CHZCN+ and CD2CN+ are shown in
Figure IV-13. As previously mentioned, the thresholds for
production of these ions (~880 A) are in a blank region of the
photoelectron spectrum. Therefore in the region from threshold
up to about 820 A, where the second excited state of the
parent ion becomes available, the fragmentation is from states
of the parent ions populated by autoionization. Some auto-

ionization-like structure, which correlates well with auto-

ionization structure in the CH3CN+ PIE curve, is readily

117

Table IV-6. Heats of Formation of some Neutral Species and

. a
some Useful ConverSlon Factors.

 

 

l eV/molecule
l kcal/mole

96.49 kJ/mole
4.184 kJ/mole
aFrom reference 91 except AHfo of CD

were estimated from AHfO of the pro
that differences were due to differences of zero point energies.

(kJ/mole) (kJ/mole)
CH3CN 94.5 87.
HCN 135.5 135.
CH 592.5 595.
CN 431.8 435.
H 216.0 218.
CD3CN 82.4
DCN 132.5
CD 591.7
D 219.8 221.
1 eV 2 8066 cm-

CN, DCN and CD, which
onated analogs by assuming

118

 

 

 

 

 

 

 

 

I.“
a
02c2N+

J1 llllllLl I l11__]

O] ITIYITIIT'IVWI]
60 800 900

x

2: ‘\\
n.

+ J
JJILllJJLJllJll1411114111][JLIJIJJJ
1ITT'[TijjijIlWITTrflil'IIlTlfilII1

600 700 300 900
Am

Figure IV-13. CHZCN+ and CDZCN+ PIE Curves.

n)

119

apparent in the CHZCN+ PIE curve between 820 — 860 A. The
rise starting at 820 A and continuing to shorter wavelengths
can be attributed to the threshold for the second excited
state of the parent ion. The PIEs level off at about 700 A
and decrease at shorter photon wavelengths due to competition
with other fragmentation processes.

The APs determined by extrapolating the linear region of
the PIE curves between 860 and 880 A to the base line and

subtracting one-half the photon band width are 886.0 1 0.5 a

+

(13.99 _ 0.01 eV) for CH CN+ and 876.0 r 0.5 A

2
(14.15 t 0.01 eV) for CDZCN. The error limits reflect the
uncertainty of extrapolating the data to the base line. The

AP reported by Dibeler and Liston65 for CHZCN+ (14.01 i 0.02 eV),
determined by an unspecified procedure, agrees within experi-
mental error with the value found in this work. The AP of
CDZCN+ has not been previously determined; however it is
reasonable that its value is greater than that of CHZCN+. If
the H-atom (D-atom) loss is considered to be a simple extens—
ion of a C-H (C—D) bond, both the protonated and the deuterated
compounds will dissociate over the same potential surface.
Because the zero point energy of a C—D stretch is lower than
that of a C—H stretch, in the former case more energy will be
required to get over the top of the surface and the AP of the
deuterated fragment will be at a higher energy. To quanti—
tatively account for the difference in the APs of the protona-

ted and deuterated fragments, the zero point energies of both

the neutral and the ionic transition state would have to be

120

known in both cases. However, since one can only guess the
structure of the transition state, this would require a dif-

ficult and uncertain analysis.48

There are several reasons to believe that the H-atom loss
is sufficiently fast that the experimental APs are not sig-
nificantly affected by the kinetics of the fragmentation.
First, since this is the lowest energy fragmentation it is
not in competition with any other fragmentation pathway at the
threshold. Competition almost always causes the experimental
AP to be shifted to higher energy than the true thermochemical
threshold. Second, the PIES are very linear in the region
just above threshold. Fragments whose intensity is kineti-
cally limited usually exhibit PIEs with a slowly rising thresh-
old and with considerable curvature. Third, the small curved
section at the foot of the PIEs can be completely accounted
for by the internal thermal energy of the neutrals.

The average thermal vibrational energy of neutral CH3CN
at 300°K (calculated by using the statistical thermodynamics
expression for independent harmonic oscillatorsgo) is
23 meV/molecule. For CD3CN it is 29 meV/molecule. The
average thermal rotational energy (3/2KT) is 39 meV at 3000K.
When the sum of the vibrational and rotational thermal energy
CN and 68 meV for CD

(62 meV for CH CN) is added to the experi-

3 3
mental AP of the fragments it puts one at the point of depar-

ture from linearity at the foot of the PIEs. This is the

predicted result for fragment ion PIEs whose intensity at

threshold is not kinetically limited. Thus it can be con-

cluded that the experimental APs accurately reflect the true

121

thermochemical threshold for the fragmentation process.

Addition of the rotational and vibrational thermal energy of

the neutral to the experimental APs gives 0 K APs of

14.05 i 0.01 eV for CHZCN+ and 14.22 r 0.01 eV for CDZCN+.
From the 00K APs,the 00K heats of formation are easily

calculated. The calculations are shown in Table IV—7 and the

results are: AHfO(CH CN+) = 1235 kJ/mole and

2
AHfO(CD2CN+) = 1234 kJ/mole. There are no currently accepted
literature values with which to compare these numbers.
2. CHCN+,CDCN+

CHCN+ and CDCN+ are the fragments with the next higher
AP; PIE curves are shown in Figure IV-14. The curves are
smooth and structureless and there is little to be said about
them. The leveling off at about 700 A, followed by a decrease
in intensity at shorter wavelengths, is due to competition
with other fragmentation processes. An important feature,
however, is the curved region at the foot of the PIEs.
Although it is not readily apparent in Figure IV-14, the
curvature extends over a much wider region than in the
CHZCN+ and CDZCN+ PIEs, and it cannot be accounted for by the
thermal energy of the neutral. This is evidenced by the fact
that when the average thermal energy of the neutrals is added
to the experimental AP, the result is significantly lower than
the point of the departure of the PIE from linearity. This is
a sure sign that the intensity of these fragments is kineti-

cally limited at the thermochemical threshold and the experi-

mental APs will be higher than the true thermochemical threshold.

122

Table IV-7. Calculation of AH of CH CN+ and CD CN+.

 

fo 2 2
+ +
CH3CN + CHZCN + H Aern = AP (CHZCN )
+ +
AHf (CHZCN ) - AP (CHZCN ) + AHf (CH3CN) - AHf(H)

AP00K(CH3CN+) = 14.05 ev 1356 kJ/mole

AHfO(CH2CN+) = 1356 + 95 - 216 = 1235 kJ/mole

 

CD3CN + CDZCN+ + D Aern = AP(CH2CN+)

+ + _
AHf(CD2CN ) - AP(CD2CN ) + AHf(CD CN) — AHf(H)

3
APd>K(CD2CN+) = 14.22 ev 1372 kJ/mole

AHfO(CD2CN+) = 1372 + 82 - 220 = 1234 kJ/mole

 

123

PIE
/

 

 

 

 

 

 

 

 

alllllllllll
trilliillilllj
800 900
.“1
l
HC2N+ \

\\\
JllJlJ_llllllLll1111h¥jllll
tfilI'lltvffiTIfITIfiIIWI111111I

600 700 800 900

MR)

Figure IV-l4. CHCN+ and CDCN+ PIE Curves.

124

Kinetic limitation is to be expected in this case since frag-
mentation to produce CHCN+ (CDCN+) is in competition with

dissociation to produce CH CN+ (CDZCN+).

2

The experimental APS determined by extrapolating the
region 760-790 R to the base line are 813 r 2 3 (15.25 i 0.04eV)
for CHCN+ and 807 r 2 8 (15.36 i 0.04 eV) for CDCN+. Because
of the curvature at the foot of the PIES, the extrapolation is
much less certain than for CHZCN+ (CDZCN+), and this is reflec-
ted in the error limits. The AP reported for CHCN+ in refer-
ence 65 is 15.1 r 0.1 eV. This is significantly lower than
the AP determined in this work and the difference may well be
due to the (unspecified) procedure used in reference 65 to
determine the AP.

The currently accepted literature value for the heat of
formation of HCCN+ (1551 kJ/molegl) was calculated by using
Dibeler and Liston's AP65. This value is 150 meV lower than
would be calculated from the AP determined in this work; how-
ever, the PIE curves reported here indicate that 1551 kJ/mole
Should be considered only as an upper limit for the heat of
formation. The tails on the PIES continue to lower energy
with more intensity than can be accounted for by thermal
energy alone, and it is estimated from the data of this work
that the literature value may be more than 30 kJ too high.

There are two possibilities for the neutral fragments: two
H-atoms (D-atoms) or H2(D2). The formation of H2(D2) is
energetically more favorable by about 4.5 eV and is most cer-

tainly the pathway near threshold. Fragmentation to produce

125

two H-atoms (D-atoms) is estimated to be energetically possible

at about 19 eV (650 8); however, there iS no evidence that this

pathway contributes to the PIES,even at energies above 19 eV.
Since the heat of formation of CDCN+ has not been reported

it is worthwhile to calculate an upper limit; by assuming D2

as the neutral product and by using the experimental AP, the

upper limit for the heat of formation (2980K) of CDCN+ is

51564 kJ/mole.

+
2 2

+ . . .
The CH2 PIE curves (Figure IV-15 are very Similar to

the CHCN+ and CDCN+ PIE curves and Show even more curvature

3. CH +,CD

at the thresholds. This is to be expected Since this fragmen-
tation process is in competition with two other pathways; the
experimental APS should be considerably higher than the thermo-
chemical threshold. Due to the curvature of the PIE curves

in the threshold region it is difficult to accurately extrapo-
late the data. Nevertheless, extrapolation from the 730-750 A
region yields 811 i 2 A (15.29 i 0.04 eV) for CH + and

2

805 r 2 R (15.40 i 0.04 eV) for CD2+.

The AP reported by Dibeler and Liston65 for CH2+
(14.94 i 0.02 eV) is considerably lower than the result of this
work and its accuracy is questionable. CH2+ was the lowest
intensity fragment for which Dibeler and Liston determined an
AP, and it can be assumed that its intensity was near the
limit of sensitivity of their instrument.

It iS difficult to estimate exactly how much more sensitive

. . +
the MSU PIMS instrument 18, but the PIE curves of CH3+ and H2CN

 

126

 

 

 

 

 

T-
(”X"
M‘M ‘2
”8'50! Qfl¢5 xx
‘\
g x
‘t \
\
c02+ \
l L l l IgL I I I I1 I I I J
4.%::}*.:::}::..}....{....,....,
600 700 800 900
AM)
....
_ .:.-:§;.52%‘
g9»: .
3.
e \
a \
CHi+ \\
\
\
I I I I I4 I I I J I IJ .I I J. I l I I I Ij I I J J;
I I I I : I I T '1' I I 1 f7 I I T I I [I I I l I T I ‘1
600 700 y 800 900
AM)
Figure IV-15. CH2+ and CD2+ PIE Curves.

127

(to be described subsequentlY), which are about one-third the

intensity of CH2+ (see Table IV-2), were recorded with a

Signal-to-noise ratio of better than 100. This fact amply
demonstrates that the MSU instrument is considerably more
sensitive than that of reference 65. Yet, the (low) AP re-
ported by Dibeler and Liston is beyond any measurable intensity

in the CH2+ PIE curve reported here. Even if the first

detectable Signal of CH + was assigned as the AP, the value

2

would be higher than 14.94 eV.

The heat of formation of CH2+ (1398 kJ/molegl) has been

accurately determined by several methods (from the spectroscopic

IP of CH2 92 and by photoionization of CH3 93 and CH4 52. The

thermochemical threshold for the formation of CH2+ from CH3CN
calculated from this value is 14.92 eV when the neutral frag-
ment is assumed to be HCN. If the neutral products are H + CN,
the thermochemical threshold is 20.2 eV. HCN must be the
neutral product in the region investigated in this work. The
experimental AP for CH2+ appears to be kinetically shifted
above the thermochemical threshold by about 370 meV.

One can conceive of two different mechanisms by which the
decomposition CH3CN+ + CH2+ + HCN could proceed. The H—CN
bond could be formed simultaneously with the rupture of the
C—C bond and a C-H bond, a one-step process; or a hydrogen
atom could migrate to the cyanide group, followed by a rupture
of the C—C bond, a two-step process. As will be Shown below,

the CH + and H CN+ data strongly suggest that the two-step

3 2

mechanism is the most likely pathway.

128

There is no currently accepted literature value for the
heat of formation of CD2+ to which to compare the AP of this
work. However, the experimental AP is most likely kinetically
shifted above the thermochemical threshold by even more than
the AP of CH2+, since deuterated ions always dissociate more

48

Slowly than their protonated analogs and more excess energy

is necessary to produce the deuterated ion with a measurable

+

intensity. An upper limit for the heat of formation of CD2

calculated from the experimental AP is 1441 kJ/mole. This

value can be improved upon by assuming that the kinetic shift
.1.

is at least equal to that of CH2 (370 meV). The result is
that AH (CD +) S 1399 kJ/mole.
f 2
298
+ +
4. CH3 ,CD3
The CH3+ and CD3+ PIE curves, which are smooth and

featureless, are Shown in Figure IV-l6. These curves are ex-
pected to be competitively Shifted even more than the previ-
ously-discussed fragment PIES since this fragmentation channel
is in competition with at least three others. The APS measured
by extrapolating the data between 760 and 790 A are 808 r 2 A

(15.34 i 0.04 eV) for CH3+ and 797 i 2 R (15.55 i 0.04 eV)

for CD3+. The APS of these ions from CH3CN have not been

previously reported.

The heat of formation of CH +

3
93'94'95 and the currently accepted literature value is

91

has been accurately deter-
mined
1095 kJ/mole. The thermochemical threshold calculated from

the heat of formation is 14.85 eV, which is approximately

490 meV below the experimental AP. The thermochemical threshold

129

P15

c 0+ .'.

 

 

l
600 700 800 900

PIE

 

 

I l l J _: l

l I l 1
j I I I I 1

l J I l
l l I l lj 1 I I l A I
600 700 8 O 900
A (X)

 

 

Figure IanG. CH3+ and CD3+ PIE Curves.

130

is also 70 meV lower than that of CH2+, yet the experimental

AP is greater than the experimental AP of CH2+

Clearly, the fragmentation pathway to form CH3+ is suppressed

by 50 meV.

until well above the thermochemical threshold.
The heat of formation of CD3+ is not available in the

literature, and it is therefore worthwhile to calculate an

upper limit from the AP. AHf(CD +), corrected for the kinetic

3

shift according to the results for CH +

3 , is found to be

51103 kJ/mole.

It is surprising that the CH + experimental AP is greater

3
than that of CH2+; in general one would not predict this
result. Usually in the threshold region the fragment ion with
the lower thermochemical threshold is produced at a higher
rate and thus is more intense. It is therefore expected that
CH3+ would be produced with measurable intensity at lower
energies than CH2+. However, the difference between the thermo-
chemical thresholds is small, and it is possible that the rate

constant for the CH + fragmentation near threshold increases

3
more Slowly with energy than that for CH2+. The CH3+ fragmen-
tation may Simply be too slow to compete with the CH + frag-

2

mentation at photon energies near the CH2+ threshold, and

CH3+ is therefore not detected until the photon energy is

above the CH2+ AP.

Another possible explanation for the anomalous AP would
be a rapid migration of a hydrogen atom from the methyl group

to the cyanide group. If the hydrogen migration was faster

than the CH3+ fragmentation near the CH3+ thermochemical

131

threshold, there would be few parent ions with three hydrogens
on the terminal carbon from which CH3+ could be produced.

CH + would not be detected until an energy was reached at

3
which the rate of fragmentation is comparable to the rate of
rearrangement. On the other hand, the intensity of CH2+
might be enhanced since its fragmentation channel would not
be in competition with that to form CH3+.

It is not unreasonable that such a migration would occur.

Migrations of hydrogen atoms are common for gas phase ions,96

as well as for ions in solution.97 CH3CN+ is a radical ion
and therefore there is a half-filled orbital to which a hydro-
gen could easily migrate. Moreover, hydrogen migration would
not require an especially low potential barrier. The CH3+
threshold is more than 3 eV above the ground State of the
parent ion. In solution hydrogen migrations occur at thermal
energies,97 and it is conceivable that migration would be
energetically possible in the gas phase at energies far below
the threshold for formation of CH3+ from CH3CN.

It is interesting to speculate about possible structures
for a rearranged parent ion. Some possibilities for which

one hydrogen atom has migrated from the methyl group are shown

below.

132

\ ‘\ +
C = N C = N: C = N
/ / / \
H-C-+ H—-C- H-—C-+ H
| I I
H H
(l) (2) (3)
+ H\ + H\ +
C = N: C = C = N- C — C E N — H
, / I / y /
H-C H H H H
1
H
(4) (5) (6)

Many more structures can be drawn, including those with a
C—C double bond and a C—N single bond, with no multiple bonds,
or with only one hydrogen atom on the terminal carbon. Struc-
tures such as those Shown above would seem most likely to have
an effect on the CH3+/CH2+ fragmentation ratio Since they are
probably more stable than structures with no multiple bonds,
whereas those with a C-C double bond and a C—N single bond
would be more likely to fragment at the C-N bond. Structures
with only one hydrogen on the terminal carbon would preclude
fragmentation to form CH2+.

The stability of the above structures with respect to one
another and to CH3CN+ with the methyl group intact would be
an important factor for determining the possible contribution

of each. However it is difficult to judge the relative stabili-

ties, especially considering that a rearranged molecular ion

133

could be in an excited electronic state and that no molecular
ions of these structures have ever been studied. Ions (1-6)
are drawn primarily to demonstrate that fairly reasonable
structures for a rearranged parent ion can be constructed.
There is some evidence that structure (5) might be more
stable than the others. Ketenimine, the neutral equivalent
of (5), has been identified as a photolysis product of
acetonitrile.98 Moreover, SCF-MO calculations Show ketenimine
to be the next most stable molecule with a C—C—N framework to

99 Structure (5) has also been proposed as the

acetonitrile.
geometry of the ion at m/e=4l in the mass spectra of longer-
chain aliphatic nitriles.71 The CH2+ fragmentation channel
might be on an excited state surface of the manifold of states
belonging to structure (5).

Another factor which should not be overlooked when ration-
alizing a fragmentation mechanism is the stability of the
products. The more stable products are almost always favored.9
Structures (3)-(6) imply that the neutral fragment for the
CH2+ fragment channel is hydrogen isocyanide (CNH), while
structures (1) and (2) would lead directly to hydrogen cyanide
(HCN). This would suggest that structures (1) and (2) might
be more important for the CH2+ fragment channel.

Unfortunately, the PIE curves do not provide structural
information about the parent ion at energies above the first
fragmentation threshold or about the fragment ions. The
anomalous CH +

3
suggest that a hydrOgen migration does influence the CH3+(CD3+

AP, together with the above ideas, would

)

134

fragmentation, as will be discussed in the next section.

+ +
5. HZCN 'DZCN

The HZCN+ and DZCN+ PIE curves are Shown in Figure IV-l7.

HZCN+ and N2+ both have m/e=28, and even though the acetonitrile
sample was thoroughly degassed, autoionization structure due
to N2+ was readily apparent in the HZCN+ PIE curve. The N2+
PIE curve is very distinctive, being predominated by auto-
ionization, which made it possible to correct the H2CN+ PIE
by subtracting from it a scaled N2+ PIE. The curve shown in
Figure IV-l7 is the result of the subtraction.

The APS determined by extrapolating the region 750 - 780.A
are 797 r 2 R (15.56 i 0.04 eV) and 794 r 2 3 (15.61 t 0.04 eV)

for H CN+ and D CN+, respectively. The difference in the AP

2 2
of the protonated and deuterated ion may reflect both disparate
kinetic Shifts and zero point energy differences.

The reaction channel for the neutral fragment CH is 3.5 eV
lower than the channel for C+H, and it can be safely assumed
that CH(CD) is the neutral fragment of this dissociation at
threshold. The extrapolated AP for HZCN+ results in a cal-
culated heat of formation of <1009 kJ/mole. For D CN+ the

2
result is <997 kJ/mole. There is no currently accepted litera-
ture value for AHf(H2CN+) (or AHf(D2CN+)) from which to deter-
mine the kinetic Shift, and since this fragmentation channel
is in competition with several otherS,the values should be
considered only as upper limits.

It is difficult to conceive of a mechanism for the forma-

tion of HZCN+ in which two hydrogens from the methyl group are

135

 

 

 

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136

transferred to the cyanide group in concert with the breaking
of the C—C bond. It is most probable that this fragmentation
proceeds via a rearranged parent ion intermediate in which
two hydrogens have migrated from the terminal carbon to the
nitrile moiety. Again it is entertaining to speculate about

possible structures for a rearranged parent ion, and in this

case about the structure of the fragment ion also. Some possi-
bilities for HZCN+ are:
H + + + . +,,H
C=N H—C=N: H—CEN-H C=N
/ I \
H H H
(7) (8) (9) (10)

On the basis of the PIE curve alone it is not possible to
make a definite assignment of the structure of the ion at
m/e=28. There is thermochemical evidence for structure (9),
protonated hydrogen cyanide. The proton affinity of HCN in

100'107 and the heat of for-

the gas phase has been measured,
mation of H—CsN—H + is 942 kJ/mole, a value that is 67 kJ/mole
lower than AHf determined from the experimental AP. This dif-
ference is reasonable, considering the kinetic shift of the

experimental AP, and thus structure (9) is consistent with the

available data.

Some structures which can be drawn for H3C2N+ for which

two hydrogens have migrated from the methyl group are:

137

— C H — C H
+ +/
= N — H C = N — H H — C = C = N
/ / + \
H H H
(11) (12) (13)
/H
2— c' '1'“
- \. . / \
/ N — H C = C H
I / +
H H H
(14) (15)

Structures (11) and (12) would lead most directly to ion (9).
The photoionization data do not provide any evidence for the
contribution of structures (13)-(15), but at excitation energies
above 20 eV, structures with two hydrogens on the nitrogen

must be formed Since NH2+ is detected in the electron impact

62
mass Spectrum.

The relative intensities of CH2+, HZCN+ and CH3+ in the

photoionization mass Spectrum are l:0.29:0.24, respectively.
Without the benefit of the experimental AP and PIE curves of
these ions this would be a rather unexpected result. In

general, one would not predict that CH2+ would be four times

as intense as CH3+. However, this is easily explained when

hydrogen migrations are taken into account. The rapid migra—
tion of hydrogen reduces the number of excited parent ions

with the methyl group intact from which CH3+ must be flormed and

thus limits the intensity of CH3+. The fact that CH2+ and

+ . . .
HZCN are more intense than CH + means that the migration must

3

138

be more rapid than the CH3+ fragmentation, even at 21 eV.

The detection of HZCN+ and DZCN+ provides clear evidence

that hydrogen and deuterium atom migrations do occur, at

least at photon energies above ~15.6 eV. The APS of CH2+ and
.1.

CH3 (15.29 and 15.34 eV respectively) are only slightly lower

than that of HZCN+ (DZCN+), and it is reasonable that migration

is important also at the fragmentation thresholds for these ions.

139

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CHAPTER V.

CONCLUSIONS AND SUGGESTIONS FOR FURTHER WORK

The acetonitrile PIE curves yield a remarkable amount of
information for a photoionization mass Spectrometry investi-
gation. From the parent ion curves, accurate ionization
potentials for the Be (CEN bonding) and 5a1(nitrogen lone pair)
orbitals of CH3CN and CD3CN were determined and it was found
that the Be ionization potential is isotope dependent. Prev-
iously unresolved vibrational structure was observed in the

CH CN+ PIE, from which the vibrational frequency of the CCN

3
bending mode of the ground state of the parent ion was measured.
This in turn led to the conclusion that the Jahn-Teller effect
is operable in this ionic state. Rydberg series converging
to the first and second excited electronic states of the ion
were observed and definitive series assignments were made.

The fragment ion PIE curves provided less structural
information than the parent ion curves, but they did reveal
the important fragmentation pathways and mechanisms. Accurate
heats of formation of HZCCN+ and DZCCN+ were determined. The
remaining fragment ion APS were kinetically shifted, but com-
parison with accurate literature values for the protonated
fragments provided corrections for their deuterated counter-
parts. Although the derived heats of formation are only upper

limits for these fragments, the data should be useful to scien-

tists interested in the ion chemistry of acetonitrile.

140

141

Often a thesis research project raises new questions.
The unanswered questions resulting from this investigation
lead to the suggestion of further experiments that should help
provide a more complete understanding of the ionization and
fragmentation of acetonitrile.

Although the CCN bending vibration was resolved in the

CH CN+ PIE curve, it was not observed for the deuterated ion.

3
It was suggested that this transition was obscured by auto-
ionization in CD3CN+. A high resolution photoelectron spec—
trum of CD3CN should be able to resolve this feature and

would be useful for confirming the observations of the PIMS
experiment.

One of the shortcomings of any mass spectrometric experi-
ment is that only the m/e of an ion is measured, and one must
use other sources of information to infer the structures of
the detected ions. The PIMS data show that rearrangement of
the parent ions occurs at energies above the HZCN+ threshold,
and strongly suggest that a rearrangement is important at even
lower energies. However, the data reveal neither a precise
energy threshold for the rearrangement nor the structure(s)
of the rearranged ion. A potentially useful experiment in
this regard would be a matrix isolation study of the parent
ions. In a low temperature, inert matrix the parent ions may
well retain the rearranged geometry, and their structures
could be determined by means of standard spectroscopic tech-

niques such as infrared and visible—ultraviolet absorption

spectroscopy and Raman scattering, perhaps supplemented by ESR

142

measurements. The approximate energy at which the rearrange-
ment becomes possible could be determined by observing changes
in the spectra of the matrix-isolated ions as a function of
the ionizing energy. This technique has been successfully
applied to several ionic systems.102

The rearrangement of the parent ion raises questions about
the structures of the H2C2N+, HC2N+ and H2CN+ fragments (and
their deuterated counterparts). To which atoms on the carbon-
nitrogen framework are the hydrogen atoms bonded? The struc-
tures of these ions could also be studied with the matrix-
isolation technique.

The relative intensity and energy dependence of a fragment
ion PIE is a function of an energy-averaged fragmentation rate
constant and the number and distribution of parent ion states
populated with sufficient energy to fragment. From the PIE
curve one can determine an appearance potential and the energy
dependence of the ion yield, and a reasonable fragmentation
mechanism can often be deduced. However, several parameters
remain unknown; the kinetic and internal energy of the frag-
ments is not measured and the potential surface on which the
fragmentation occurs is not determined.
tron coincidence technique (PIPECO) is well suited for deter-
mining these parameters.21

Experimentally, PIPECO is very similar to ordinary PIMS,
with the added feature of an electron energy analyzer which

is most often constructed to detect only zero-kinetic energy

electrons. Only fragment ions that are produced in coincidence

143

with an electron of zero-kinetic energy are detected, and their
intensity is followed as a function of photon energy. Since
the photon and electron energy are precisely known, the exci-
tation energy of the parent ion is determined and the fragmen-
tation rate of state-selected parent ions is directly measured.
With a knowledge of the electronic structure of a parent ion
(i.e. the photoelectron spectrum), one can directly infer the
ionic state from which the fragmentation occur. Further, in
a PIPECO experiment the fragment ions are often mass selected
by their time of flight from the ionization region to the ion
detector. From the mass spectral line shapes (the intensity
versus time distribution of ions of a given mass) one can often
arrive at the kinetic energy release accompanying the fragmen-
tation. (More details on PIPECO can be found in reference 103.)
A PIPECO investigation of acetonitrile could be interesting
and informative. As a supplement to the PIMS data, it would
be useful for measuring the kinetic shifts of the experimental
APS, allowing more accurate heats of formations of the various
fragments to be determined. As an extension of the acetonitrile
investigation, it would provide a measurement of the state-
selected fragmentation rate constants, which in turn would
provide a more complete characterization of the fragmentation
mechanisms. Moreover, the rate constants could be compared
directly with those calculated with the statistical theory of
mass spectra.

Although some questions remain, it should be emphasized

144

that the photoionization mass spectrometric investigation re-
ported in this dissertation was highly successful. Acetonitrile
is the first molecule to be studied in detail with the PIMS
apparatus which was designed and constructed at MSU. The
instrument performed extraordinarily well and allowed the

study of processes too weak to observe with instruments which
are not computer-controlled. Valuable thermochemical and

kinetic information has been obtained for acetonitrile.

145

APPENDIX A

PIE curves are most reliably acquired by recording the
curve of a single m/e at a time, hence the mass spectrometer
is used most of the time in a fixed mass mode. However in
the course of an investigation it is often desirable to scan
the transmitted m/e to record a mass spectrum. The Extra-
nuclear quadrupole mass filter controller used in this
investigation does not have this capability but it does
have provisions for the addition of mass scanning circuitry.
The mass can be scanned via an externally supplied voltage
or current ramp. The following iseadescription of a digital
ramp generator that was designed and constructed as part of
this thesis research.

There were several design requirements to be considered
for use in conjunction with the MSU PIMS instrument. First,
it was desirable to be able to control the ramp generator
with the PDP-8/M computer that is used to operate many other
devices on the instrument and to also be able to manually
operate the device. Second, the ramp generator needed to be
linear to insure the linearity of the mass scale of a mass
spectrum. Third, the device needed t£> be stable over a long
period of time, and fourth, it needs to provide scan rates
over the range of 10 ms to several hours.

A block diagram of the device is shown in Figure A-l.

146

 

 

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147

The heart of circuit is a lZ-bit digital-to-analog converter
which receives a lZ-bit number from the PDP 8/M mini-computer
via an interface circuit or from a lZ-bit counter for manual
operation. Under computer control the DAC input can be set
to any desired value or incremented one bit at a time. The
manual control allows the input to be Set to a fixed value
via a thumb wheel switch or to be scanned by filling the
counter with counts from a variable rate oscillator.

The circuits are built on three separate wire wrap boards
which are connected with 3-M ribbon cable. The computer
interface board is mounted in a card cage in the computer
rack which provides access to all signals necessary for
communication with the computer. The other two boards, the
main logic board and the analog board, are mounted in an
aluminum box in a rack containing the mass spectrometer power
supplies. The circuits are constructed primarily from stand-
ard TTL integrated circuits.

On the circuit diagrams shown on the following pages,
connections with card edge connectors are indicated with open
arrows (-<(- ), those with 3-M ribbon cable with elongated
closed arrows (-—E>>), and connections between circuits on
the same board with standard closed arrows (—°-). Integrated
circuits are labeled with a chip number corresponding to their
location on the circuit board, and for ICs for which the
identity is uncertain the standard TTL chip type is also

indicated.

148

Figures A-2 and A-3 are schematics of the computer inter-
face circuits. Their locations on the computer interface
board are shown in Figure A-4. The circuit consist of a
lZ-bit counter (ll-13) and comparator (8-10) which are con-
nected to the computer lines (ACOO-ll) via latches (1-4).

The counters allow the mass to be scanned at a maximum rate
by incrementing the count with the increment line. The end
of a scan can be checked for with the computer via the §RP
line. This allows a preselected mass range to be scanned in
a minimum amount of time by eliminating the need to increment
and to check the value of a number in the computer accumulator.

The main logic board (Figures A-S to A-ll) consist pri-
marily of the circuits for manual control. It also contains
the line receivers for the connections with the computer
interface board. The connections from the computer interface
board are electrically isolated from the main logic board with
6Nl37 optoisolators (Figure A-S). This was necessary to
eliminate current loops which introduced 60 cycle noise on
the output of the D/A converter.

The manual control circuits consist of a crystal con-
trolled oscillator time base and divider (Mostek MK5009P,
Figure A-6), a one-through-ten frequency divider (Figure A-7)
and a twelve-bit counter (Figure A-8). The MK5009P is used

with a 409.6 KHz crystal. With its built-in frequency divider

and external control circuitry it provides an output frequency

that allows base scan times of 0.015, 0.105, ls, 105, l min.,

149

and 1 hour. The output of the base frequency generator goes

to a variable, one through ten frequency divider. The output
from this circuit is accumulated by the twelve-bit counter
whose outputs are connected to the digital-to-analog converter
via multiplexers (Figure A—8). The multiplexers allow selec-
tion of input from the computer or themanual operation counter.

The manual operation counter can be set to a preset I
value with thumb wheel switches (Figure A-9). In addition
provisions were made to set the counter to all low or all high
and to select continuous or single scanning (Figure A-lO).

The input to the D/A is displayed with seven-segment LEDs.

The analog board (Figure A-12) contains only the
digital-to-analog converter (Datel model HZlZBMC). The
circuits were originally constructed with the digital-to-analog
converter on the main logic board, however there was excessive
pickup of digital noise on the analog output. This problem
was most easily eliminated by placing the digital-to-analog
converter on a separate circuit board. The analog output of
the converter is connected to the quadrupole power supply

with a short BNC cable.

150

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LIST OF REFERENCES

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