THE CONDENSATION OF SOME TERTIARY DIMETHYL AMYL CAHBINOLS
HITH PHENOL IS THE PRESENCE OF ALUMINUM CHLORIDE

A DISSERTATION

Submitted to the Faculty
of
MICHIGAN STATE COLLEGE
of Agriculture and Applied Science

In partial fulfillment of the Requirements
for the degree of Doctor of Philosophy

by
Ralph Lawrence Guile

1958

ProQuest Number: 10008320

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ACMOmLjjGMENT
To Dr* R* C* Huston* the writer wishes to
acknowledge his appreciation for the guidance and
helpful suggestions which have made possible com­
pletion of this work*

331592

Contents
Page
Introduction--------------

1

Historical----------------

£

Theoretical-----

7

Experimental
>

------- - -

Materials
General

- - -

---------

- -

15
15

Alcohols
2-methyl heptanol-2

---

16

Z, 5-dimethyl hexanol-2

-----

£* 4-dimethyl hexanol-£

----------

18

--------

19

Z, 5-dimethyl hexanol-2

- - -

18

£-aethyl-5-ethyl pentanol-2--------

19

2, 4* 4-trimethyl pentanol-2

£0

-------

Zf 5, 4-trimethyl pentanol-2-------

21

2, 5, 5-trimethyl pentanol-2

24

Condensations with Phenol
Derivatives

---

----------------------

---

Proof of Structure

£5
28

----------- ----------- .—

£9

Alkyl Benzenes----------------

29

Nitration of Alkyl Benzenes----------------

55

Oxidation of p-nitro Alkyl Benzenes

---------

55

Reduction of p-nitro Alkyl Benzenes

- ----

55

Di&zotizatioa of p-amino Alkyl Benzenes------

54

Isolation of Phenol and Derivatives---------

55

Matelson Synthesis of £, 4, 4-trimethyl-----2-p~hydroxyphenyl pentane -

55

Contents

1
Introduction

As a contribution from this laboratory in 1956 Huston and Hsieh (1)
reported the condensation of tertiary butyl, tertiary amyl, and the tjhree
possible tertiary hexyl alcohols with phenol in the presence of aluminum
chloride.
In 1937 Huston and Hedrick (2) published results on the condensation
of the tertiary heptyl alcohols with phenol using aluminum chloride as
the condensing agent*
Extension of this work to the tertiary octyl alcohols by Huston and
Anderson (5) covered the action of methyl ethyl n-butyl and methyl ethyl
tertiary butyl carbinol with phenol under the same conditions.
To continue further investigation in tills field the dimethyl terti­
ary octyl alcohols were prepared and condensed with phenol in the presence
of aluminum chloride.

2
Historical

Preparation of the alkyl phenols to which class the principal pro­
ducts described in this thesis belong is accomplished by three general
methods*

First the direct alkylation of phenols using alkyl halides,

acyl halides, alcohols and alkenes in the presence of various catalysts.
Second the replacement of a variety of groups by a hydroxyl in alkyl
benzene derivatives*

And third by rearrangement of the alkyl phenyl

ethers.
Primary synthesis of all alkyl phenols reported herein is by the
first general method and synthesis for proof of structure by the second.
Since this work is concerned with the use of alcohols as alkylating
agents under the catalytic influence of aluminum chloride only those
papers dealing with condensations of alcohols and benzene nuclei in the
presence of aluminum chloride will be included in this review.
two facts should be mentioned in passing.

However,

First that as early as 1884

Auer (4) reported condensation between alcohols and phenols using as a
catalyst a mixture of zinc and zinc chloride and second that from that
time to the present alcohols and phenols have been condensed under the
influence of a great variety of catalysts some of which are phosphoric
acid, zinc chloride, magnesium chloride, alkali bisulfates, concentrated
sulfuric acid, and perchloric acid.
In 1897 Nef (5) mentioned the formation of diphenyl methane from
benzyl alcohol and benzene in the presence of aluminum chloride.

Re­

peating this work Huston and Friedmann (6) reported this reaction to
give a 50 percent yield of diphenyl methane.

A little later Huston

5
and Friedmann (7) continuing their previous work condensed successfully
mixed aliphatic aromatic secondary alcohols and true aromatic secondary
alcohols with benzene.
In 19E4 Huston (8) extended this reaction of benzy1 alcohol using
phenol, anisole, and phenetole in a similar manner to benzene*

He re­

ported yields of the alkylated products as 45, 45 and 50 percent re­
spectively*

Huston and Sager (9) 1916 attempted to condense various

primary alcohols with benzene*

negative results were obtained for

methyl, ethyl, propyl, iaopi'opyl, n-butyl, isobutyl, isoamyl, phenyl
ethyl and phenyl propyl alcohols.

However, allyl alcohol gave a 16 per­

cent yield of a condensed product — allyl benzene.

Huston and Hewmann

(ID) followed this work by condensation of allyl alcohol and phenol.
This led to the conclusion that only those alcohols in which the alpha
carbon atom was a member of a benzene ring or was double bonded would
condense under the action of aluminum chloride.
Later Huston, Lewis and Grotemut (11) reported condensation between
phenol and benzhydrol, methyl phenyl earbinol and ethyl phenyl carbinol.
Benzhydrol giving a much larger yield of alkylated product than benzyl
alcohol they stated that here was additional evidence of the effect of
unsaturation of the alpha carbon atom on condensation for both the alpha
carbon atoms in benzhydrol are members of an aromatic unsaturated benzene
ring.
Huston and Davis (12) found that the tertiary alcohol triphenyl
earbinol reacted with benzene to give triphenyl methane and not tetraphenyl methane.

The reaction between triphenyl earbinol and phenol has

not been reported.

4
Other papers by Huston and co-workers (13) condensing benzyl or
halogenated benzyl alcohols with phenol or halogenated phenols, ereeols
or halogenated eresols followed*

Mono and di substituted derivatives

were the products*
Further to investigate the effect of unsaturation of the alpha atoa
on condensation Huston and Goodemoot (14) compared the reactivity of
cyclohexyl, cyclopentyl, and cyclobutyl earbinols with, benzene*

They

showed a progressive increase in activity as the number of carbon atoms
of the ring was reduced from six to four.
Work with various di&ryl-alfcyl and dlalkyl-aryl earbinols by Huston
and Wilsey (15), Huston and Hradel (16), and Huston and MacGomber (17)
showed that they did not condense but dehydration of the alcohol occurred*
All these experiments indicated that uasaturation of the alpha
carbon atom, whether it was double bonded or a member of the benzene ring
favored condensation reactions of aliphatic and aromatic alcohols with
aromatic hydrocarbons and phenols in the presence of aluminum chloride.
With the work of Huston and Hsieh (1) the field of condensation
reactions of saturated aliphatic alcohols with phenol mid with benzene
in the presence of aluminum chloride was discovered*

In reacting iso­

propyl alcohol with benzene they obtained a fair yield of eumene (9) end
following this lead using simple aliphatic primary, secondary, and terti­
ary alcohols discovered that primary alcohols did not condense with
either phenol or benzene, secondary alcohols condensed with benzene
(or Its homologues) and tertiary alcohols with phenol under the influ­
ence of aluminum chloride as a catalyst.

Huston and Fox (18) using the

5
simple tertiary alcohols already condensed with phenol by Hsieh namely
tertiary butyl, amyl and hexyl alcohols found that they condensed also
with benzene,

Tzukervanik

(19) reported the condensation of some

simple secondary and tertiary alcohols with benzene and toluene obtain­
ing results similar to those of Huston and Hsieh and Huston and Fox but
explained them by a different mechanism*
Since tertiary aliphatic alcohols condensed readily with both
benzene and phenol an extension of this work to higher homologues of
that type of compound seemed logical.

Hence Huston and Binder (20) con­

densed the tertiary heptyl alcohols with benzene and Huston and Hedrick
(2) condensed these same alcohols with phenol.
Soon afterwards work was started in this laboratory upon the con­
densation of the tertiary octyl alcohols with phenol and benzene.

Huston

and Sculati (21) condensed tertiary dimethyl n-amyl, isoamyl, active amyl
and secondary amyl carbinols with benzene.

Huston and Anderson (5) in­

vestigated the reaction between methyl ethyl n-butyl and methyl ethyl
tertiary butyl earbinol and phenol,

Huston and Breining (22) described

the condensation of diethyl a-propyl and diethyl isopropyl carbinols with
benzene.
This present work is a continuation of the investigation on the con­
densation of tertiary aliphatic octyl alcohols under the influence of
aluminum chloride with phenols and benzene.

In specific it deals pri­

marily with the condensation between phenol and the various dimethyl
amyl carbinols*
The only one of the substituted phenols prepared as principal pro­
ducts of this reaction and reported herein that has been,to the writer*a

6
knowledge, prepared end identified in the literature is <, 4, 4-tricethyl
2—p-hydroxyphenyl methane*

It is the subject of a patent by Hester (23)

who prepared It from phenol and diisohutylene under the action of HgSO^.
It was also prepared and reported by 8 atsison (24)*

7
Theoretical
In all cases of Ganderssatlone between alcohols and aromatic hydro-*
carbons in the presence of aluminum chloride it has been shown by Huston
and eo-workers that the alpha carbon atom of the alcohol must fee under
strain such that the hydroxyl group is activated.

This activation is

present where the bond between carbon and the oxygen of the hydroxyl is
relatively unstable* thus beasyl and allyl alcohols both of which con­
dense readily can fee represented %

the following formula*

it

n

**' **
C6BSl”= pj3iO*H

i. it
H«c !c s ^ cV

*

o »H

8

the electron pair (a) forming the bond between Q and the 0 of the
hydroxyl is attracted strongly by both the -0H and the G atom resulting
**
*
in a bond such as found in a molecule of chlorine
s Cl
.* t 01
■*. s which
is unstable and hence reactive.
When we Consider various primary * secondary and tertiary alcohols
the existant conditions may be represented as follows.
B
JUC-*5 OsH
*• <$ ••
S

H

B
R
SjC-^j 0»H-------- UtC---VoiH
•• <$..
.. (£,*■
E

Relatively then the electron pair (b) is closer to the hydroxyl group
in tertiary alcohols than in secondary or primary and closer to the
hydroxyl in secondary alcohols than in primary.

In tertiary alcohols

the bond between G and 0 approaches ©ore nearly the type of bond in a
*#
molecule of hydrogen chloride Ii : Cl t which we know is a highly
reactive compound.

Therefore, we have an activated hydroxyl in tertiary

8
alcohols and w© would expect condensation.

Similarly less condensation

Would be expected with secondary alcohols and still less with primary
ones,

Experimental results are found to support this view for in gen—

era! tertiary aliphatic alcohols condense more readily and with higher
yields than secondary aliphatic alcohols while condensation of primary
aliphatic alcohols takes place only under much more drastic conditions*
that the carbon and oxygen bond in tertiary aliphatic alcohols is
reactive is also supported by the ease of dehydration of such alcohols
and the ease of replacement of this hydroxyl group by halogen of a
halogen acid*
Since condensation first teas observed between

tertiary

aliphatic

alcohols and aromatic hydrocarbons there have been several mechanisms
advanced to explain the course of the reaction* none of which have been
conclusively^ established.

Due to the use of different catalysts* tem­

peratures and solvents the results are not always strictly comparable,
but there have been evolved three possible mechanisms that merit atten­
tion* These mechanisms for convenience will be designated as follows*
1* Alkyl halide formation plus Friedel-Crafts Reaction
2. Aiken© formation plus condensation
3* Ether formation plus rearrangement
and will be discussed briefly, confining the presentation to that appli­
cable to tertiary aliphatic alcohols with the understanding that the
mechanism for primary and secondary alcohol condensation may or may not
be similar to those given for tertiary alcohols.
Each of these mechanisms is an attempt to explain the path by which
condensation can take place with the net result of water being

9
split off between the hydroxyl group of the alcohol and the para hydrogen
of the aromatic ring a©
I.

RjCOH + HC6H4QH

13-> R5C-C6H4OH + H^O

While AlClg is a good, dehydrating agent this simple conception of intermolecular cleavage of water as represented above does not account for
all the phenomena of the reaction nor does it suggest how the elimination
of water is actually accomplished.
1* Alkyl Halide Formation plus Friedel-Crafts Reaction
This mechanism was proposed by Tzukervanik and Haaarova (25) who
observed that after the first phase of the condensation between tertiary
aliphatic alcohols and benzene there were present all the components, such
as

analkyl halide, olefin, an excess of AlGl^ and HC1required

for the

Friedel-Crafts reaction and the condensation of olefines witharomatic
hydrocarbons.

From this they outlined a scheme of reaction applicable

to any tertiary alcohol and benzene.

Illustrated with tertiary butyl

alcohol it was
II. {GH5)gCOH +> AlGlg ---> AlClgOC(CHg)3 + HG1

lit. A1G1^)G(0H5)3

> CHgGzCHg + AlGlgOH

es3
I?.

CH«? + HG1

^ (GHg)gG-Cl

tT* (CHg}gG—Cl *f CgHg-- > (GH3)gC—CgHg + HG1
However, this mechanism is not completely satisfactory for it seems
unlikely that an aluminate can form as in equation II. In view of the
fact that it is not easy to replace the hydroxyl hydrogen of a tertiary

10
alcohol.

Further, Hedrick (26) in this laboratory attempting to test the

validity of Tsukervanik1s conception added a tertiary alcohol to aluminum
chloride suspended in an inert solvent and observed almost instantaneous
evolution of hydrogen chloride and heat.

This evolution of hydrogen

chloride would not be expected to occur if the alkyl halide formation
was an intermediate step*

It is significant also that an addition of a

solution of phenol in petroleum ether to the same mixture did without
evidence of further reaction, give 18 percent of the alkyl phenol expected
which was a much smaller yield than that obtained under ordinary conden­
sations between the same alcohol and phenol*
2.

Alkene Formation plus Condensation

The mechanism of alkene formation was offered by McKenna and Sowa
(£7) for the alkylation of benzene using alcohols and boron trifluoride
as a catalyst and is applicable to either primary, secondary or tertiary
alcohols. Shown for normal butyl alcohol it is
F I . CHgC^CHgCHgGH —

BF
^
4 G%SHgC=CH£ + HgG

BF*
VII. CHgCHgCH^CHg + C6H6—

CHs
CH5CH2-C-C6%
H

That normal and secondary alcohols give identical products as do iso
and tertiary alcohols is evidence of this mechanism.
McGreal and Miederai (28) have suggested a like mechanism for the
use of ZnClg as a catalyst and Welsh and Drake (29) believe this path
is probable in the condensation of aryl substituted carbinols with
phenol in the presence of aluminum chloride.

Where the alcohol employed

11
is incapable of dehydration eg- benzyl alcohol, benzhydrol, ana triphenyl
earbinol they suggest the reaction may proceed in effect by elimination
Of water from the hydrorxyl group and nuclear hydrogen a procedure which
they use to account for the reaction between triphenyl earbinol and
phenol at elevated temperatures without a catalyst*
Certainly unsaturated hydrocarbons do Gondense with aromatic hydro­
carbons using aluminum chloride as a catalyst as shown by numerous
workers (5Q).
Evidence against such a mechanism is slight but it should be men­
tioned that McKenna and Sowa used a catalyst other than aluminum chloride
and a much higher temperature than employed in the Huston method and con­
sequently obtained condensations between primary alcohols and benzene.
In contrast Huston and Sager (9) have shown that primary alcohols will
not react with benzene in the presence of alurainum chloride under ordi­
nary conditions*
Olefin formation and alkyl halide formation as intermediates are
not mutually independent in all cases, for according to Grosse and Ipatieff
(51) the presence of a hydrogen, halide is often necessary for reaction*
In which case they assume its action to consist in the addition to the
olefin to form an alkyl halide which then reacts with the aromatic
hydrocarbon whose G to H bond is activated by the metal halide*
Ether Formation plus Rearrangement
Briefly this mechanism consists In the formation of an ether of
phenol end then its rearrangement into the substituted phenol itself*
It seems probable that if alkyl ethers were formed as intermediates they

12
might rearrange into alkyl phenols for Smith (52) has reported the re­
arrangement of ra—oreayl Isopropyl ether,

tertiaiy

butyl

isobutyl

se­

condary butyl —, isopropyl phenyl ethers and p-cresyl isobutyl ethers when
treated in the cold with aluminum chloride*

He prepared th© ethere by

treating an alkali salt of the phenol with an alkyl halide*
VIII*

CgHgOtfa + RC1

» G6H5QR + MaCl

Rearrangement was effected by the addition of an equal molecular amount
of aluminum chloride.

Similar works are numerous (33)*

However, the formation of alkylphenyl ethers as intermediates is
questionable*

Her* and Weith (34) did report a yield of 10 to 12 percent

of diphenyl ether from aluminum chloride and phenol at reflux temperature*
Nieviand (35) using boron fluoride with phenol and methyl, ethyl, and
isopropyl alcohols obtained ethers and substituted ethers.

Dehydration

was given as the first step in the progress of this reaction.
Gl&sien (33) has pointed out that In alkylating the alkali salt of
phenol with a halide of an unsaturated alkene the ether Is not a neces­
sary intermediate for phenylalkyl ethers under the conditions of forma­
tion do not rearrange to alkyl phenols.

Thus allyl bromide and sodium

phenolate in a medium of alcohol gives a 90 percent yield of the allyl
ether but in benzene medium there is only a 30 percent yield of the
ether and a 70 percent yield of ortho allyl phenol.
It is significant also that Huston has reported good yields of the
alkylated hydrocarbon in the condensation of tertiary alcohols and
benzene, anisol© and m-croaylsiethyl ether (1) end the condensation of
benzyl alcohol with anisole and phenetole (8) in which reactions there

IS
is no possibility of ether formation*

Also no alkylphenyl ethers have

been isolated even in traces in this laboratory from aluminum chloride
condensations between tertiary aliphatic alcohols and phenol {1, 2, 5).
lit general no mechanism yet reported seems completely satisfactory*
In this laboratory (26) some work has been done in an attempt to ex­
plain the color phenomena observed in condensations between phenol and
tertiary aliphatic alcohols as due to the formation of a complex ion
or molecule much as phenol forms with ferric chloride, but such an ex­
planation is supported by very little evidence*

A similar mechanism

with the formation of addition compounds and ionization has been sug­
gested by Daugherty (57) for the Friedel-Crafts reaction.That the path
of condensation between tertiary aliphatic alcohols and phenol and
those same alcohols and benzene is different seems highly probable
based on th© observation of reaction progress*

The color formation

noted in condensations with phenol has not been observed in condensa­
tions with benzene nor has the splitting of long branched allyl chains
been demonstrated in condensations with phenol*
At present in this laboratory (38) a mechanism based on addition
products between aluminum chloride* alcohol, and phenol followed by
rearrangement is being considered*

The idea is new only to this parti­

cular field for addition products with AlCl^ have been reported (39)
and their existance and formation postulated as an explanation of the
catalytic action of several catalysts (40) - In brief this theory is;
that a catalyst unites with the substance catalysed through some of
the electrons of the outer shell of one of the atoms of the molecule*

M
The sew arrangement of electrons end atoms In th© fTpolymoleoulen is net
stable at the temperature of inaction, and rearrangement of atoms as
well as electrons then take place to form systems which are more stable*
The theory as applled^ln this particular field is promising and timely*

15
Experimental Data
Materials
Korm&l amyl, isoamyl, secondary amyl, and active amyl bromides
were prepared from the correspending alcohols (Eastman, technical) by
the action of sulfuric acid and hydrobromic acid (41).
The bromides of diethyl earbinol and methyl isopropyl earbinol
were prepared by treating the earbinols with phosphorous tribromide.
Diethyl earbinol was Eastman technical (B* P. 110 -117° G) and the
methyl isopropyl earbinol m s prepared by a GriguardReactionbetween
isopropyl bromide and freshly prepared aeetaldehyde (4£).
Tertiary amyl chloride was obtained from tertiary amyl alcohol
(Eastman B* P. 100 — 102° G) by treatment with, concentrated hydros
chloric acid (45) or by passing dry hydrogen chloride gas into the
alcohol (44).
Tertiary butyl alcohol Eastman M. P. 25 - 25° 0 was used without
distillation to prepare diisobutylene.
Acetone used was of G. P* grade dried over sodium sulfate and
twice redistilled*
Magnesium turnings especially prepared for Griguard reactions were
used after being dried for several days over O&Clg*
Benzene was thiophene free, 0* P. grade*
Petroleum ether, B* P. 50 - 65° C.
Ether for Grignard reactions was anhydrous.
Each of the last three chemical© was dried over freshly cut sodium
before use.
Methyl iodide and acetyl chloride were both Eastman*s and used
without farther purification.

16
Phenol was twice redistilled and a one degree fraction used*
Aluminum chloride was Merk*s Reagent anhydrous sublimed*
Alcohols condensed wares
A* 2-methyl hept&aol-fc
B* 2, 5-dimethyl hexanol-2
0* 2, 4-dimethyl hexEnol"^
JD* 2, 5—dimethyl hexanol"*-^
E* 2-methyl—5~ethyl pentanol-2
E* 2 , 4, 4-triiiiethyl pentanol—2
G* 2 , 3, 4-trimethyl pentanol-2
H* 2, 3, 3-trimethyl pentanol—2
A*

GH* -

2-methyl heplanol-2
HI
0
- CH* - CHo - C - GH«

This aleohol was prepared by use of the Griguard reaction using
the Whitmore method (44) for preparing the Griguard Reagent and the
Edgar procedure (45) for the reaction of this reagent with a ketone
and subsequent hydrolysis of the resulting compound*

As this proce­

dure was used with slight modifications for the preparation of several
alcohols it is described in detail*
In a * dry three-liter three-necked round bottom flask fitted with
an efficient stirrer, reflux condenser, and dropping funnel are placed

^Extreme care must be taken to insure dry apparatus and reagents.
Also the reaction must be protected from the carbon dioxide and water
vapor of the air*

1?
first a few small crystals of iodine and then 98 gee (4 soles) of fresh
magnesium turnings {dried over GaCI^)* The bottom of the flask is
heated with a small flame imtil the iodine commences to vaporise and is
then allowed to Cool while the normal amyl bromide is weighed out*
Thirty cc of a mixture of four moles of the halide and SGO cc of anhy­
drous diethyl ether is then added directly to the dry magnesium.

After

the reaction has started and progressed for a few minutes 200 ee of dry
ether is added directly to the reaction mixture*

Then, 475 cc of the

above halide ether solution is placed in the dropping funnel and added
with stirring at the rate of a drop every second.
The remainder of the halide ether solution is diluted with 300 ee
of dry ether and added at the same rate*

Ether refluxes slightly during

the haiide-ether addition no external cooling being applied*

It is un­

necessary to heat the mixture after the ether-h&lid© solution has been
added but stirring is Continued four hours and then the mixture let
stand overnight before proceeding.
After the solution has stood overnight to it is added at the rate
of a drop a second four moles of very pure acetone in an equal volume
of anhydrous ether*

It is again let stand overnight and the next day

decomposed by pouring on water and ice*

The precipitated magnesium

compounds are dissolved by adding 10 percent HCl,(keep cool with ice
during the addition.)*

The ether layer is separated, washed with dilute

sodium carbonate, followed by distilled water and dried finally
anhydrous sodium sulfate*

over

18
Fractionated under reduced pressure ** a four mole run yielded
194 gms (37 percent) of a product B* P* 78 - 80° C at 30 mm.

Checked

as to physical constants this corresponded to the earbinol as described
in th© literature (46) and as prepared and reported in this laboratory
by Huston and Sculati (£1)*
B*

2» 5-dlmethyl hexanol-£

H
H
6
GH5 - CHg - C % - G - q - GHS
G % CH3

Using the above described method for E-methyl heptanol-E the bromide
of methylpropyl earbinol (secondary amyl alcohol) was substituted for
normal amyl bromide*

field from a four mol© preparation 80 gms (15 per­

cent of theoretical) boiling at 68° C ©t 15 smu

This product cheeked

as to physical constants with that prepared by Clark (47) and prepared
also in this laboratory by Huston and Sculati (21)*
C*

2* 4-dimethyl hexanol-2

H

H
0

e % - GHg - c --■ C - CH3

Prepared according to the method used for 2-methyl heptaaol-2 sub­
stituting the bromide of secondary butyl earbinol (active amyl alcohol)

**These tertiary alcohols dehydrate to some extent when distilled
under atmospheric pressure*

19
for normal amyl bromide*

Held from 4 moles was 72 gms (14 percent) of

a product boiling between 155 — 156° C at 748 mm*

The physical con­

stants of this product checked with those of the same earbinol prepared
in this laboratory (21) and reported in the literature (48).
0*

2* 5-dimethvl hexanol-2

H
CJHg — 6 — CHg —
CHg

H
0
— G — OHg
GSg

Prepared according to the already described method*
bromide used in place of normal amyl bromide.

Isoamyl

A four mole run yielded

268 {55 percent) of a product B. P. 68 - 70° C at 12 mm.

This was the

2, 5-dimethyl hexanol-2 as its physical constants cheeked with those
obtained in this laboratory by Huston and Sculati (21) and reported in
the literature (49).
B*

2-methyl—5—ethyl pentanol-2

If
a o
G % - C % - d - C - CHg
?®£ ® S
CHS
Prepared according to the already described method, using 5-bromopentane in place of normal amyl bromideB* P. 60 - 64° G at 15 mm.

field 7 percent of a product

This was used as the earbinol as it corres­

ponded to that prepared in this laboratory by other workers and re­
ported in the literature (50).

20

P.

£. 4. 4-trlmethyl neat£U3oI-£

CH5
ch5 - g 1

ghe

OH5

H
0
- c -

ch 5

OH 5

This alcohol was prepared by the method of Butlerow (51) with
slight modifications.
Two parts by volume of a quantity of like volumes of sulfuric acid
and water were mixed with one part by volume of tertiary butyl alcohol
and Hie mixture placed in a round-bottomed flask fitted with reflux
condenser and heated for twenty-four hours on a steam bath,
appeared.

two layers

The layers were separated by means of a separatory funnel

and the top oily layer was saved*

After being washed with water it was

dried over anhydrous calcium chloride*

It was then further dried by-

use of phosphoric acid anhydride followed by refluxing over freshly
cut metallic sodium.

The product was fractionally distilled and that

portion boiling 102 — 104° C at 756 mm was saved &a diisobutylene*
Into the diisobutylene at 10° C was passed gaseous hydrogen iodide,
generated by allowing water to drop on a mixture of red phosphorus,
iodine and send, until the diisobutylene was completely saturated with
hydrogen iodide.

The resulting iodide was washed with water until all

unused hydrogen Iodide had been removed.

Then to the iodide was added

the calculated amount of moist silver oxide.
quantities with vigorous stirring at 0° C.

This was added in small

zx
The resulting mixture was allowed to warm up to room temperature
sad. all the liquid removed from the precipitated silver iodide by vacuum
distillation.
parated.

This distillate consisted of two layers which were se­

The water layer was extracted three times with ether and this

extract was added to the oily layer which, after being dried with anhy­
drous sodium sulfate* was freed of ether at ordinary pressure and then
fractionally distilled.

From eight moles of tertiary butyl alcohol

was obtained 164 gtas (51 percent) of a product B. P. 51° C at 15 mm
or 144° 0 at 758 mm*
This fraction was used as £, 4, 4-trimethyl pentanol-2 as it
corresponded to the literature reported carbinol (51) and the earbinol
as prepared by other workers in this laboratory.
Jhu 5. 4-trtmethyl pentanol-g
I
H
|
as, - c - e - o CHS QHj CHg

This alcohol to the writer* s knowledge has not been reported in
the literature so several methods were tried.

Of these the preparation

of of 4-dimethyl pentanone-£ and its reaction with methyl®agneslum
iodide was the most satisfactory and will be described in detail.
1. Preparation of 5, 4-dimethyl pentanone-£.
A Grignard reagent was prepared in the usual fashion (44} using
798 gas of

1 — m e t h y l - J—bromobutane.

by the Gilman

The yield of C-rlgnard was determined

method (5£) of titrating a hydrolysed aliquoit, to be

4X£.S gas or a 45 percent yield*

22

Using a modification of the tShitmore—Bradertscher procedure for
preparing ketones (44) the Gri^aard reagent was added to 250. 5 gas
(2*95 moles) of acetyl chloride dissolved In 70S ee of dry ether
contained in a five-liter three-necked round-bottomed flask fitted with
reflux condenser? separatory funnel, and mechanical stirrer.

This addi­

tion was at such a rate that the ether refluxed and after three-fourths
of the reagent was added, an

additional 50 cc of acetyl chloride was
A white

placed in the reaction flask to insure its presence in excess*
precipitate formed which turned yellowish later in the reaction*

The

solution upon completion of addition of the reagent was allowed to stir
for four hours and then stand overnight*
The precipitate and filtrate were then poured on ice, the ether
layer separated and the water layer extracted three times with ether and
added to the ether layer.

The combined extracts were washed with one-

fourth of their volume of saturated aqueous potassium carbonate solution*
The solution was dried with anhydrous potassium carbonate and the ether
was then removed at ordinary pressure. The remaining residue was steam
distilled with aqueous potassium carbonate solution and the ketone was
salted out of the distillate with M&G1, separated from the water and
dried overnight with anhydrous sodium sulfate at zero degrees*

It was

then fractionally distilled collecting the fraction 155 — 140° 0 at
744 mm*

This fraction weighing 55 gms was a yield of 3.5 percent based

on l-sethyl-2-bromobutaae.
2* Preparation of 2> 5, 4—trime thyi pentanol—2*
Methylmagnesiuai iodide was prepared in the usual fashion by allow—
-i

a dry ether solution of methyl iodide *&o react wrth magnesium*

In

23

this case 0.7 of a mole of methyl Iodide was used.
To the Grignard reagent in a two—liter three—necked round—bottom
flask fitted with a separatory funnel, reflux condenser and mercury—
sealed mechanical stirrer was added the 56 gms of ketone obtained above
dissolved in an equal volume of anhydrous ether.

After the addition

which was made not faster than one drop of the mixture a second, the
solution was allowed to stand overnight.
in the usual manner by being poured on

The next day it was hydrolysed
ice and the basic magnesium

compound removed with 15 percent sulfuric acid*

The ether layer was

separated from the water layer which was extracted three times with
ether.

The combined ether extracts were shaken with solid sodium car­

bonate until basic.

T he sodium carbonate was then removed by washing

with distilled, water and the ether, and- the ether solution dried over
anhydrous sodium sulfate.

Ether was removed from the product and it

was fractionally distilled at 13 mm.
tained, boiling point 45 - 50° C*
ketone*

A thirty-six gram yield was ob­

This was 58*1 percent based on the

Physical constants were determinedupon this fraction.
Boiling Point — — — 151 — 153° G at 732am
tJ.30
Refractive Index ”
- 1*4400
20°

Specific Gravity

- *8532
oqO

Surface Tension

-28.1 dynes

24
***

5» 5—trljaethyl peataaoI-2

E
CHg 0
CBg — CHg — 0 — "C — tJEg
GHs GH3
This alcohol was prepared la two w&ysj first by trsetting tertiary
anyl magnesium florid© with acetone (see preparation of 2-iaethyl
heptanol-2) ■ and second by synthesising the ketone 5, 5-dimethyl
pentanone-2 and reacting that with methyl magnesium iodide (see pre­
paration 2, 5, 4-triaethyl pentanol-2).

However, due to the difficulty

encountered in obtaining tertiary Grignard reagents very small yields
of the alcohol were obtained (2 - 5 percent based on tertiary amyl
chloride) * The alcohol thus obtained, however, was in accord with that
,
'
v

v

prepared by other workers (55).

w -?*)t

^

lable Jk which follows gives several physical constants on the vari­
ous alcohols used in condensations as determined la this laboratory*
TABLE k
1 Hefr&eiiv® *« .HpecxTfS""
«
Index
•
3 . Gravity,_ ,
....... ..AicobpA . —
BollingJiolci.t.....
D
t Temper&ture°C 2Pressure nms
n
4
K*
2-»ethyl heptanol-2 t
159*5
746
: 1.4255
t
.81666 "SB*
-f390 j^o
20°
a,5-diiiiet||lanol_g .155.5-156.5
m 756
•
3 1.455
•
2,4-dimethyl
20°
hexanol-2 * 152 — 155
1 750 .. f 1.4221
1 _.8i2S6_|®’
2,5-dimethyl
•
* .81826
746
hexanol-2 :
154.5
*
t i W 7-5° «
2-methyl-'6-ethyl
£3<U
s .90864
t 1.4S0140
pentanol-2 * 151 - 155
s..758
26^
2,4, 4-trimethyl
•
•
t 746
1*429118°
oentanol-2 i
144
•
.82063
"
25!5
»
28°
2,3,4-trimethyl
•
*
.8532 1XF
pentanol-2 i 151 - 155
! .-.Z3£
*
_.^.45§918*5°- ♦
25°
2,5,5-trimethyl
t .8156 "SW
: 1.440920°
( 746
pentanol-2 3
157
l
.*
____________

■
9

25

Condensations with Phenol
The alcohols were prepared as described and condensed with phenol
using a method of condensation as to relative quantities, temperature,
and addition of reagents which has been determined by a series of workers
in this laboratory to produce the best results and be most convenient
when applied to the condensations between tertiary aliphatic alcohols
and phenol with aluminum chloride as a catalyst*
In as much as all the condensations were carried out in a similar
manner except for slight variations in temperature only a typical run is
described*
Thirty-two grams (0*25 mole) of the octyl alcohol and 28 grams
(0*3 mole) of phenol dissolved in 100 cc of petroleum ether was added
dropwise with stirring over a period of two hours to 17 gms (0*125 moles)
of aluminum chloride suspended in 150 cc of petroleum ether in a 500 cc
round-bottomed three-necked flask equipped with a condenser, dropping
funnel and stirrer.

The temperature was controlled between 25 - 30° G

by immersing the flask in a water bath, and the reaction mixture was pro­
tected from the moisture in the air by means of a CaGlg tube on the reflux
condenser.

Hydrogen chloride was given off all during the course of the

reaction, and a deep reddish color developed in the solution*

After

standing overnight the mixture was hydrolyzed by pouring It Into ice and
hydrochloric acid 1 : 1 mixture.

Two layers resulted and were separated*

The water layer was extracted three times with ether and this extract
combined with the petroleum ether layer.

The combined extract was dried

over anhydrous sodium sulfate and the ether removed under ordinary
pressures.

The residue was then fractionated in a modified Claiaen flask

26
with an 18 to 24 inch m l m a at 4 amu
Ther© ware always three main fractions*

A small ajaoiint below 70°

which was oncandeased alcohol, traces of its chloride and uasatuirated
compounds obtained from the alcohol; a second fraction between 70 - 100° G
consisting chiefly of phenol; and a. higher fraction 100
desired aliyl phenol.

150° 0 the

Tarry residues or the fraction above 130° C were

from 2 - 6 grams.
The fraction 100 - 150° C at 4 sm in cases where it failed to crys­
tallize was fractionated repeatedly until a colorless liquid was obtained
boiling over a 8 to 1 degree range*

Those phenols that crystallised,

after the removal of any oily inpurities by use of a porous plate and
pressing between filter paper, were recrystall!zed from a 50 percent
mixture of alcohol and petroleum ether until a constant sharp melting
point was obtained.
Table B shows the yields obtained of the principal products re­
sulting from condensations between tertiary alcohols and phenol,

27

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Physical constants and analysis of these p-hydroxyphenyl derivatives are tabulated in Table I

a. o

28
Derivatives
A* Benzoyl Esters
Of seven of the alkyl phenols were prepared by a raethod described
by Sariner and

Fuson (55).

The procedure consisted in dissolving three

grams of the phenol in 4 cc of pyridine and adding 5 cc of benzoyl
chloride*

After the initial reaction the mixture was warmed over a low

flame, refluxed for one hour, cooled, poured on
material extracted with ether.
dilute sulfuric

ice, and the oily

The ether extract was washed with cold

to remove pyridine and then cold dilute sodium car­

bonate solution, to remove excess add.

After removal of the ether the

ester was distilled under reduced pressure from a small modified
Glasien flask*

Usually upon cooling in the refrigerator the ester

crystallized out.

It was then removed from contaminating oily material

by absorbing such impurities on & porous plate*

And finally it was re-

crystallized several times from 85 percent alcohol until further recrystallization caused no changes in melting point*

Table II gives the

data on these esters.
B. Alpha—napthylurethaaes
These were prepared by the following method (56).

One gram of the

tertiary octyl phenol was placed in a large test tube and 1.5 cc of
alpha-napthyl isocyanate was added the reaction being catalyzed by two
drops of a dilate anhydrous ether solution of triaethyl amine. The
tube was protected from moisture by being fitted with a 0aClg tube and
thus stoppered,the reaction was heated on a steam bath for half an hour,
Ifpon cooling the reaction contents became solid. This solid was ex­
tracted with 60 cc of boiling ligroin (6© - 90° 0) and all undissolved

29
material filtered out*

Xu the clear filtrate the &!ph^—napthyluretiione

crystallized out on cooling.

It was filtered off and reerystallized

from hot ligroin until a constant melting point was obtained.

Results

on the3® urethanes are given in Table III.
Ho derivatives were prepared of the supposedly 2, 5, 5-trimethyl2-p-hydroxyphenyl pentane as it was obtained in a quantity of less than
0.7 gram upon recrystallization to a constant melting point.
Proof of Structure
This was accomplished by synthesis of the octyl phenols by another
method; namely that of preparation of the octyl benzenes, their nitra­
tion, reduction to toe p-nitro derivative formed to the corresponding
p—amino compound, followed by di&zotization and hydrolysis of the
diazonium salt to yield the phenol.

A description of this process in

detail follows.
A.

Preparation of the Alkyl Benzenes

Pour of these compounds had already been prepared in this laboratory
and their physical constants determined (£1).

However it was necessary

to obtain them in larger quantities and to prepare the others of the
series.

Since their preparations were carried out in a similar manner

a typical synthesis is given.
In 97 grams (1.25 moles) of benzene in a 500 cc three—necked
round-bottom flask fitted with dropping funnel, condenser, mercury-sealed
stirrer, and thermometer, was suspended 17 grams (0.125 mole) of aluminum
chloride by rapid stirring.

To this suspension was added drop by drop

52 grams (0.25 mole) of the octyl alcohol the temperature being maintained

30
below 30° C by immersing the reaction flask in a water bath If necessary.
During the addition of the octyl alcohol the mixture first became yellow
in color and the AlGlg seemed to go into solution.

Then upon further

addition a dark brown viscous layer appeared which separated out on the
bottom of the flask and the whole mixture became dark brownish in color.
Aftex' complete addition of the octyl alcohol the mixture was
allowed to stir four additional hours and then to stand overnight. The
next day the reaction mixture was poured on
acid 1

j

parated.

1 to cause decomposition.

ice and hydrochloric

Two layers resulted which were se­

The water layer was extracted three times with ether and this

ether extract added to the benzene layer.

The combined ether and

benzene extract was washed with dilute sodium carbonate solution and
dried over anhydrous sodium sulfate.
moved at ordinary pressures and

The ether and benzene were re­

then the remainder fractionated under

reduced pressures to obtain the alkyl benzene.
This procedure was found adequate for the preparation of
2-methyl-2-phenyl heptane, the hexanes 2, 3j 2, 4; and 2, 5-dimethyl2-phenyl and 2-methyl~3-ethyl-2-phenyl pentane but applied to the
prepration of 2, 4, 4-trimethyl-2-phenyl pentane and 2, 3, 4-trimethyl2-phenyl pentane splitting of the long alkyl side chains occurred
giving products of lower molecular weights.

In these cases a modificar-

tion of the originally described method was tried with apparently better
results.

It consisted of carrying out the reaction at a lower tempera­

ture* but,since benzene solidifies at 5° G, it was necessary to use a
solvent that would permit the reaction mixture to remain a liquid at
sub-zero temperatures.

Such a solvent was petroleum ether and the 97

(1.25) moles of benzene was dissolved in 150 cc of petroleum ether in

SI
which was suspended 17 grams (0,125 moles) of aluminum chloride and the
octyl alcohol added as usual.

The temperature was maintained between

—5 and -10° G by use of a hath of ice and ESI or solid carbon dioxide
{dry ice) in which the reaction flask was immersed.

The remainder of

the preparation was as already described.
Bue to the limited supply of these alcohols and the late discovery
of this modified procedure to -prevent in part splitting of the alkyl
chain, the data presented Is based upon only two condensations and hence
is only suggestive of a promising possibility.

That the 2, 4, 4-tri-

methyl pentanol—2 splits in condensation in such a way that tertiary
butyl benzene is formed has been definitely established by isolation
©f this compound* nitration of it, reduction of fee nitrocompound,
di&zotiz&tion of the formed amine, and hydrolysis of the diazonlum com­
pound wife isolation of tertiary butyl phenol {$. P. 95 - 96° C) ♦ The
benzoyl ester of this phenol when prepared {M* P. 81 * 82° G) was mixed
wife known benzoyl ester of tertiary butyl phenol and gave no melting
point Change to the known ester.
The U, 5, 4-trimethyl pentanol-2 in a similar condensation gave as
fee principal product an alkyl benzene B. P. 160 - 170° G at 756 mm
which converted to a phenol by a similar series of reactions as those
used to convert tertiary butyl benzene to p-tertiary butyl phenol melted
at 95 ^ 96° 0.

Its benzoyl ester melted at 86 - 87° G.

Ho attempt to prepare 2, 3, 5-feimethyl-£-pkenyi pentane was made
as the alcohol k, 5, 3-trimethyl pentanol-2 could not be obtained in
sufficient quantities*
Table G summarizes fee condensationa carried out to prepare the
octyl benzenes as to yields and products.

32
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55

The alkyl benzenes thus prepared were nitrated,
B.

Nitration of the Tertiary Octyl Benzenes

Malherbe* s procedure (5$) was used.

It consisted of treating the

hydrocarbon with an equal weight of fuming nitric acid (1.52) and cool­
ing during the addition.

After the reaction had subsided the mixture

was warmed to 90° G in & water bath for one hour.

It was then poured

on ice and the resulting solution extracted three times with ether, These
ether extracts were dried over C&Clg and after removal of the ether the
remaining p-nitro tertiary alkyl benzenes which were liquids were frac­
tionally distilled under reduced pressure.

Boiling points and analyses

of these compounds are recorded in Table IV,
G. Oxidation of Para Nitro Tertiary Alkyl Benzenes
In order to establish the position taken by the nitro group in re­
ference to the alkyl side chain a portion of the nitro tertiary alkyl
benzene was oxidized by a method adapted from Malherbe (56),

0ns gram

of the nitro compound and 20 cc of 6 N nitric acid was placed in a
Carius tube, sealed and heated in a C&rius furnace for six days at
150° C.

By this time crystals had formed in the tube which were removed

and collected.

They were washed with hot petroleum ether to remove oily

material and then r©crystallized several times from alcohol.

In each

case the crystals melted at 258 - 240° C mid mixed melting points with
p-nitro benzoic acid showed no depression indicating a para nitro ter­
tiary alkyl benzene as the original compound.
D, Reduction of the Para Nitro Tertiary Alkyl Benzenes
This reduction to yield the p—amino tertiary alkyl benzenes was
accomplished as follows.

Thirty grams of tin were placed in & 500 cc rouznl—bottoi&ed flask
fitted with &u air condenser*

Fro® XO — 15 grans of the p—nitro tertiary

alkyl benzene was added and than 100 cc of concentrated hydrochloric acid
in two portions*

After the initial reaction had subsided the mixture was

placed on a steam hath and left for four hours*

it the end of this time

it was treated with a large amount of water (£GQ — 200 cc) cooled and
made alkaline with 40 percent sodium hydroxide*
was then steam distilled*

This alkaline solution

The amine was extracted from the distillate

with ether and the ether solution of the amine was dried over solid
potassium hydroxide*

After removal of the ether the residue was frac­

tionally distilled from a 10 cc Glasien flask with a 12 inch column*

Re­

sults as to boiling points and percent nitrogen of these amines are
summarized in Table 7*
E* Phenols from the Para issiao Tertiary Alkyl Benzenes
These mines were diazotised and then the diazoniua salt hydrolyzed
to form the phenol*

A typical procedure is as follows*

The amine was

treated with concentrated sulfuric acid 1*5 cc is 10 cc of water for
each 2 grams of the amine*

The solid salt thus formed was quite in­

soluble in water but it was suspended by vigorous stirring in 10 times
the volume of the mixture of water, amine, and sulfuric acid*

After cool­

ing to about 5° C a 25 percent solution of sodium nitrite was added dropwiee
with continued stirring over a five hour period until the calculated amount
to act with the amine had been reached*

Stirring was then continued for

two hours more and finally the diazotized solution was warmed on a
steam bath for an hour*
steam distillation.

This reaction mixture was then subjected to

The phenol was extracted from the distillate with

35
ether and after drying the ether extract with anhydrous potassium sulfate
it was fractionated under reduced pressure to obtain the pure phenol,
F* Derivatives
The alpha-**apthylurethanes were prepared using 0,5 grams of the
phenol obtained and their melting points determined.

In all cases these

melting points were identical with those of alpha—napthylurethanes pre­
pared from phenols from the aluminum chloride condensations of alcohol
and phenols already described.

Mixed melting points showed no depres­

sions and hence the phenols as synthesized by the two different methods
were identical.

Absolute proof in this fashion was established for

£-©ethyl-2-p-hydroxyphenyI heptanej Z, 3-dimethyl, 2, 4-dimethyl and
2, 5-d.imethy1-2—p-hydroxyphenyl hexane; and g-methyl-3-ethyl and 2, 4,
4-trifflethyl-2-p-hydroxyphenyl pentane.
Further proof of the structure of 2, 4, 4-trimethyl~£-p-hydroxyphenyl pentane was obtained by synthesizing it as described by Satelson
(24) as follows;
G. Synthesis of 2, 4, 4~trimethy1-2-p-hydmxyphenyl pentane,
A mixture of one mole of powdered potassium hydroxide and one mole
of phenol was heated at 65 - 100° C in a 500 ee round-bottom flask im­
mersed in an oil bath until solution was complete,

Then a mole of di­

isobutylene chloride was added drop by drop at a temperature of 75° C
until the reaction was complete.

Potassium chloride separated out. The

temperature of the b&th was raised to 125° G, kept there for three to
four hours and then raised to 180° C where it was kept for one hour.
After cooling the potassium chloride was dissolved in water and the
separated crystalline product was purified by pressing out oily im­
purities and recrystall!zatioa from petroleum ether.

This product

36

according to Natelson is 2, 4, 4—trimehhyl-£—p-hydro:zyphenyl pentane or
diisobutylphenol, IS, P* 34° G*
Benzoyl ester and alpha-napthylurethane derivatives had melting
points corresponding to those derivatives prepared fro® the 2, 4, 4trii^thyl^E-p^ydroxyphenyl pentane obtained as a product fro® the con­
densation of 2, 4, 4-trimethyl pentsnol-g and phenol with aluminum
chloride as a catalyst*

Mixed melting point determination showed these

phenols and corresponding derivatives to be identical.
No absolute proof is offered of the structures of 2, §, 4-trjjaethyl
or Zf. 5, 3-tri»ethyl-2-p-hydraxyphenyl pentanes due to the difficulty in
obtaining the alcohols £, 3, 4-trimethyl pentaaol-E and 2, $, S-triraethyl
pentanol-2,

la the former case splitting of the alkyl chain upon conden­

sation with benzene prevented preparation of the alkyl benzene in suffi­
cient quantities sad in the latter all the alcohol prepared was used in
condensations with phenol.

37

TABLES

38
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•*

H r 10.76J5

*©

59

TABLE I I

smmiL m m & s
Benzoyl Ester of

x !*P.° C s Analysis Fqus&B*

2-»ethyl-2—p-hydroxyphenyl heptane

t% 0
i % M .... .
s 22 - 23 i 80*55 i 8,27

2>3-dimethyl-3-|>4aydroxyph.enyl hexane

x54*2-55,2? 01,22 s 8,55

2,4-dimethyI-g-p-hydroxyphenyl hexane

* 57 - 50 s 81,28 * 8.41

2,5-diraethyl-2-p—hydroxyphertyl hexane

x 46 * 4? x 81,18 f 8.26

2—methyl-5—ethyl-2~p—hydroxyphenyl pentane t 69 - 70 t 01,19 i 8.59
2,4,4—trisethyl-E-p-hydroxyphenyl pentane

x 75 - 74 t 80,66 t

2,S,4-trim9thyl~2-p-hydroxyphenyl pentane

X 47 - 48 x 80*43 t 8.18

* GaiccL for G ^ s a ^ S

C r 81*E2$

8*22

Hr 8.45$

TABLE III
ALPHA-®APTHILURETriANES
AlphaHmpthylurethan.es of

s H. P,°C : Analysis Found*
x
:
% ®

2-methyl-2-p-hydraxyphenyl heptane

x 120-121 s

5.69

2,3-dimethyl-2-p-hydroxyphenyl hexane

x105-105.5x

3*75

2 ,4-dimethylr-2—p-hydroxyphenyl h exane

x119,5-120.5s

3.72

2,5-dimethyl-2~p~hydroxy phenyl hexane

X132.5-1S3* 5;

3.70

2-methyl-3-ethyl-2-p-hydroxyphenyl pentane xl09,5-110,5x

3,70

2,4, 4-trijaethyl-2-p-hydroxyphenyl pentane

t 102-103

a
*

3.69

2,3,4-trinethyl-2-p~hydroxyphenyl pentane

I114*5-115, 5s

3.68

* C&Xod* fox* ^26^29^2^

H= 3.75 56

40
table m
PAEA NITBD TEETIAEX GGTYL BENZENES
S u b s ta n c e

B o llin g

t

t? e m p .° G

m

e t h y l-

2

>

3—d

2

,

4-

d im e th y

d L m

2 —m

e th y l-

,

p - a it r o p h e n y l

h e p ta n e

i m e t h y l — 2 —p —n i t r o p h e n y l

2 , 5-

2, 4

2-

4-

* C a lc d .

s

143-1508

2

*

6*01

h e x a n e

s

153- 155

*

&

t

5*99

p - n it r o p h e n y l

h e x a n e

8

155- 157s

2

3

5*98

2~

p ~ n itr o p h e n y l

h e x a n e

t

129-1518

2

8

6*09

:

127- 150?

4

f

6*09

3 108-1103

4

3

6*05

3—e

t h y l —2- p - n i t r o p h . e n y l

t h

f o r

2-

y l -

p - n it r o p h e n y l

C -^ H g jO g R

p e n ta n e

p e n ta n e

5 . 95%

S r

TA B LE
PA EA

a m in o

V

t e e t ia e i

o c t y l

D E L E T E S

»
#-

S u b s ta n c e

B o ilin g

5 *r e
*

2-

m

e th y l-

£ ,

3-

2

,

4- d

2

,

5-

2-

2

,

m

4

d im

4

-a m in o p h e n y l

e t h y l-

- t r im

* C a lc ;d .

5-

s P re s s u re ;

N

:

?

2

8

6.77

9

s

4

8

6.58

h e x a n e

3

H

U

%

F o u n d *

mm

108-111
5-

: A n a ly s is

2- p

-a m in o p h e n y l

h e x a n e

3

99-101

8

2

3

6*87

2- p

~ & r a in o p h e n y l

h e x a n e

:

99-102

s

2

:

6*92

8 105-106

?

2

3

6.86

8

8

5

3

6*72

e th y l-£ -p -a m

e t h y l -

f o r

m p .° C

P o in t

........ 5

:

h e p ta n e

e t h y l —2- p - a m in o p h e n y l

e t h y l-

,

2—p

im e t h y l -

d im

5

%

mm

1 - 2-

e th y l-

t r i j ^

F o u n d *

: P re s s u re :
j

2-

fe n a ly s is

P o in t

2- p

C -j^ il^ N

in o p h e n y l

-a m in o p h e n y l

p e n ta n e

p e n ta n e

N z 6.82 %

l l g

-115

41
Discussion
The general procedure employed in preparing the tertiary octyl
phenols described in this work consisted of the preparation of the
various dimethyl amyl tertiary carbinols fallowed by their condensation
with phenol in the presence of aluminum chloride as a catalyst*
H

fl<?H

IX.

H

E - C - OH
H CH
H

+

H<?H

CgHsOH-=il±fE - C - CeHgOH
HCH
B

+

SgO

The carbinols thus condensed were
A* 2-methyl heptauol-E
8. Z9 5-dimethyl hexanol-2
C. 2, 4-dimethyl h.exanol-2
D. 2, 5—dimethyl hexanol—2
E* 2-Baethyl-5-ethyl pentanol-2
F. 2,4, 4-trjjaethyl pentanol-2
Q. Zptw 4-trimethyl pentanol-2
H.

Zp 5, 5-trimethyl pentanol-2

Of these,all have been reported in the literature except 2, 5, 4-tri­
methyl pentanol-2*

This alcohol as well as the others were prepared

and a detailed description of their preparation along with their physical
constants as determined in this laboratory has been given in the Experi­
mental portion of this thesis*

In general,good yields were obtained of

the simpler compounds by using direct methods of synthesis eg* the
reaction between amyl magnesium bromides and acetone*

However, as the

amyl bromide involved became more complex the yield of the alcohol

diminished*

for this reason)cofflpXex ketones were prepared in several

cases so that a simple bromide might be used*

fields, however, of 2, S,

4-trimethyl and 2, 5, S-triaethyl pentanols-2 remained small*
The alkyl phenols were prepared by suspending a one-half molecular
equivalent of AXGlg in stirred petroleum ether at 20 - W P Q to which
was added dropwise a petroleum ether solution of a molecular equivalent
of the alcohol and a one and two-tenths molecular equivalent of phenol*
A deep red color developed and hydrogen chloride was evolved during the
reaction.

The mixture was stirred for four hours let

end than decomposed with ice and hydrochloric acid,

stand overnight

from this was iso­

lated the hikyl phenols.

X. CSg-CHg-CH^-CHg-GHg-C-C® + CeHgOH
SHS

® 5 9Hs
XI. CHg-CHo-CHg- C ~ C - OH
5

css
^Hg-Ca2-Ga2-CHg-ea2-C-C^40H . H20
<k5

eH5-CHg-eHg-c - c - c ^ o a + HgO
S

CH*

GHg
H I * C^g-Qag-9--(Mg-G--0H
H
CS,
is
.

GH,
rs

H

C%

+

CgE^OH

«3B5 ^ 5
GHg—
5
e%

-) GH

t

013
GHg
GUg—G—Gif*?—GS^—C--1
Gglt^QK ■+

XXIX.

a

* ¥*5
XIV* GH jip*GH^-»C—C—dB

G&S

+

C6% «

H CHg
GH^—CHg—G—G—G0H4OH
SB©®*
CHg

+ HgQ

^3
XV. CHj-C-GHg-C-OH
m 5 CEs

+

CgHgOH

CHg
CHg
> CEs-C-GHg-C-C6H4°B
chs

<®3 <fHg <®s
XVI. CHg-C - C - G - oa
E
H
CHa
w

Xini* (Hg-CHg-C - C - OH
<^5 CH5

+

Eg}

da;

CHg CRj CHg
+---CgHsGH------ > OHg-9 - C - C - CgB^OH t Eg}
H
H
CHv

V

*

06H5O H ----- > GHg-CH^-C ~ 0 - CeE4GH 4 H^O
G % CHg

Good yields resulted when the condensations were carried out at
25 — 50° 0$ lower temperatures 10° C were observed to decrease the amount
of alkyl phenol*

Of the phenols prepared five were liquids ana did not

crystallize even when subjected to ice box temperature• However* they
were very viscous requiring several distillations to obtain pure fractions*
The alkyl phenols after purification were analyzed

for G and H#Their

physical constants were determined and derivatives

were made*

The benzoyl esters and alpha-napthylurethanes

were preparedfor

means of identification of all the phenols except 2, 3, 5-trim©thyl-2p-hydroxyphenyl pentane*

Since these derivatives were all solids their

melting points were determined and they were analyzed,j the benzoyl esters
for percent C and H end the alpha-iiupthylurethanes for percent nitrogen*
Data on those phenols and derivatives is contained in the tables accom­
panying this* thesis*
Absolut© proof of the structure of these alkyl phenols was accom­
plished by synthesizing them from the corresponding alkyl benzenes
prepared by condensations between the already listed carbinols and ben­
zene .In the presence of aluminum chloride*

In this procedure it was

44
noted that highly branched &11 ph&tio chain£ often undergo splitting resuiting la product® of lover moleGul^x weight*

This was especially true

in the css© of Z, 4# 4-trimethyl pe2itanol~~£ and I, S, 4~tri»ethyl
pentaaol~£*

Temperature appeared to affect this splitting;at lower

temperatures -10° Q it occurred to a leaser degree than at £5 - 30° C*
These alkyl benzenes whan purified were nitrated with flatting nitric
a d d giving 'the p&ra-dtro derivative*

That substitution of the sa*

group into the benzene ring took place para to the alkyl chain was
proven by oxidation of a portion of the nitro derivative with dilute
nitric a d d in a C&rius furnace to give in every case p-nitro benzoic
add*
The para-nitro derivative was then reduced with tin and concentrated
hydrochloric to the p-tertiary oetylphenyl amine which upon diazotizatlnn
and subsequent hydrolysis of the diazonlua salt yielded an alkyl phenol*
These phenols were then identified by their dpha-napthylurethaaes nixed
editing point determinations indicating that they were identical with
the urethanes sad© from the phenols obtained by direct condensation of
phenol with the various earbind a under the action of almalnua chloride*
Am - amyl groupings c%

m n * m ~ c ~ c6ss
f «

- CgH4U02
cb5

+■

moz--------- —

> a® - c -

Oxidiaeci

MJSEemi

0

V *

- C - CsH^g

45
XX.

XXI*

<*5
Am - C - C6H4HO£ -

Reduced
Tin + HG1

<a5
* Ah * C - C6H4HHE
CH«

ch5
Diazotizod HMO^ in Acid
Am - 0 - G6H4UHg
:>Am - C - CeHgCH
Hydrolyzed
with
EOH
cr3
®5
la this fashion was established the structure of six of the alkyl

phenols namely* 2-®ethyl-2~p-hyaroxyphenyl heptane} 2, 3-dimethyl~2-phyciroxyphenyl hexane 5 2, 4-dimethy1-2-p-hydroxyphenyl hexane} 2* S-dimethyl—£-p-hydroxyphenyl hexane} 2-ffiethyl-5-*ethyl-2-p-hydroxyphenyl
pentane and 2, 4* 4-trimethyl-2—p-hydroxyphenyl pentane*
Mo absolute proof of the structure of £, 5, 4-ti'isethyl—2-p-hydroxyphenyl pentane end Z, 5, S-trimeihyl-£—p-hydroxyphenyl pentane was possible
due to the difficulties encountered in preparing £> 5, 4-tilmethyl-2phenyi pentane and 2, 5* 5-trimetbyX~£-ph«nyI pentane*

However, since

the preparation of these alkyl phenols was similar to that used to pre­
pare those whose structures have been definitely established in six
separate cases the writer feels that they are undoubtedly the compounds
as designated*

46
Summary
1* Same tertiary dimethyl amyl c&rbiaols have been condensed with
phenol in the presence of aluminum chloride to yield p~tert±ary octyl
phenols*
2* 2-methyi~2—p~hydroxyphenyl heptane| 2, 3-&iaethyl-2-p^hydroxy*phenyl hexane j 2, 4-dimethyl-£^p-hydroxyphenyl hexanej tP 5~dImethyl-2-p-hydroxyphenyl hexane| 2-®ethyl-$-ethyl~2-p--hydroxyphssyl pent&nej
2t 4, 4-triraethyl-2-p-hydi^:^phenyl pent&nej g, 5, 4-trim8thyl~£-phydroxyphenyl peatanaj and 2, 3* 5-trimsthy1-2-p-hydroxyphenyl pentane
have been prepared in this way*
3* Bensoy1 ester and &tpha~n&pthyXurethanes have been prepared of
ail the alkyl phenols except 2,

3-trimethyl-g-p-hydroxyphenyl pentene.

4* Proof of structure has been advanced for the phenols excluding
the £, 5,. 3-trimethyX and 2, 3, 4—trimethyl-2-p-hydroxypheny1 pentanes
by synthesizing them in another way *

Bibliography

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(1955)
(1956)

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162—4

Dupont

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Chem* Zent,

72 II

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Chem* Zent.

73

Dupont

Compt. rend*

152

156

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(1915)

625

(1901)

1271

(1902)

198

(1911)

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56* lalherbe

59

674

(1917)

189

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100

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0140

(1956)

Am* Chem*. Soe.
J* Am* Chem* Soc*

The Systematic Ide&ti.ficatian of
Organic expounds
*T* Am* Chem* Soe,

40

Qualitative Organic Analysis
Ber*

p* 62
1756

(1986)

p. 184
50

519

(1919)