o
A STUDY OF THE PERIODIC ACID OXIDATION OF CELLULOSE
ACETATES OF LOW ACETYL CONTENT

By
Franklin Willard Herrick

A THESIS

Submitted to the School of Graduate Studies of Michigan
State College of Agriculture and Applied Science
in partial fulfillment of the requirements
for the degree of

DOCTOR OF PHILOSOPHY

Department of Chemistry

1950

ACOOTIBDGMENT

Grateful recognition is given to Professor
Bruce B. Hartsuch for his helpful guidance
and inspiration throughout the course of
this investigation.

**********
********

* * ****
****
**

*

TABLE OF CONTENTS

I

INTRODUCTION.................................... ........

Page
1

The Structure of Cellulose.
.....................
The Present Problem....................................
II

1
2

GENERAL AMD HISTORICAL...................................

3

CELLULOSE ACETATE........................................

3

PERIODATE OXIDATION OF CELLULOSE.........................
DISTRIBUTION OF HYDROXYL GROUPS IN CELLULOSEACETATES....
III

EXPERIMENTAL.............................................
PREPARATION OF CELLULOSE ACETATE........................

10
12
15
15

Materials.................................. .. ..... . 15
Preparation of Standard Cellulose...................... 15
Preparation of Cellulose Acetates of LowAcetyl Content 16
Conditioning and Cutting of Standard Cellulose and
Cellulose Acetate....................
The Weighing of Linters
........................
20
Analysis for Percentage of CombinedAcetic Acid........
21
Tabulation of Analyses of Cellulose Acetate Preparations 23
Calculation of the Degree of Substitution and the Unit
Molecular Weight of Cellulose Acetates.........
28
PERIODATE OXIDATION OF CELLULOSE ACETATES...............
Materials.............
Determination of the Periodate Content of a Solution of
Periodic Acid.......
Preparation and Standardization of Arsenite Solution...
Preparation and Standardization of Periodic Acid Solu­
tion.........................
Preliminary Oxidations: The Selection of Oxidation
Conditions......................................
Oxidation of Cellulose Acetates: The Four Hour Re­
action.
Long Time Oxidations and the Effect of Mixing..
Oxidation of Cellulose Acetates for 60 Hours with
Standard Mixing.........
Periodate Oxidation of Sulfuric-Acid Hydrocelluloses...
Oxidation of Acetone Soluble Cellulose Acetates.......

31
31
31
32
34
36
43
55
64
83
86

19

Page
90

DISCUSSION

THE NATURE OF FIBROUS CELLULOSE ACETATES OF LOW ACETYL
CONTENT........................................
The Acetylation Reaction#•••*••••■•••••••••••••••##•
The Fibrous Structure of Cellulose and the Acetyla­
tion Reaction.................................
PERIODATE OXIDATION OF CELLULOSE....................

90
90
92
97

The Mechanism of Periodate Oxidation............... 97
Periodate Oxidation of Cellulose#................
99
Factors that Influence the Reproducibility of Re­
sults and the Rate of Oxidation of Cellulosic
Materials.................................... 105
PERIODATE OXIDATION OF CELLULOSE ACETATES OF LOW
ACETYL CONTENT.................................
The Rate of Oxidation of Cellulose and Cellulose
Acetates.#......................
The Course of the Acetylation Reaction............

jit*********

108

108
115

I

IBTBDDUCTION

The Structure of Cellulose
During the past 50 years exhaustive investigations have been made
in studying the structure of cellulose.
sulted in the following conclusion^;

These investigations have re­
cellulose is a high-molecular-

weight polymer composed of anhydroglucose units joined together by
1,4-glycosidic linkages.

The simplest structural formula for cellulose

may be shown as follows;

The chemical behavior of cellulose may be explained in terms of
the reactions of the three hydroxyl groups in the anhydroglucose unit,
and the sensitivity of the glycosidic linkage to cleavage by acids.
In the past 25 years physical chemists have investigated tjhe manner
in which the cellulose polymer is arranged in native cellulosic materials

2 7 61
* . The theory of the micellar structure of cellulose may be

briefly stated as follows;

the cellulose polymer is arranged in parallel

bundles of chains in the greater portion of a fiber, but these areas of
high degree of orientation are disrupted at fairly well defined inter­
vals with areas of relatively high disorder, i.e., random orientation
of polymer chains.

This theory is derived principally from X-ray

studies of cellulosic fibers.

The Present Problem
There has been considerable argument among cellulose chemists regard­
ing the course of the reactions by "which various cellulose derivatives,
such as esters and ethers, are prepared.
The purpose of this investigation was originally stated somewhat as
followsi
"Prepare a series of cellulose acetates of low acetyl content and
determine how the periodate oxidation of these preparations compares with
that of the cellulose from which they were prepared.

The comparison of

the periodate consumption of a particular cellulose acetate with that of
cellulose may lead to some conclusion regarding the average distribution
of the acetyl substituents in this cellulose acetate.

For example, if

initial acetylation takes place at the primary hydroxyl group on carbon
No. 6 of the anhydroglucose unit, then the periodate consumption of cellu­
lose and a partially acetylated cellulose should be the same.

However,

if acetylation takes place at either of the secondary hydroxyl groups on
carbons No. 2 or 3, the consumption of periodate by the cellulose acetate
would be less than that of cellulose."
It was further suggested that conditions should be selected such
that the rate of acetylation would be slow enough to permit the selective
esterification (if any) of either primary or secondary hydroxyl groups.
During the course of this investigation a serious attempt was made
to control all possible factors that might affect either the rate of
acetylation of cellulose, or the subsequent periodate oxidation of cellu­
lose and cellulose acetates of low acetyl content.

■2-

II

GENERAL AND HISTORICAL

CELLULOSE ACETATE

The acetic acid ester of cellulose is today one of the most
important of the plastic materials.

The acetates have found use in

filaments, films, molding powders, and lacquer resins.

The turn of

the twentieth century marked the beginning of the cellulose acetate
industry, and since that time extensive resear’
ch programs have been
devoted to the study of these materials and to the improvement of
acetate products.
The commonly used materials for the preparation of cellulose
acetate ares

a cellulosic raw material, an acetylating reagent, a

starter or swelling agent, and some diluent or solvent.

Cotton

fibers or linters have been used most extensively as raw material,
although purified wood celluloses are becoming more important in the
modern industry.
The use of acetic anhydride as an acetylating agent is credited
to Schutzenberger®®, who in 1865 prepared a cellulose acetate by
means of acetylation in a sealed tube at 140° C. for several hours.
Present day knowledge indicates that this product must have been
considerably degraded under these severe acetolytic conditions.
Other acetylating agents have been used.

Acetic acid is unsatisfac­

tory and long refluxing produces only slight acetylation^.

Acetyl

chloride may be used if a base is present to react with the hydrogen
chloride liberated, which otherwise might degrade the cellulose.

-3-

"Whol3^ introduced the use of pyridine in conjunction with acetyl
chloride.

The gas ketene (CI^CO) is mentioned as an acetylating

agent in several patents33*^3*^6*
Starters or swelling agents are used in the acetylating mixture
to increase the rate of reaction.

They are often called catalysts,

The use of sulfuric acid was introduced by Franchimont

1fi

in 1879,

He observed that the rate of acetylation was increased by the
presence of this acid.

Cross and Bevan^ mention the use of such de­

hydrating salts as zinc chloride and sodium acetate,

Hess^3 acetyl-

ated cotton with acetic anhydride in pyridine medium and in the
absence of sulfuric acid.

In this reaction pyridine functions as a

swelling agent, and Hess noted that the rate of reaction under such
conditions was considerably accelerated.

Furthermore, in pyridine

medium the extent of acid degradation is very much reduced.
ing to Kruger and coworkers,

Accord-

perchloric acid (HCIO^) is far super­

ior to any other catalyst, a very small concentration having a
powerful effect,
reaction,

Eren water may be regarded as a catalyst in this

Elod-^ found that very diy cellulose was acetylated with

difficulty, but if the moisture content of the fibers were allowed
to increase progressively, the reaction rate increased up to the
point where water became a diluent, with added hydrolytic effect on
acetic anhydride.

The increased rate of acetylation, due to the

presence of water in the cellulose structure, has been explained in
terms of the swelling power of the water.

-4-

The diffusion of the

acetylating mixture throughout the cellulose fibers is also facili­
tated by the presence of -water.
Diluents or solvents that have been used in the preparation of
cellulose acetates include glacial acetic acid, benzene, and pyri­
dine.

Acetic acid is a solvent for cellulose acetates, whereas

benzene and pyridine are nonsolvents.

'When it is desired to pre­

serve the fibrous structure of the original cellulose a nonsolvent
medium is used.

If glacial acetic acid medium is used, the end

product is a clear viscous colloidal solution.
The properties of a cellulose acetate depend on the kind and
quantity of reactants, the acetylation conditions, and the subse­
quent treatment of the product.

In the usual acetylation in glacial

acetic acid, a 2.5 to 4.0-fold excess of acetic anhydride, and about
2 to 5 percent of concentrated sulfuric acid are used.

The amounts

of acetic anhydride and sulfuric acid are based on the weight of
cellulose.

Reaction temperatures are controlled between 30 and 40°

C., and complete acetylation is ordinarily achieved in about eight
hours.

Mechanical stirring facilitates the formation of a homo­

geneous reaction mixture.

The acetate is recovered from the react­

ion mixture by first diluting with more acetic acid, and then pouring
the liquid in a thin stream into a large amount of water.

It is

important that the aggregation of large lumps of acetate be prevented,
as these will retain the acetylating reagents under surface films.
The precipitate is worked mechanically and washed repeatedly with

-5-

water until free from acid and a final boiling with water helps to
remove the last traces of sulfuric acid.
If benzene is used as a diluent, instead of acetic acid, the
final product will be a fibrous mass similar in appearance to the
starting cellulosic material.

This reaction is more heterogeneous

and generally requires a longer reaction time.

Recovery of the

acetate is made by filtration followed by thorough washing with
water.
The stability of the final product is determined largely by the
thoroughness of the washing operation.

Sulfuric acid, in this case'*

reacts with cellulose to form mixed esters or sulfoacstates.

Ost^,

who is responsible for much of the research dealing with the acetyla­
tion of cellulose, concludes that all acetate preparations retain
some small percentage of combined sulfuric acid.

To obtain a stable

acetate this sulfate content must be removed or reduced to a minimum
by boiling with water.

A product which has not been stabilized

tends to degrade slowly, becomes brittle, and develops an odor of
acetic acid.
The degree of acetylation for any particular cellulose acetate
may be determined by saponification with alcoholic alkali, and is
expressed in terms of percent combined acetic acid or percent acetyl.
These values may be used in a suitable equation (see page 28) to cal­
culate the unit molecular weight of anhydroglucose acetate.

A com­

pletely acetylated cellulose, the triacetate, would have a combined
acetic acid content of 62.50%, or an acetyl content of 43.75%, and

6-

a unit molecular weight of 288.25.

Lower degrees of acetylation

may be obtained by either reducing the amount of acetic anhydride
available for reaction, or by allowing the reaction to proceed for
a shorter length of time.

A third alternative consists of adding

acetic acid (approximately 50%) at the triacetate stage of a react­
ion mixture, and allowing this mixture to ”ripen” for some time at
a fixed temperature, usually not over 50° C.

This process allows a

limited amount of hydrolysis of the triacetate to take place, lower­
ing the combined acetic acid content to between 50 and 57%.

Miles^,

in patents obtained in 1903 and subsequent years, was the first to
recognize the commercial possibilities of this technique.

The

partially hydrolyzed, so-called ’’secondary” acetate, was found to
be soluble in acetone, a good, versatile and cheap solvent.

The

property of acetone solubility is associated with a certain limit in
the amount of free hydroxyl groups present in the acetate.

When the

combined acetic acid content of an acetate falls below 50% or is
above 57%, it is insoluble in acetone.
The strength and toughness, and in part the solubility of a
cellulose acetate, is dependent upon its degree of polymerization
(D.P.).

The higher the D.P. of the original cellulose, the stronger

and tougher the acetate product will be.

Effort is always made to

reduce the amount of degradation of the cellulose chain by means
of improved reaction conditions and controls.

Low reaction tempera­

ture, rapid acetylation, and stabilization of end products are
important.

The average degree of polymerization and the molecular -weight
of cellulose acetates may be determined by viscosity methods.

Viscos­

ity and fluidity characteristics of cellulose acetates in solution
are those of lyophilic colloids and are affected by such variables as
concentration, temperature, solvent, instrument design, structure of
polymer, and degree of association.

The Ostwald type viscometer is

commonly used, and the viscosity of a liquid is given by the equation:
|7 * Ktd, where t is the time of flow of the liquid in the viscometer;
d is the density of the liquid at some specific standard temperature,
and E is a constant for the instrument.
that the specific viscosity,

The Staudinger rule®® states

^sp, of a very dilute solution of poly­

mer, is proportional to its molecular weight.

The empirical rela­

tionship is written:
*]r -1 :
C
where

^sp 'C

Em M

,

J r is the ratio of the viscosity of the solution of linear

polymer to that of the solvent; C is the molar concentration of the
solution with respect to the structural unit of the polymer chain;
M is the molecular weight; and Em is a constant for the cellulose
derivative in a specific solvent at specific temperature and pressure.
The value of Em must be calculated by substituting the value of the
viscosity of a solution of cellulose acetate of known molecular
weight in the equation.

Osmotic pressure or ultracentrifuge methods

are used as standards for the measurement of the molecular weight of
high polymers.

Viscosities are measured for solutions having concentrations
of the order of 0.002 to 0.005 molar,

A common solvent used in

cellulose acetate viscosity measurements is m-cresol®®.

Viscosity

relationships are ideal only for very dilute solutions or at infinite
dilution.

For this reason it is customary to determine the viscosity

of a series of dilute solutions of the same acetate.

The value of

*>p/C is then plotted against the concentration, and the curve extra­
polated to infinite dilution.

The value of the specific viscosity

at infinite dilution has been called the Hintrinsic viscosity”.

The

intrinsic viscosity is used in the Staudinger equation to calculate
the molecular weight of a cellulose acetate.

The degree of polymeri­

zation is obtained by dividing the molecular weight by the unit mole­
cular weight (288) in the case of cellulose triacetate.

Kraemer^

has determined molecular weights as high as 250,000, and D.P. of 950
for cellulose acetates.
Cellulose acetates of high acetyl content are usually soluble
in chloroform, halo-hydrocarbons, aromatic amines and phenols, ali­
phatic acids, and some esters, ketones, and alcohols.

Ostwald and

coworkers^® have studied the solubility problem with respect to the
molecular weight and degree of acetylation of cellulose acetate.
They have classified solvents according to the dielectric functions
/ y £ > where /*is the dipole moment and € is the dielectric constant.
For liquids having solvent activity the function has a value between
0.251 and 0.528.

-9-

PERIODATE OXIDATION OF CELLULOSE

In recent years solutions of periodic acid and its alkali metal
salts have been applied with considerable success to the analysis
of 1,2-glycols in diverse fields of organic compounds^.

The selective

and quantitative aspects of the reaction have made it a valuable ana­
lytical and preparative tool, not only in applied but also in research
chemistry.
The reaction was discovered in 1928 by Malaprade®9*^9.
and coworkers

11-14

Fleury

were responsible for investigating the scope of

the periodate oxidation, and found that many 1,2-type oxygen and
nitrogen functional groups were attacked.

Thus 1,2-diol, °<--hydroxy

carboiyl, °0-hydroxy amino, and diketo compounds are reactive.

The

present discussion will be confined to the periodate oxidation of the
1,2-diol or glycol groups in cellulose,
Criegee® has suggested the following mechanism for the oxidative
cleavage of a 1,2-diol by periodic acids

- c — oh
(a)

+ HglOg — *- c — oh:

- c - o - i o 5h4
(b)
—

— OH

(c)

-10-

- i - o — io5h4
I
- C — OH

+ HoO

Jackson and Hudson^8 applied the reaction to cellulose.

The

secondary hydroxyl groups in the 2 and 3 positions are oxidized to
aldehyde groups, with cleavage of the carbon-carbon bond between
them:

CHgOH

«ch 2o h

H
H

OH

If cotton is oxidized with periodic acid, anhydroglucose rings will
be opened at different points along the chain, and it will be seen
that the polymer is no longer composed of successive anhydroglucose
units, but at the points of oxidation, glyoxal and d-erythrose units
will be present.
Since this type of oxidation produces new aldehyde groups,
periodate oxycelluloses have a high reducing property.
sensitive to degradation by alkalies.

They are also

These properties were demon­

strated by Davidson8 who made a thorough investigation of the action
of periodic acid on cellulose.

According to Davidson the oxidation

causes a weakening of the glycosidic linkages, making a periodate
oxycellulose very susceptible to alkaline degradation.

Pacsu8® has

suggested that the glyoxal hemiacetal units may be enolized in basic
medium, and that the degradation is due to an electrophilic attack by
water on the hemiacetal bonds.

Furthermore, a Cannizzarro type oxida-

tion-reduction may occur between the aldehyde groups in basic medium.

-11-

Studies on the determination of aldehyde groups in periodate
oxycellulose have been made by Harris and coworkers^.

Mark and co-

workers^-®, Jayme^-*-, H e a d ^ , and Timell*^ have also contributed to
the knowledge of the periodic acid reaction on cellulose.
The experimental technique for oxidizing cellulose with periodic
acid may be described briefly.

A standard sample of cellulosic

material is treated with an excess of a solution of periodic acid or
its alkali metal salts.

The concentration of the oxidizing solution

is usually less than 0.1 molar.

Buffer solutions may be added to

maintain a standard pH, usually pH 4.

Reaction temperatures of be­

tween 20 and 30° C. are convenient, and a standard temperature is
maintained throughout the reaction by means of a thermostat.

At the

end of the reaction time, the cellulosic material is filtered off
and washed, and the filtrate is analized for unreacted periodic acid.
The amount of periodic acid consumed by a certain sample may be ex­
pressed in milliequivalents per gram, or perhaps more suitably in
moles of periodic acid per unit molecular weight (anhydroglucose unit).

DISTRIBUTION OF HYDROXYL GROUPS IN CELLULOSE ACETATES

The art of preparing cellulose derivatives is still far ahead of
the theory.

Although research has been able to point the way in many

cellulose problems, there remains much to be done to explain the
specific mode of attack of esterifying and etherifying reagents on
cellulose.

Reaction kinetics fail in this field where reaction rates

follow heterogeneous patterns and are usually associated with adsorption

-12-

and diffusion factors.

The preparation of certain acetates with

specific properties, for example that of acetone solubility, has
added further interest to the investigation of the distribution of
hydroxyl groups along the cellulose chain.

Any reaction that has

reproducible selectivity with respect to the hydroxyl groups of cellu­
lose, and that does not destroy the substituents already present,
might be of use in these studies.
Acetone soluble cellulose acetates have been investigated quite
extensively.

Safcurada and Kitabatake^ condensed triphenylmethyl '

chloride with the acetate dissolved in pyridine.

Assuming that this

reagent reacts only with the free hydroxyl groups in the 6-position,
they found that one-third of the total available hydroxyl groups
were in this position.

Purves and coworkers^»®»^ have Used p-toluene-

sulfonyl chloride (tosyl chloride).

They observed that the hydroxyl

group in the 6 position reacted with the reagent approximately twelve
times as rapidly as those in the 2 and 3 positions.

Furthermore,

the tosylated acetate could be treated with sodium iodide in acetone
to replace the tosyl group with an iodine atom.

These experiments

indicated that at least 35% and possibly SO% of the available free
hydroxyl groups in these acetates were in the 6 position.

In order

to determine whether any glycol groups were present in acetone soluble
acetates, a glycol oxidation with lead tetraacetate in glacial acetic
acid was performed.

This reagent acts in the same manner as periodic

acid, cleaving the carbon-carbon bonds between adjacent hydroxyls and
oxidizing them to aldehyde groups.

-13-

Purves, using this method, could

account for only one glycol group for every 100 to 150 glucose
residues.
Similar studies on the distribution of hydroxyl groups in cellu­
lose ethers have been carried out^®.

Most recently periodic acid

oxidation has been applied as a means of determining the glycol con­
tent of certain water soluble cellulose ethers^*®®»60.

-14-

Ill

EXPERIMENTAL

PREPARATION OF CELLULOSE ACETATE

Materials
1.

Celluloses

Kodak filter cotton, Eastman Kodak Co,

2.

Acetic anhydrides

3.

Sulfuric acids

4.

Benzenes

C.P. grade.

sp. gr. 1.84, 96.7$, C.P. grade.

C.P. grade redistilled 79 to 81° C., dried

and stored over sodium.
5.

Washing solventss

benzene, technical grade, and 95$

ethanol.
6. Waters

laboratory distilled -water.

All the chemicals used ^.bove) conform with A. C. S. specifications.

Preparation of Standard Cellulose
Kodak filter cotton was found to be a high quality long fiber
cotton of high purity and uniformity.
experimental use as followss

The cotton was processed for

250 g. of cotton was placed in a

4-liter beaker and covered with 4 liters of water and allowed to
stand in a hot room at 60° C. for 24 hours.

The water was then

squeezed out and the cotton covered with four liters of boiling
water.

When cool enough to work, the water was again squeezed out

and the cotton was rinsed with another 4-liter portion of cold water.
The thoroughly pressed cotton was then placed in a 2-liter beaker
and covered with 2 liters of 95$ ethanol and allowed to stand as

-15-

before at 60° C. for 24 hours.

Rinsing with 4-liter portions of

boiling and cold water was repeated.

This treatment was considered

sufficient to remove pectic materials and waxes from the cellulose
fibers.
The purified cotton was pulled apart and dried for 24 hours at
60° C.

Standard cellulose to be used for the preparation of cellu­

lose acetate samples was dried in a vacuum oven at 60° for 24 hours
and stored in a large desiccator over concentrated sulfuric acid.
The moisture content of the vacuum dried cotton was determined by
heating a 5 to 10-gram sample, contained in a 100-ml. weighing bottle,
at 110° C. in a vacuum oven for 24 hours®
reduce the weight.

Further heating did not

In all cases the moisture content of the vacuum

dried cotton was found to be less than 1% by weight.

For example,

5.9380 g. of this cotton lost 0.0469 g. by this treatment, and there­
fore contained about 0.8% moisture*

Storage over concentrated sul­

furic acid at room temperature was considered adequate to maintain,
if not further reduce, the low moisture content of this standard
cellulose.

Preparation of Cellulose Acetates of Low Acetyl Content
In this investigation it was desired to prepare a number of
cellulose acetates of an acetyl content below 10%.

This was accom­

plished by a method in which the acetylation reaction was interrupted.
It was also desired that the acetylation reaction be slowed down
somewhat, and that the fibrous nature of cellulose be retained.

-16-

Elod^ has shown that the rate of the reaction is decreased consider­
ably when cotton of low moisture content is used.

The proportions

of the acetylating reagents and cellulose used in these preparations
21
were established in a preliminary study .

The reaction mixture used for the preparation of all cellulose
acetate samples was as follows;
cellulose, moisture content

10 1 0.1 g. of vacuum-dried standard

K.1%; 205 ml. of anhydrous benzene;

55 ml. of acetic anhydride; and 0.8 ml. of concentrated sulfuric acid.
The following figures show the molar quantities of each component of
the reaction mixture;
0.0617 mole of cellulose
2.305

mole of benzene

0.578

mole of acetic anhydride

0.0147 mole of sulfuric acid
The molar ratio in the same order would be;

1

; 37.33 ; 9.37 ; 0.238.

The concentration of sulfuric acid would be 0.0563 M based on 260.8 ml.
of acetylation medium.
Before starting the preparation of aiy cellulose acetate the
proper quantities of benzene, acetic anhydride and sulfuric acid were
mixed.

Usually enough of this mixture was prepared to acetylate 5

samples of cellulose.

This avoids small variations in the quantity

of sulfuric acid used for each sample.
At zero reaction time 10 g. of vacuum-dried standard cellulose
was rapidly weighed into a dry 400-ml. beaker and immediately covered

-17-

with 260.8 ml. of the acetylating mixture.

Since small variations

in the total amount of this mixture are not important, it was measured
in a 500-ml. graduated cylinder.

Air bubbles were removed from the

cellulose mass by pressing with a glass rod.

The beaker was covered

with a watch glass and the reaction mixture was allowed to stand at
room temperature for a length of time that varied with the degree of
acetylation desired.

It was found that during the first 5 minutes

of the reaction, the temperature rose approximately 2° C. and then
slowly came back to room temperature.

The temperature of the reaction

was recorded from time to time and did not vary after the first half
hour of reaction time.

Average temperatures ranged between 27 and

29° C.
At the end of the reaction time the cellulose acetate mass was
transferred to a Buchner funnel-suction flask apparatus and pressed
under suction with the bottom of a 250-ml. beaker.

The mass was then

returned to a 400-ml. beaker and washed with four 100-ml. portions of
benzene and four 100-ml. portions of 95% ethanol, each washing being
accompanied by agitation, and removal of the wash solvent by pressing
under suction.

At this point the acetate always tested acid to litmus.

Water washings to remove all traces of acid were standardized as
follows*

two 4-liter washes with distilled water, the acetate mass

being stirred in the second wash by means of an electric stirrer for
2 hours; one 2-liter rapid wash with dilute ammonia water (20 ml. of
14.7/6 NH4OH in 2 liters of water); two 4-liter washes with water;

-18-

one 24 hour steep in one liter of water at 60° C.; and finally one
wash with 4 liters of water.

The acid-free cellulose acetate was

air dried for 48 hours.

Conditioning and Cutting of Standard Cellulose and Cellulose Acetate.
The cellulose acetates and samples of standard cellulose were
conditioned for several days in a desiccator containing 36$ sulfuric
acid in its well.

The relative humidity of the atmosphere in this

desiccator is approximately 65$ at 25° C.

66

in the laboratory also averaged about 65$.

.

The relative humidity

Conditioning at 65$ rela­

tive humidity permitted handling and accurate weighing of acetate
samples without too much danger of loss or gain in weight due to
moisture transfer.

The moisture content of conditioned samples was

determined as described previously and was found to be about 5$ for
both cellulose and cellulose acetate samples.

The weight of all

samples of cellulose and cellulose acetate recorded in the data tables
is the dry weight, i.e., the weight of the conditioned sample cor­
rected for 5$ moisture content.
In order to obtain a uniform sample suitable for oxidation stud­
ies, the long fiber's were cut to 20-mesh linters.

This was done in

a Wiley mill, which cuts the fibers by means of rapidly spinning
knives that pass by stationary cutting edges.

A 20-mesh screen allows

the desired size of linters to pass into a receiving jar.

No heating

effects were observed during the cutting procedure, and the cut ends
of the linters were sharp and clean.

The cut samples were stored in

the conditioning desiccator at 65$ relative humidity.

The Weighing of Linters
The method that m s used to weigh cotton and cellulose acetate
linkers m s kept standard throughout this investigation.

Samples

were weighed on an analytical balance to the nearest 0,1 milligram.
The samples were weighed in a specially constructed weighing tube.
This tube consisted of an outer jacket and a plunger.

The outer

jacket m s made from a 1,5 x 9.5 cm, glass tube, which was fitted with
a plunger which m s a 1.2 x 9,5 cm, test tube.

A pair of forceps was

used to transfer the linters from a storage bottle to the cylinder
tube -which was held in a vertical position with one end against a
piece of filter paper.

The plunger m s then used to compress the

sample into a compact mass.

The depth of this compressed sample m s

used to estimate the weight of linters present, and with a little
practice, the desired weight could be judged quite easily.

The sample

could be ejected into the desired reaction flask by exerting pressure
on the plunger.

Adhering linters in the tube were dislodged by gently

tapping the side of the flask with the tube and by manipulation of
the plunger.
weighing tube.

Chamois finger protectors were used in handling the
The weight of the sample was obtained by difference:

the weight of the sample and tube minus the weight of the tube.
This method of weighing m s found to be quite rapid.

It pre­

vented the very lightweight linters from escaping into the balance
housing, and furthermore, protected the linters from excessive
moisture transfer.

■20-

Analysis for Percentage of Combined Acetic Acid.
The alcoholic alkali saponification of Eberstadt

34

as modified

by Howlet and Martin^® was used to determine the combined acetic
acid content of the cellulose acetate samples.
for this method is t 0.1%

HOAc^®.

The accuracy claimed

The concentrations of the reagents

were modified slightly to add to the convenience of the analysis.
Standard potassium hydroxide solution, approximately 0.2 IT
(carbonate free) was prepared according to procedures used for the
standardization of bases described by Willard and Furman

65

•

Potassium

acid phthalate was used as a primary standard, and phenolphthalein as
an indicator of the equivalence point.

Solutions of potassium hydrox­

ide, approximately 0.5 IT, and of sulfuric acid, approximately 0.6 IT,
■were prepared and the concentrations checked by reference to the
standard 0.2 IT KOH, but it was not required that the concentration of
these solutions be known, except for planning the proportions of solu­
tions to be used in the analysis.
Three 0.5 to 1.0 g.-samples of the cellulose acetate to be ana­
lyzed were weighed in the -weighing tube and transferred to 250-ml.
glass stoppered conical flasks.

At least three flasks containing

approximate equivalent amounts of standard cellulose were also pre­
pared for each group of analyses.
determinations.

These flasks were carried as blank

Each sample of linters was wetted with 20 ml. of 95%

ethanol, measured with a pipet, and allowed to stand for 15 minutes.
Each sample was then treated with 20 ml. of approximately 0.5 IT KOH,

-21-

measured with a standard pipet, and the sample and solution were mixed
thoroughly and allowed to stand for 24 hours at room temperature.

At

the end of this time each sample was treated with 20 ml. of approxi­
mately 0.6 IT HgSO^ measured with the same standard pipet.

After mix­

ing, the sample was allowed to stand 4 to 6 hours so that the excess
alkali could be removed from the fibers.

During the 24 hour saponi­

fication period the potassium hydroxide swelled the cellulose acetate
and diffused into its capillary structure.

Howlet and Martin^® found

that the addition of excess sulfxiric acid to such a mixture did not
neutralize the base on the inside of the cellulose fibers unless the
mixture was allowed to stand for a 4 to 6 hour diffusion period, after
which the excess acid could be titrated with standard base and repro­
ducible resiilts obtained.

The excess acid present in each sample was

titrated with standard 0.2 IT KOH to the phenolphthalein end point.
In this final step the contents of the flask was shaken repeatedly to
insure complete neutralization of the acid.
The calculation of combined acetic acid was made from the equa­
tion:
per cent _
HOAc

(T

-

t)

(IT of KOH )

(0.06005)

(100)

.

sample weight

where T is the ml. of KOH to titrate the sample of cellulose acetate;
t is the average of the blank determinations; and the figure 0.06005
is the milliequivalent weight of acetic acid.

-22-

Tabulation of Analyses of Cellulose Acetate Preparations.
The preparation of cellulose acetates of low acetyl content
under the conditions used required some preliminary experimentation.
Samples of cellulose acetate, No* 1 to 7, resulted from this investi­
gation, and since they were not used in any oxidation studies, the
data on these samples will be omitted.

Cellulose acetate samples,

No. 6 to 15, were prepared as a group and used in the study of the
initial reaction (a 4 hour period) of periodic acid on cellulose ace­
tate,

Samples, No. 16 to 25, were also prepared as a group and were

used in oxidations over a period of 60 hours.
Table I contains the data pertaining to the conditions of acetylation and the analysis of cellulose acetate samples.
is used to designate cellulose acetate.

The symbol ”CAc"

The value of the average

titer for blank determinations is listed at the bottom of the titer
column of each analysis.

The sample weight listed as 0.0000 g. may

be interpreted as an equivalent quantity of standard cellulose in the
blank.
The progress of the acetylation reaction may be illustrated by
plotting the percent combined acetic acid against the reaction time.
Figure 1 shows the rate of acetylation for standard cotton cellulose
(moisture content less than 1%) at 27 to 29° C.

Although it was not

intended that this study should reproduce the reaction curve of
Elod'*'^, it can be seen that the rate of acetylation is the same even
though the conditions of moisture content and temperature are slightly
different.

-23-

TABLE I

ANALYSES OF CELLULOSE ACETATE PREPARATIONS

Analysis for percent combined
____________ acetic acid_____________
CAc
No.

Reaction
Time, hrs.

Tamp.
°C.

8

2.5

27

sample
wgt. g.

0.4782
0.4771
0.4798
0.0000

ml. of
st. KOH

29.25
29.25
29.30
28.22

N of
st. KOH

HOAc
%

0.2147

3.14
3.09
3.28
av. 3.17

9

5.0

27

0.4810
0.4864
0.4860
0.0000

29.85
30.00
30.05
27.40

0.2148

6.57
6.89
7.03
av. 6.83

10

4.0

28.5

0.4841
0.4869
0.4884
• 0.0000

29.65
29.65
29.75
27.40

0.2148

av. 6.06

■
11

7.5

28.5

0.4710
0.4895
0.4796
0.4768
0.0000

30.85
31.10
30.90
30.92
27.40

6.00
5.96
6.21

0.2148

9.45
9.75
9.41
9.53
av. 9.53

12

3.25

29

0.4760
0.4755
0.4776
0.0000

28.60
28.70
28.70
27.25

0.2148

3.66
3.93
3.92
av. 3.84

13

6.0

29

0.4772
0.4761
0.4758
0.0000

29.90
29.80
29.90
27.25

0.2148

7.17
6.92
7.20
av. 7.10

Cont’d next page

-24-

TABLE I - Continued

Analysis for percent combined
acetic acid
CAc
No.

Reaction
Time, hrs.

Temp.
°C.

14

4.25

28

'sample
wgt. g.

ml. of
St. KOH

N of
st. KOH

0.9532
0.9505
0.9516
0.0000

10.48
10.60
10.54
9.49

0.1934

HOAc
%
1.21
1.35
1.28
av. 1.28

15

7.0

28

0.5727
0.5744
0.5728
0.0000

12.05
12.10
12.08
9.49

0.1934

5.19
5.27
5.25
av. 5.24

16

2.0

29

0.9537
0.9554
0.9564
0.0000

10.00
10.02
10.05
9.49

0.1934

. 0.62
0.64
0.68
av. 0.65

17

4.0

29

0.4769
0.4800
0.4776
0.0000

11.55
11.65
11.58
9.48

0.1934

5.04
5.24
5.10
av. 5.13

18

6.0

29

0.4769
0.4770
0.4760
0.0000

12.88
12.85
12.85
9.48

0.1934

8.28
8.20
8.22
av. 8.23

19

8.0

29

0.4769
0.4804
0.4781
0.0000

14.44
14.50
14.50
9.48

0.1934

11.94
12.12
12.20
av.12.09

20

10.0

29

0.4796
0.4764
0.4796
0.0000

15.40
15.25
15.25
9.48

0.1934

14.34
14.07
14.01
av.14.14

Cont’d next page
-25-

TABLE I - Concluded

Analysis for percent combined
acetic acid
CAc
Ho.

21

Reaction
Time* hrs.

2.75

Temp.
°c.

28

sample
■wgt. g.

ml. of
st. KOH

N of
st. KOH

0.4821
0.4784
0.4813
0.0000

10.95
10.92
10.98
9.48

0.1934

HOAc
%

3.39
3.35
3.47
av. 3.40

22

3.5

28

0.4775
0.4796
0.4807
0.0000

11.72
11.70
11.78
9.48

0.1934

5.30
5.23
5.40
av. 5.31

23

5.0

28

0.4804
0.4808
0.4780
0.0000

12.30
12.28
12.22
9.48

0.1934

6.66
6.62
6.50
av. 6.60

24

7.25

28

0.4777
0.4815
0.4768
0.0000

13.10
13.12
13.10
9.48

0.1934

8.65
8.63
8.66
av. 8.65

25

9.0

28

0.4792
0.4802
0.4802
0.0000

13.65
13.65
13.65
9.48

0.1934

9.96
9.93
9.93
av. 9.94

-26

16.

15
14
13
12
11

10
c
/

8
7

6
5
4
3

2
1

0

5--- 1

10

11

Time, hours
Figure 1
—

Acetylation of cotton, <1$ moisture, at 27 to 29°C.

--- Acetylation of cotton, O.lfo moisture, at 45°C.,
Elod and Schmidt-Bielenberg 10
-27-

Calculation, of the Degree of Substitution and the Unit Molecular
Weight of Cellulose Acetates.
Combined acetic acid percentages may be converted to percent
acetyl by multiplying by the ratio:

molecular weight of an acetyl

group to the molecular weight of acetic acid, i.e., 42/60.

Peroent

combined acetic acid may be converted to degree of substitution by
means of a mathematical expression^ as shown below.
When cellulose acetate is saponified the elements of HOH are
added to yield cellulose (unit molecular formula CgH^QOg) and acetic
acid.

In terms of acetic acid content, the unit molecular formula

of any acetate may be written:

c6h10-2D.S.°5-d S (H0A-C)j) 3 » Y*iere

D.S. is the degree of substitution of acetic acid per anhydroglucose
unit.

The percent acetic acid in cellulose acetate may then be ex­

pressed by:

HOAc

•

100

_

TTrt,

----------

Substituting the proper atomic weights in this equation and solving
for the degree of substitution:
D.S.

=

162 (HOAC??)
6000 - 42(HOAc/)

The unit molecular weight of cellulose acetate will always be
that of an anhydroglucose unit plus the weight of the acetyl content.
Knowing the degree of substitution, the unit molecular weight of any
acetate may be expressed:
Unit molecular weight - 162 + 42 D.S.
The degree of substitution for a cellulose triacetate has the maximum
value of 3.

By the above equation its unit molecular weight is 288.

-2 8-

It was found convenient to calculate the unit molecular weight for
cellulose acetates of 1 to 15% combined acetic acid, and to plot
the HOAcjS against unit molecular weight.

A large piece of graph

paper (2 feet square) was used for this graph, and the value of the
unit molecular weight of any acetate in this range of percent com­
bined acetic acid could be determined at a glance.
The values of the acetyl content, degree of substitution, and
unit molecular weight for each acetate sample are recorded in
table II.

-29-

TABLE II
DEGBEE OF SUBSTITUTION AND UNIT MOLECULAR WEIGHT OF CELLULOSE
ACETATE PREPARATIONS

CAc
No.

Combined
HOAc %

Acetyl
content
%

Degree of
substitution
(calc.)

Unit molecular
weight
(calc.)

8

3.17

2.22

0.0875

165.67

9

6.83

4.7e

0.1936

170.13

10

6.06

4.24

0.1706

169.16

11

9.53

6.67

0.2758

173.57

12

3.84

2.69

0.1066

166.48

13

7.10

4.97

0.2018

170.47

14

1.28

0.896

0.0348

163.46

15

5.24

3.67

0.1466

168.12

16

0.65

0.455

0.0177

162.75

17

5.13

3.59

0.1436

168.03

18

8.23

5.76

0.2360

171.91

19

12.09

B.43

0.3560

176.95

20

14.14-

9.90

0.4235

179.77

21

3.40

2.38

0.0940

165.94

22

5.31

3.715

0.1490

168.25

23

6.60

4.62

0.1868

169.84

24

8.65

6.05

0.2490

172.45

25

9.94

6.96

0.2880

174.10

-30.

PERIODATE OXIDATION OF CELLULOSE ACETATES

Materials
1.

Standard cellulose (see page 15).

2.

Cellulose acetates of low acetyl content (see page 16).

3.

Paraperiodic acids

HglOg, reagent grade, G-. Frederick

Smith Chemical Co.
4.

Sodium bicarbonate:

5.

Potassium iodide:

6.

Arsenious oxide:

7.

Sodium hydroxide pellets:

8.

Potassium iodate:

9.

Hydrochloric acid:

10.

Water:

reagent grade.
C.P. grade.

reagent grade.
C.P. grade.

primary standard.
sp. gr. 1.19, 37-38.5%, C.P. grade.

laboratory distilled water.

All of the above chemicals conform with A.C.S. specifications.

Determination of the Periodate Content of a Solution of Periodic Acid.
When periodic acid oxidizes cellulose it is reduced to iodic acid.
The periodate content of a solution may be determined in the presence
of the iodate ion.
to iodate.

In neutral solution periodate is reduced by iodide

Thus, if a solution of periodic acid is neutralized with

excess sodium bicarbonate, and then treated with excess potassium iodide
solution, the reaction may be written:
NaI04 + 2KI + 2NaHC03

__ *

NalOg + I2 + Na2C03 + K2C03
♦ h 2o

The iodine in this solution may be determined by titration with standard
45
arsenite solution, using a starch indicator .

-31-

ft
Davidson found that

this method yielded the same results as the more commonly used but
less direct method of Fleuiy and Lange14*15.

The latter method uses

an excess of arsenite to react -with the iodine, followed by a backtitration of the excess arsenite with standard iodine solution.

The

equation for the reduction of iodine by arsenite may be written:
I2 + NaAsOg + 3NaHC03

Na2HAs04 *■ 2NaI + 3C02 + H20

Preparation and Standardization of Arsenite Solution.
Standard 0.015 N sodium arsenite solution was prepared according
to directions described by Willard and Furman55.

Arsenious oxide,

As20s analytical reagent, was dried at 110° C. for 24 hours, and used
as a primary standard.
one time.

Seven liters of the solution were prepared at

Exactly 5.1928 g. of the dried arsenious oxide was weighed

out on a tared watch glass, transferred quantitatively to a 250-ml.
beaker, and treated with a solution of 10 g. of sodium hydroxide pellets
in 50 ml. of water.
warmed slightly.

The oxide dissolved readily when the solution was

The solution was transferred quantitatively to a

1-liter volumetric flask and diluted with water to 500 ml.

An excess

of concentrated sulfuric acid (10 ml.) was added to the alkaline arsen­
ite solution.

After thorough mixing the excess acid was destroyed by

the addition of 10 g. of sodium bicarbonate added in small portions.
Such a solution is saturated with carbon dioxide and contains excess
sodium bicarbonate; therefore, it is a buffered solution.

After thor­

ough mixing and cooling to 20° C., the solution was made up to the mark.
It was then poured into a 7.5-liter bottle and diluted with six liters

-32-

of -water measured in the same volumetric flask.

The storage bottle was

fitted with a siphon apparatus and protected from the laboratory atmos­
phere with a calcium chloride-soda-lime tube at the air inlet.
The formation of sodium arsenite from arsenious oxide may be writ­
ten:

AsgOs + 2NaOH

— ►

2 NaAsOg + HgO •

The normality of the

arsenite solution may be calculated from the equation:
N

(0,049455)

g.of A s g O g ___
(ml, of solution)

From this equation, the normality of 7 liters of solution prepared from
5,1928 g. of arsenious oxide would be 0,015.
The normality of standard arsenite may be checked against a standard
iodine solution or by an adaptation of the potassium iodate primary
standard technique.

The latter method was found to be more convenient.

Three 0.25 to 0.30-g. samples of dried primary standard KlOg were
weighed out.

Each sample was dissolved in 50 ml. of water.

This solu­

tion was transferred quantitatively to a 250-ml. volumetric flask, and
diluted with water up to the mark.

Twenty-ml. aliquots of these stand­

ard KlOg solutions were measured with a standard 20-ml. pipet into a
250-ml. glass stoppered conical flask.

Each aliquot sample was diluted

with 30 ml. of water and 5 ml. of 10%, KI solution.

The iodine in this

solution was liberated with 5 ml. of dilute HCl (1 part of 58% HC1 to
15 parts of water) according to the equation:
KI03 + 5KI (excess) + 6HC1 — ►

6KC1 + 3I2 + 31^0

This solution is acidic and must be neutralized before the arsenite
method of determining iodine can be applied.

This requirement was ful­

filled by adding 2 g. of solid EaHCOg in small portions, the flask

-33-

being tilted so that no loss of solution occured during the evolution
of carbon dioxide.

The solution was chilled in ice water and titrated

at once with approximately 0.015 N arsenite solution delivered from a
50-ml. buret, using 1 ml. of 1% starch solution as indicator.

Calcu­

lation of the normality of the arsenite solution was made as follows:
H of arsenite z

(20) (g. of KIO3 ) _________
(250) (0.03567) (ml. of arsenite)

.

When checking the normality of the arsenite solution, three ali­
quots of three different standard KlOg solutions were titrated.

The

normalities obtained for these nine trials were usually in agreement
within 2 parts per thousand.

The best average was used as the stand­

ard normality of the solution.
The normality of the arsenite solutions used throughout this in­
vestigation remained constant within 0.0001 N for several months.
When the storage bottle was nearly empty, the concentration changed
more rapidly, and therefore, when the solution was down to the 1 liter
mark, a fresh solution was prepared.

Preparation and Standardization of Periodic Acid Solution.
Periodic acid solutions may be prepared by dissolving crystalline
paraperiodic acid in the desired amount of water.

The concentration

of the periodic acid solution selected for the oxidation of cellulose
and cellulose acetate was 0.03 N.

The solution was made up in double

strength (0.06 H) so that the linters of cellulose and cellulose ace­
tate could be wetted and dispersed in a standard volume of water before
addition of an equal volume of approximately 0.06 N HIO4 solution.

-34-

To prepare a 6-liter volume of approximately 0.06 TT solution, 42.5 1
0.01 g. of HglOg was weighed and dissolved in 6 liters of distilled
water.

This solution was stored in a 7.5-liter bottle fitted with a

siphon tube and protected from the laboratory atmosphere with a cal­
cium chloride-soda-lime tube.

Paraperiodic acid is very hygroscopic

and contains some water in excess of the formula HglOg.

A trial solu­

tion was made up to establish the correct weight of the reagent to be
used to prepare 0.06 N solutions.

It was found that the reagent grade

of HglOg contained about 5.5% water.
Three 10-ml. samples of the stock HIO4 solution, measured with a
standard 10-ml. pipet, were removed and transferred to 125-ml. Erlenmeyer flasks and neutralized with 10 ml. of saturated sodium bicarbon­
ate solution.
utes.

Each flask urns chilled in an ice water bath for 2 min­

Ten ml. of 10% potassium iodide solution was added and the

liberated iodine titrated immediately with standard 0.015 II arsenite
delivered from a 50-ml. buret.

The arsenite was added as rapidly as

possible at first, and then more slowly until the iodine color had
almost disappeared or was a faint yellow.

At this point 1 ml. of 1%

starch solution was added as an indicator, and the titration was con­
tinued until the blue color of the starch-iodine complex just dis­
appeared.

The starch solution was prepared by adding 1 g. of soluble

starch dispersed in 20 ml. of water to 80 ml. of boiling water, and
allowing this mixture to boil for 10 seconds.
The periodic acid solutions were found to remain constant within
0.0002 II during any three day period.

-35-

After a period of 5 or 6 weeks

the concentration of the stock solution decreased from ,06 K to
0.055 N.

As in the case of the standard arsenite solutions, when the

volume of periodate was down to the 1 liter mark, a fresh solution was
prepared®

The normality of the periodic acid solution was calculated

from the equation:
N of HIO4

=

Preliminary Oxidations:

(H of arsenite) (ml. of arsenite)
(ml. of HIO4)

The Selection of Oxidation Conditions.

A number of preliminary periodate oxidation experiments were per­
formed on standard cellulose in order to select the proper oxidation
conditions that would lead to reproducible results.

It was found that

mary variables required either accurate or at least approximate control.
These factors are described and discussed in this section.
The selection of the concentration of periodic acid solution to be
used in the oxidation of cellulose and cellulose acetate was based on
the work of Harris and coworkers

53

.

This concentration varied between

0.0275 N and 0.03 H.
All reaction flask equipment was scoured thoroughly with a deter­
gent scouring powder to remove oxidizable impurities or impurities that
might catalyze the decomposition of periodic acid.

After rinsing with

water, the inside surface of each reaction flask was standardized by
treatment with about 0.06 N HIO4 solution for 24 hours before use.
After the flasks had been used in oxidation experiments they were cleaned
by rinsing with water and were dried in an inverted position.

•36-

The physical form of the material to be oxidized was standardized
by using 20-mesh linters of standard cellulose and cellulose acetate
fibers (see page 19).

Weighing of these linters was performed as des­

cribed on page 20.
Before addition of the oxidizing solution, the linters samples
were prewetted with a standard volume of water and allowed to stand for
1 hour.

An equal standard volume of stock periodic acid was added and

the time of addition noted.
mixed.

The solution and linters were carefully

The reaction flask was then thermostated at 30° C. in a con­

stant temperature bath for the desired length of time.
The constant temperature bath consisted of a battery jar, 40 cm.
in diameter and 30 cm. high, fitted with Precision Scientific Co. elec­
tronic thermostating apparatus, together with a stirring motor, and a
50° C. thermometer calibrated in units of 0.1° C.

A wire rack was sup­

ported in the jar by three chains that could be adjusted to hold the
rack at any desired depth.

The jar was filled with enough water to

cover the thermostat control and the rack was adjusted to a depth 5 cm.
below the water level.

The thermostat control was adjusted for a bath

temperature of 30 t 0.1° C.

Snail flasks thermostated in this bath

were weighted with squares of heavy lead sheet with the corners turned
up to clamp around the bottom of the flask.
No method of mixing was used in the case of these preliminary oxi­
dations.

A flask containing at least 100 ml, of the stock periodic

acid solution was thermostated with the reaction flask and was used
for blank determination of the concentration of periodic acid.

37-

Since

the concentration of a periodic acid solution decreases slowly, due to
the decomposition of the periodate ion, the standardization procedure
was repeated for each series of oxidations.
The pH of the reaction mixture was found to remain constant over
a period of 72 hours.

Since this pH was between 1.6 and 2.0 no buffer

solutions were incorporated in the oxidation mixtures.
At the end of the reaction time the mixture was analyzed for unre­
acted periodic acid by the same procedure used for standardizing
periodic acid solutions.

In some cases the linters were filtered from

the oxidizing medium with a specially constructed suction-filter appara­
tus.

This was made from a 2.5-liter wide-mouth bottle, 8.5 cm. in

diameter at the top.

This bottle was large enough so that a 250-ml.

conical flask could be placed inside it.

The bottle was provided with

a rubber stopper holding a 6-cm. long-stem funnel and an 1-shaped glass
tube.

A Gooch crucible was supported in the funnel with a rubber

adapter.

T}ie funnel extended halfway into the receiving flask inside

the suction apparatus, so that during the filtering procedure, the fil­
trate coming from the Gooch crucible passed into the flask in a quanti­
tative manner.
Three methods of sampling to determine the excess periodic acid in
an oxidation mixture were studied:

(l) the oxidation mixture was fil­

tered and the sample removed from the filtrate; (2 ) the oxidation mix­
ture was filtered and washed, the combined filtrate and washings were
made up to a standard volume, and an aliquot of the standard volume
removed as a sample; (3) the entire reaction mixture (without filtering)
was used as the sample.

-38-

Method 1. A 1 to 1.5-G. sample of standard cellulose linters mas
weighed into a 250-ml. Erlenmeyer flask and suspended in 50 ml. of
water measured with a standard pipet.

Fifty ml. of approximately 0.06

N HIO^ solution, measured with a siiandard pipet, was added and mixed
with the suspended linters.

The flask was stoppered with a cork and

thermostated at 30° C. for 30 minutes.

At the end of this time the

flask was plunged into ice water at 0° C. for 2 minutes.

The reaction

mixture was filtered through a Gooch crucible into a clean 250-ml.
Erlenmeyer flask.

Three 20-ml. samples of the filtrate were analyzed

for periodate content.
Method 2.

Method 1 was followed exactly, except that after separation

of the linters from the oxidizing solution, the linters were washed with
50 ml. of water added in about 5 ml. portions.

The mixture of filtrate

and wash water was transferred quantitatively to a 200-ml. volumetric
flask and diluted to the mark with water.

Three 50-ml. aliquots of

this solution were analyzed for periodate content as usual.
Method 3.

In this experiment the oxidation mixture was analyzed directly.

A 0.2 to 0.25-g. sample of conditioned 20-mesh standard cellulose linters
was weighed into a 125-ml. Erlenmeyer flask and suspended in 10 ml. of
water measured with a standard pipet.

Ten ml. of approximately 0.06 N

periodic acid was measured with a standard pipet and mixed with the
suspended linters.

The flask was stoppered with a cork and thermostated

at 30° C. for 30 minutes.

At the end of this time the flask was plunged

into ice water at 0° C. for 2 minutes, and the oxidation medium was im­
mediately analyzed for periodate content.

-39-

At least, four separate samples of cellulose were used to test
each method of sampling described.
each sample was calculated.

The consumption of periodate by

This figure is expressed as milliequiv-

alents of HI04 consumed per gram of cellulose, and may be calculated
from the equation:
HI04 , meq./ g.

=

(B - S) (W of arsenite) (F)
(g. of standard cellulose)

where B is the average ml. of arsenite used to titrate the blanks;
S is the ml. of arsenite used to titrate the solution or aliquot
fraction; and P is a multiplication factor that depends on the frac­
tion of the total solution analyzed.

In method 1 this fraction was

l/5, therefore the multiplication factor would be 5.

In method 2 the

factor would be 4, and in method 3, since the whole solution was
titrated, the factor is 1.

In methods 1 and 2 the three titrations

made on each sample did not vary more than £ 0.05 ml. and the average
was recorded.
The data for the three methods of sampling are listed in Table
III.

The values of the blank titers are listed opposite the zero

sample weights at the top of each group of analyses.
From the data in column 5 of table III it can be seen that the
variations in the periodate consumption, as determined by the three
methods of sampling, are so small that it may be concluded that any
one of the three would be satisfactory.
It is difficult to decide the limits of reproducibility that
should be considered as acceptable in the case of heterogeneous

-40-

TABLE III
RESULTS OF THE ANALYSES OBTAINED BY THREE METHODS OF SAMPLING
(Oxidations for 30 Minut es at 30° C.)

Method of
Sampling

Sample
Wgt.,
S»

Arsenite
Titer,
ml.

Normality
'of
Arsenite

hio4
Consumed
meq./ g.

1

0.0000
1.4395
0.9364
1.0241
0.9738

39.65
38.30
38.80
38.60
38.60

0.015

0.0000
0.0704
0.0689
0.0769
0.0808

2

0.0000
1.0272
1.0202
0.9664
0.9906

49.55
48.42
48.25
48.28
48.25

0.015

0.0000
0.0654
0.0765
0.0788
0.0788

3

0.0000
0.1910
0.1881

39.70
38.80
38.80

0.015

0.0000
0.0707
0.0718

0.0000
0.1929

39.50
38.52

0.0147

0.0000
0.0753

0.0000
0.2028

37.45
36.50

0.0152

0.0000
0.0720

-41-

reactions.

It was thought that the maximum error in an arsenite-

iodine titration (0.015 U arsenite) "was one drop (0.05 ml.) of the
arsenite solution.

This error would correspond to 0.00375 milliequiv-

alents of HIO4 per gram of cellulose.

Therefore, any method that

gives periodate consumption figures which check within 0.004 meq./g.
would be considered a satisfactory analytical method.

Reproduci­

bility within this limit was easily obtained in short time oxidations.
On the other hand, larger errors or variations in the periodate
consumption by comparable samples may be encountered.

Some of the

factors to which these variations might be attributed are as follows:
(1) Variations in the volumes of solutions delivered from a
standard pipet might result in a periodate consumption that would be
too high or too low.

An error of one drop (0.05 ml.) of 0.06 N

periodic acid would correspond to 0.015 milliequivalents of HIO^ per
gram of cellulose.
(2) The presence of impurities might catalyze the decomposition
of periodic acid and result in a periodate consumption that would
always be too great.

This effect would be more significant in long

time oxidations.

(3 ) Differences in the swollen condition of the cellulosic mater­
ial might permit more rapid or slower diffusion of the oxidant into
the interior of the fiber and thus result in a periodate consumption
that would vary according to the rate of diffusion.
also be more apparent in long time oxidations.

-42-

This effect would

Oxidation of Cellulose Acetates:

The Pour Hour Reaction.

Cellulose acetate samples No, 8 to 14 were oxidized in these
experiments.

Since it was found that the determination of the excess

periodic acid in an oxidation mixture by direct titration yielded
reproducible results, this simple technique was used in the following
experiments.
At least two samples of each cellulose acetate and several sam­
ples of standard cellulose were oxidized for each of the following
time periods:

0.5, 1.0, 1.5, 2, 2.5, 3, 3.5, and 4 hours.

A few of

the first oxidations were also recorded for time periods of 0.25 and
0.75 hours, but this practice was later abandoned.

Time schedules that

would allow the oxidation of 16 samples in one series were established.
No two samples of the same cellulose acetate were oxidized for the
same length of time in any one schedule.

This rule was established so

that the reproducibility of the results could be compared between
experiments performed on different days and perhaps under slightly
different conditions.

The standard procedure used for all of these

oxidation experiments is described below.
A sample of cellulose or cellulose acetate approximately 0.2 g.
in weight was weighed into a 125-ml. Erlenmeyer flask and suspended in
10 ml. of water measured with a standard pipet at 20° C.

The flask

was weighted and thermostated at 30° C. for a 1 hour wetting and swell­
ing period.

A 250-ml. glass stoppered conical flask containing 200 ml.

of stock periodic acid solution was also thermostated at 30° C.

At

zero time, 10 ml. of this periodic acid solution was measured with a

standard pipet (calibrated for 30° C.) into the reaction flask and
mixed with the suspended linters*

Care was taken to prevent the lin­

ters from clinging to the sides of the flask and thus avoid contact
with the oxidizing medium*

The linters were allowed to steep, without

any mixing, in the reaction flask for the desired length of time*

At

the end of the reaction time the flask was plunged into ice water at
0° C. for 2 minutes and analyzed immediately for unreacted periodic
acid.

The standard arsenite solution was delivered from a 50-ml*

buret.

After analysis of the sample was completed, or during a 2 hour

period following the time of analysis, at least three 10 ml. samples of
periodic acid solution were removed from the conical flask that was
previouslythermostated
with a pipet

at 30° C,

These samples were also measured

calibrated at 30° C. andwere used as blank determina­

tions of the normality of the stock periodic acid solution.
The oxidation data for cellulose and cellulose acetates No. 8 to
14 are recorded in table 17.

The symbols S.C. and CAc are used to

designate standard cellulose and cellulose acetate respectively.

The

consumption of periodic acid expressed in milliequivalents per gram of
cellulose or cellulose acetate is also recorded in table IV.

This cal­

culation was made for each sample from the equation:
•n»*-—.
/
_ (B-S)
(N of arsenite)
------------- — ■
HIOa meq./ g. : ~
4
(g. of S.C. or CAc)

•

where B is the average ml. of arsenite solution used to titrate the
blanks, and S is the ml. of arsenite used to titrate the oxidation
solution.

-44-

TABLE 17
OXIDATION OF CELLULOSE AND CELLULOSE ACETATES
(Oxidations up to 4 hours)

Reaction
Time,
hrs.

Temp.
°C.

Sample
Wgt.,

Ars enite
Titer,
ml.

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

S.C.

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.95

0.0000
0.1974
0.1965
0.2002
0.1944
0.1960
0.2010
0.1965
0.2005

39.50
38.65
37.90
37.40
36.82
36.40
35.90
35.55
34.90

0.0147

0.0000
0.0637
0.1206
0.1550
0.2050.
0.2340
0.2640
0.3003
0.3390

S.C.

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

30.00

0.0000
0.1929
0.1976
0.1995
0.1966
0.2009
0.1972
0.1994
0.2003

39.50
38.52
38.87
37.35
36.90
36.25
35.90
35.50
35.00

0.0147

0.0000
0.0753
0.1220
0.1590
0.1960
0.2400
0.2695
0.2970
0.3320

S.C.

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2028
0.1975
0.1983
0.1995
0.1986
0.1985
0.2006
0.2013

37.45
36.50
35.90
35.30
34.75
34.40
33.90
33.45
33.10

0.0152

0.0000
0.0720
0.1195
0.1650
0.2060
0.2340
0.2720
0.3030
0.3280

CAc
No. 8

0.0
0.25
0.5
0.75
1.0
1.5
2.0

29.90

0.0000
0.1903
0.1941
0.1912
0.1901
0.1922
0.1885

38.25
37.75
37.40
37.05
36.85
36.27
35.75

0.0149

0.0000
0.0440
0.0651
0.0935
0.1096
0.1550
0.1980

Sample
Number

(Cont'd. next page)
•45-

TABLE IV - Continued

Sample
Humber

Reaction
Time,
hrs.

Temp.
. °c.

Sample
Wgt.,
S»

Arsenite
Titer,
ml.

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

CAc
No. 8

0.0
0.25
0.5
0.75
1.0
1.5
2.0

29.90

0.0000
0.1948
0.1925
0.1946
0.1922
0.1917
0.1943

38.25
37.63
37.35
37.00
36.75
36.20
35.70

0.0149

0.0000
0.0474
0.0696
0.0956
0.1160
0.1480
0.1950

CAc
No. 8

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

30.00

0.0000
0.1983
0.1986
0.2019
0.2007
0.1987
0.1982
0.1998
0.1985

39.50
38.63
37.95
37.35
36.90
36.45
35.95
35.60
35.25

0.0147

0.0000
0.0655
0.1154
0.1575
0.1920
0.2270
0.2650
0.2900
0.3170

CAc
No. 9

0.0
0.25
0.5
0.75
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2027
0.1940
0.1948
0.1995
0.2007
0.1998
0.1998
0.2016
0.1980
0.1942

37.80
37.28
37.00
36.75
36.60
35.90
35.55
35.05
34.60
34.25
34.05

0.0147

0.0000
0.0378
0.0607
0.0790
0.0887
0.1390
0.1653
0.2020
0.2330
0.2640
0.2840

CAc
No. 9

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2016
0.2018
0.1971
0.1993
0.1969
0.1966
0.2023
0.1969

39.50
38.65
38.10
37.65
37.22
36.80
36.50
35.90
35.75

0.0147

0.0000
0.0625
0.1025
0.1405
0.1690
0.2035
0.2260
0.2640
0.2830

(Cont’d next page)

-46-

TABLE IV - Continued

Sample
Number

Reaction
Time,
hrs.

Temp.
°C.

Sample
Wgt.,
g»

Arsenite
Titer,
ml.

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

CAc
No. 10

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.80

0.0000
0.1957
0.1944
0.1931
0.1983
0.1961
0.1988
0.1982
0.1950

39.50
38.90
38.30
37.80
37.30
36.95
38.45
36.20
35.90

0.0147

0.0000
0.0456
0.0915
0.1300
0.1642
0.1920
0.2270
0.2460
0.2760

CAc
No. 10

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.1933
0.1966
0.1967
0.2012
0.2017
0.2003
0.2001
0.1952

39.50

0.0147

38.30
37.85
37.30
36.90.
36.43
36.20
35.85

0.0000
...
0.0905
0.1240
0.1620
0.1910
0.2270
0.2440
0.2770

CAc
NO. 11

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.1957
0.2010
0.2010
0.1982
0.1970
0.2015
0.2024
0.1965

39.50
38.55
38.05
37.55
37.15
36.75
36.42
36.05
35.70

0.0147

0.0000
0.0715
0.1064
0.1433
0.1760
0.2060
0.22 60
0.2520
0.2860

CAc
No. 11

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.1995
0.1976
0.2002
0.1961
0.1991
0.1952
0.1919
0.1978

39.50
38.55
38.05
37.55
37.10
36.75
36.50
-----

0.014-7

0.0000
0.0702
0.1085
0.1440
0.1810
0.2040
0.2272

(Cont'd next page)

-47-

TABLE IV - Continued

Sample
Number

Reaction
Time,
hrs.

Temp.
°C.

Sample
Wgt.,
g*

Ars enite
Titer,
ml.

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

CAc
No. 11

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2013
0.1989
0.2009
0.1965
0.2019
0.2005
0.1985
0.1951

37.45
36.50
36.05
35.60
35.20
34.80
34.45
34.20
33.75

0.0152

0.0000
0.0713
0.1065
0.1400
0.1740
0.2000
0.2275
0.2490
0.2880

CAc
No. 12

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.1986
0.1985
0.1998
0.2001
0.2019
0.2007
0.2028
0.2018

37.60
36.70
36.20
35.50
35.15
34.60
34.15
33.80
33.30

0.0152

0.0000
0.0690
0.1075
0.1600
0.1860
0.2260
0.2 610
0.2860
0.3240

CAc
No. 12

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2025
0.2025
0.1986
0.1979
0.1983
0.1986
0.1988
0.1982

37.60
36.65
36.15

0.0152

0.0000
0.0730
0.1090

35.10
34.60
34.15
33.80
33.35

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2015
0.1982
0.1978
0.2018
0.2024
0.1995
0.1985
0.1995

37.45
36.65
36.05
35.60
35.20
34.60
34.40
33.80
33.60

CAc
No. 13

0.1920
0.2300
0.2 640
0.2910
0.3260

0.0152

0.0000
0.0605
0.1070
0.1420
0.1690
0.2120
0.2320
0.2800
0.2930

(Cont'd next page)

-48-

TABLE 17 - Concluded

Normality
of St.
Ars enite

Reaction
Time,
hrs.

Temp,

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.1988
0.1969
0.2028
0.2011
0.2020
0.2000
0.2011
0.1979

37.45
36.65
36.10
35.55
35.20
34.80
34.40
33.90
33.62

0.0152

0.0000
0.0615
0.1040
0.1425
0.1695
0.1990
0.2310
0.2680
0.2940

CAc
No. 14

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.1999
0.2019
0.2004
0.2008
0.2021
0.2012
0.2000
0.2009

37.25
36.27
35.65
35.05
34.60
34.15
33.75
33.30
32. B5

0.0152

0.0000
0.0745
0.1210
0.1660
0.2010
0.2340
0.2 640
0.3000
0.3340

CAc
No. 14

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

29.90

0.0000
0.2005
0.2012
0.2007
0.2029
0.2018
0.2020
0.2010
0.1991

37.25
36.35
35.65
35.15
34.70
34.10
33.70
33.30
32.85

0.0152

0.0000
0.0685
0.1210
0.1590
0.1920
0.2370
0.2680
0.2980
0.3360

Sample
Number

°c.

Sample
Wgt.,
g.

-49-

Ars enit e
Titer,
ml.

m o

C0XlSUffl’6Cl f
meq./ g.

In literature dealing with periodate oxidation the consumption
of periodate is usually expressed in terms of moles of HIO4 consumed
per unit molecular weight.

The conversion of mi H i equivalents per

gram to moles per unit molecular weight can be made by multiplying by
the unit molecular weight and dividing by 2000, as shown below:
Consumption of HI0A in moles
f
/
%
_ meq./ g.
per unit molecular weight

^

(unit molecular weight)
(2000)

The average consumption of periodate expressed in meq./g. was con­
verted to moles per unit molecular weight for all the oxidation time
periods recorded for cellulose and cellulose acetates.
are recorded in table 7.

These values

Inspection of the figures for the consump­

tion of periodate expressed in meq./g. shows that there is a consistent
difference between the consumption of periodate by cellulose and that
consumed by the cellulose acetates.

In general, the consumption of

periodate decreases slightly as the per cent combined acetic acid in­
creases.

However, the effect of an increasing degree of acetylation on

the periodate oxidation of cellulose acetates cannot be seen when the
consumption of periodate is expressed in meq./ g., since any cellulose
acetate according to its acetyl content, contains less than 100^ cellu­
lose.

On the other hand, the consumption of periodate expressed in

moles per unit molecular weight shows this effect.

In column 4 of

table 7 it can be seen that the differences in the consumption of
periodate between cellulose and cellulose acetates of low acetyl con­
tent are actually quite small for oxidation periods up to 4 hours.

-50-

The rate of oxidation may be illustrated by plotting the consump­
tion of HIO4 in moles per unit molecular weight against reaction time
in hours.

Such a graph shows the effect of increasing degree of acetyl-

ation on the periodate oxidation of cellulose acetates, i.e., the
acetyl substituents on the glycol groups of cellulose prevent cleavage
of these glycol groups by periodate oxidation, and therefore, the
higher the degree of acetylation the lower the consumption of periodate
per unit of time.
Figure 2 is a graph showing the rate of oxidation curves for stand­
ard cellulose and cellulose acetate No. 9 (6.83% HOAc).

Curves for the

other cellulose acetates are not shown because they are either the same
as that for cellulose (CAc No. 14, 1.28% HOAc), or fall slightly below
the curve for cellulose (CAc No. 8, 3.17% HOAc and CAc No. 12, 3.84%
HOAc), or fall near the curve for cellulose acetate No. 9 (CAc No. 11,
9.53% HOAc, and CAc No. 13, 7.10% HOAc).

-51-

TABLE V
CONVERSION OF PERIODATE CONSUMPTION FROM MILLIEQUIVALENTS
PER GRAM TO MOLES PER UNIT MOLECULAR WEIGHT
Reaction
Sample No.
Time,
_______________ hrs.

Periodate Consumption
Milliequivalents Moles per Unit
per Gram (av.)
Molecular Wgt.

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0703
0.1204
0.1600
0.2020
0.2360
0.2690
0.3000
0.3330

0.005695
0.009750
0.01295
0.01635
0.0191
0.0218
0.0243
0.0270

CAc
No. B
3.17% HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0667
0.1137
0.1535
0.1950
0.2270
0.2 650
0.2900
0.3170

0.005525
0.00942
0.01272
0.01616
0.01881
0.02198
0.02403
0.02630

CAc
No. 9
6.83% HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0 *

0.0616
0.0956
0.1402
0.1671
0.2027
0.2300
0.2 640
0.2835

0.00524
0.00813
0.01192
0.01422
0.01722
0.01955
0.02245
0.02410

CAc
No. 10
6.06% HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0456
0.0910
0.1270
0.1631
0.1915
0.2270
0.2450
0.2 765

0.00386
0.00770
0.01075
0.01380
0.01620
0.01920
0.02072
0.02340

S.C.

(Cont’d next page)

-52-

TABLE V - Concluded
Reaction
Periodate Consumption
Sample No.
Time,
Mi H i equ iva 1ent s Holes per Unit
_____________ hrs.___ per Gram (av.)
Molecular Wgt.
CAc
No. 11
9.53/? HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0710
0.1071
0.1424
0.1770
0.2033
0.2270
0.2505
0.2B70

0.00616
0.00930
0.01236
0.01535
0.01765
0.01970
0.02174
0.02490

CAc
No. 12
3.84% HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0710
0.1082
0.1600
0.1890
0.2280
0.2625
0.2885
0.3250

0.00590
0.00900
0.01333
0.01574
0.01900
0.02185
0.02400
0.02705

CAc
No. 13
7.10% HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0610
0.1055
0.1422
0.1692
0.2050
0.2315
0.2740
0.2935

0.00520
0.00899
0.01212
0.01442
0.01747
0.01975
0.02338
0.02500

CAc
No. 14
1.28% HOAc

0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0

0.0715
0.1210
0.1635
0.1965
0.2355
0.2660
0.2990
0.3350

0.00584
0.00988
0.01335
0.01605
0.01923
0.02172
0.02430
0.02735

-53-

weight X 100
molecular
unit
per
of HIO 4 , mols
Consumption

1.0

Time, hours
Figure 2
Periodate oxidation, initial reaction, 30*C.
O

Cotton cellulose

+

Cellulose acetate N o 0 9, 6 083$ H0Aco

Long Time Oxidations and the Effect of Mixing.
In the preceding section cellulose and cellulose acetates were
oxidized for time periods up to four hours.

During this more or less

initial phase of the reaction, with respect to the over-all theoreti­
cal oxidation, the rate of reaction is fairly rapid, due to the greater
accessibility of the glycol groups present in the amorphous and semi­
crystalline areas of cellulose.

A study of the effect of partial

acetylation on the periodate oxidation of cellulose would not be com­
plete unless the oxidations were carried out over a fairly long period
of time.

This section deals with oxidation experiments that were per­

formed for time periods of several days, and the reaction period that
was selected for comparisons between cellulose and cellulose acetates
was 60 hours.
The first experiment in long time oxidation was performed on
standard cellulose for varying periods of time up to 120 hours.

Except

for the volume of oxidizing solution and the method of sampling for
excess HIO4, the oxidation procedure was the same as that used in the
4-hour oxidations.

The total amount of available periodate in a 4-

hour oxidation mixture was approximately 3 meq. per gram of cellulose
or 0.243 moles of periodate per unit molecular weight.

In 4 hours

cellulose consumed 0.027 moles of HIO4 per unit molecular weight, and
therefore, the concentration of the oxidation medium changed a little
over 10% during the course of the oxidation.
It was thought that the concentration of the oxidizing medium
could be allowed to change as much as 50% without decreasing the rate

■55-

of reaction, since in this heterogeneous oxidation the rate of oxida­
tion is dependent more on the rate of diffusion of periodate into the
cellulose structure, than on the concentration of the oxidizing medium.
However, in order to minimize any possible change in the rate of oxi­
dation due to a decrease in the concentration of the oxidant, a con­
siderable excess of periodic acid was used in these long time oxida­
tions.

The volume of oxidant selected for use in the following experi­

ments was such that there were 7.5 milliequivalents of HIO^ for each
gram of cellulosic material.
A 0.2-g. sample of cellulose was weighed into a 125-ml. Erlenmeyer
flask, wetted with 25 ml. of water, and 25 ml. of approximately 0.06 N
HIO4 solution was added.

After oxidation and cooling the mixture was

filtered through a Gooch crucible into a clean 125-ml. flask.

Two

20-ml. samples of this filtrate were analyzed for excess periodate.
Blank determinations were carried out at 24 hour intervals.

The aver­

age titration volumes of arsenite solution were used for the calcula­
tion of periodate consumption.

The equation used to calculate the con­

sumption of periodate was as follows:

HIO4 meq./g.

Z

(B-S)

(N of arsenite)
(g. of cellulose)

(2.5)

where B is the ml. of arsenite used to titrate the blank; and S is
the average titer for the 20-ml. fractions of the filtrate solution.
The results of these oxidations are recorded in table VI.

-56-

TABLE VI
PERIODATE OXIDATION OF CELLULOSE UP TO 120 HOURS

Reaction
Time,
hrs.

0
3
6
12
IB
24
36
48
60
77.5
96
120

Temp.
°C.

Sample
Wgt.,
g»

29.85

0.0000
0.1997
0.1993
0.2005
0.2011
0.2002
0.2002
0.1985
0.1972
0.2000
0.2015
0.1996

Arsenite
Titer,
ml.

44.85
43.20
42.10
40.65
39.00
37.70
35.35
33.10
32.20
28.65
26.30
23.15

Normality
of St.
Arsenite

hio4
HIO4
Consumed Consumed
meq./ g. Moles per
Unit Mol.
Wgt.

0.01462

0.0000
0.2923
0.5040
0.765
1.064
1.305
1.735
2.165
2.344
2.960
3.350
3.710

0.00000
0.02318
0.04082
0.06195
0.0862
0.1057
0.1405
0.1754
0.1900
0.2398
0.2713
0.3004

In all of the previous experiments the oxidation mixture was not
stirred or mixed in any way during the reaction period.

Other investi­

gators studying the periodate oxidation of cellulose have mentioned
the use of ’’frequent shaking” or ’’occasional stirring” as having been
applied during the course of the reaction*

Any procedure of this sort

would be very difficult to standardize for a great number of oxidation
mixtures, and therefore, it was thought that the problem of applying c
controlled stirring during the reaction period should be investigated.
Because of the limitations of space, equipment, and time, the
application of stirring to a large number of small reaction flasks was
considered to be unfeasible.

A more efficient method of attack would

-57-

be to oxidize a fairly large amount of material with a proportionally
larger volume of oxidizing solution, the mixture being stirred at a
constant rate.

Samples of the oxidation media could be removed at

various time intervals, analyzed, and the decrease in concentration
of the oxidizing solution used to calculate the periodate consumed by
the cellulosic material.

Sampling a reaction mixture that is a homo­

geneous solution in this way would only change the total volume of the
mixture and would not change the concentration of the materials in
solution.

However, in any mixture of lirrters suspended in an oxidiz­

ing solution, it would be quite impractical if not impossible to
obtain a homogeneous sample of the mixture.

On the other hand, if a

considerable excess of periodate is available at the beginning of an
oxidation, small samples of the solution may be removed at intervals
over a period of time without appreciably affecting the rate of the
reaction.

For example:

in one particular oxidation reaction, the

available periodate at the beginning of the oxidation was 7,18 meq./g.,
and at the end of 60 hours there was still 5.03 meq./ g. left in the
reaction flask, even though four 10-ml. samples of the solution had
been removed.

This means that 70% of the initial periodate is still

available, and therefore, the decrease in the amount of available
periodate due to sampling would not have affected the reaction rate
appreciably.
In the next experiments oxidations were carried out with mechani­
cal stirring.

The reaction mixtures were stirred with cone-drive

electric stirring motors, and samples were removed from the reaction

-58-

mixture at various intervals of time.

Several 1-liter 3-neck round

bottom flasks were fitted with stirrers and filter sticks.

The stir­

rer was a 6-mm. glass rod with a 45° bend 4 cm. from one end, and was
held in place in the flask by a glass sleeve extending through a cork
in the neck of the flask.

The filter stick was made from a 7-mm.

(inside diameter) x 25-cm. pyrex tube by shrinking the diameter of the
tube in an oxygen flame to 1 mm. at a point 1 cm. from one end.

A com­

pact mass of fine glass wool was pressed into this small cup and trim­
med even with the end of the tube.
to about 250 revolutions per minute.

Three stirring motors were regulated
Three sets of the reaction flask-

stirring apparatus could be placed in the constant temperature bath at
one time.
Oxidations were performed as followss

a 2-g. sample of cellulose

or cellulose acetate was weighed into the reaction flask and suspended
in 250 ml. of water measured with a standard 50-ml. pipet at 20° C.
This mixture was stirred for 1 hour at 30° C.

At zero reaction time

250 ml, of approximately 0.06 II periodic acid was measured with the
same standard 50-ml. pipet and added to the aqueous suspension of linters.

The reaction temperature rose to 30° C. within five minutes.

The available periodate in this oxidizing medium was 7.5 meq./g. or
0.607 moles of HIO^ per unit molecular weight.

At intervals of time,

according to a previously arranged schedule, 10-ml. samples of the
oxidizing solution were withdrawn through the filter stick with a
standard 10-ml. pipet calibrated at 30° C.

The inside diameter of

the filter stick was such that the pipet could be inserted to the

-59-

point of constriction in the filter stick.
for periodic acid content.

The samples were analyzed

Blank determinations were made at 24 hour

intervals.
Several oxidations with stirring were performed on cellulose and
cellulose acetate for periods up to 6 hours, with sampling at 0.5 hour
intervals.

This oxidation reaction was found to progress more rapidly

than that previously observed during a 4 hour period without stirring.
However, the results were not satisfactory from the standpoint of re­
producibility.

Apparently a variation in the rate of stirring affected

the rate of the reaction.

The data for one sample of cellulose is

recorded in table VIII so that a comparison may be made between the
rate of reaction between stirred and non-stirred reactions.

All other

data obtained in these experiments will be omitted.
The same oxidation procedure (above) was used to test the repro­
ducibility of results that would be obtained during a reaction where
the oxidation period was as long as 60 hours.

The stirring motors

were very carefully readjusted and synchronized for the same rate of
stirring.

The reaction medium was sampled at 12 hour intervals.

The

data obtained for cellulose and two samples of cellulose acetate are
recorded in table VIII.
The calculation of the consumption of periodate by a known weight
of cellulose is more complex in the case of a reaction mixture where
samples of the oxidant are removed at intervals.

The calculation may

be simplified if, for each time of sampling the total periodate content
of the solution is determined.

For example, at zero time the normality

60'

of the oxidizing medium (determined by a blank analysis) multiplied
by the •volume of the solution yields the total milliequivalents of
periodate present at this time.

Since the concentration of the solu­

tion is also determined at each sampling time, the total milliequivalents of periodate in the volume of solution present before sampling
may also be determined for each sampling time.

But each sample re­

moved contains some periodate, and therefore, the sum of the milliequivalents of periodate removed in previous samples must be added to
the milliequivalents present in the volume of solution at any sampling
time.

The difference between the periodate content of the reaction

mixture at zero time, and periodate content present at any sampling
time plus that present in the volumes of previously removed samples,
represents the periodate consumption of the cellulosic material.
This difference divided by the weight of cellulose or cellulose ace­
tate is the consumption of periodate in meq./g.

Table VII is the

record of a typical oxidation reaction that was stirred and in which
the progress of the reaction was followed by sampling the oxidizing
medium at 12 hour intervals.

-61-

TABLE VII
RECORD OF DATA AND CALCULATIONS FOR A TYPICAL OXIDATION
Cellulose sample, 1,9667 g.

A
Total Vol.
of HI04
Solution
ml.

B
Ars enite
titer for
10 ml.,
ml.

Normality (N) of arsenite, 0,01506

C

D

Normality
of HIO
Solution
B x N
10

Meq. of
HI04 re­
moved in
10 ml.
samp.
B x N

E

F

Meq. of Meq. of
HI04 in HI04 in
Volume
samples
previous­
(A)
D x A
ly remov­
10 ed

0
C onsumption of
Periodate
by the
Cellulose
Sample,Meq.

Consump­
tion of
H!0
meq./ g.

Reaction
Time,
hrs.

Samp.
No.

00

0

500

21.35

0.03215

0.000

16.08

0.000

16.08

0.000

0.000

12

1

500

19.05

0.0287

0.267

14.34

0.000

14.34

1.740

0.885

24

2

490

17.35

0.0261

0.261

12.81

0.287

13.097

2.983

1.518

36

3

4B0

16.05

0.0242

0.242

11.60

0.548

12.148

3.932

2.000

48

4

470

14.75

0.0222

0.222

10.45

0.790

11.240

4.840

2.461

60

5

460

13.70

0.0206

0.206

9.48

1.012

10.492

5.588

2.e42

Meq. of
HIO, in
Vol.(A)
plus
Meq. of
HI04 in
samp.re­
moved (F)

TABLE VIII
OXIDATION OP CELLULOSE AND CELLULOSE ACETATES WITH STIRRING
Samp.
No.

°c.

Sample
Wgt.,
g-

Arsenite
Titer,
ml.

N of St.
Ars.

0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
5.0
6.0

29.85

1.9079

22.42
21.95
21.65
21.50
21.35
21.25
21.10
21.00
20.87
20.65
20.40

0.01462

00
12
24
36
48
60
72
96
120
168
250

29.85

22.42
20.15
18.60
17.40
16.30
15.15
13.90
11.65
9.65
5.30
0.00

0.01462

00
12
24
36
48
60

29.85

21.35
19.05
17.35
16.05
14.75
13.70

0.01506

CAc ’
No. 18
8.23/
HOAc

00
12
24
36
48
60

29.85

21.35
19.65
18.25
16.95
15.90
15.00

0.01506

CAc
No. 20
14.14/
HOAc .

00 ’
12
24
36
48
69

29.85

21.35
19.68
18.60
17.55
16.60
15.80

0.01506

S.C.

s .c .

S.C.

React.
Time,
hrs.

Temp.

1.9149

1.9667

2.0013

1.9987

63-

hio4
Consumed
meq./ g.

hio4
Consumed
moles
per U.M.W.

0 .0 0 0 0

0 .0 0 0 0

0.1940
0.2880
0.3740
0.4190
0.4492
0.5110
0.5423
0.5940
0.6590
0.7320

0.0157
0.0233
0.0303
0.0339
0.0364
0.0414
0.0439
0.0481
0.0534
0.0593

0 .0 0 0 0

0 .0 0 0 0

0.8780
1.479
1.910
2.300
2.706
3.132
3.900
4.560
5.950
7.600

0.0712
0.1198
0.1547
0.1864
0.2190
0.2540
0.3160
0.3695
0.4840
0.6160

0 .0 0 0 0

0 .0 0 0 0

0.885
1.518
2.000
2.461
2.842

0.0717
0.1230
0.1620
0.1995
0.2302

0 .0 0 0

0 .0 0 0 0

0.639
1.106
1.628
2.000
2.306

0.0549
0.095
0.140
0.172
0.198

0 .0 0 0

0 .0 0 0 0

0.630
1.023
1.415
1.750
2.023

0.0566
0.0918
0.12 72
0.1575
0.1820

Oxidation of Cellulose Acetates for 60 Hours with Standard Mixing.
The proceeding oxidation experiments, in which standard cellulose
and cellulose acetates No. 8 and 14 were oxidized for 60 hours with
stirring, and in which the oxidation mixtures were sampled at 12 hour
intervals to determine the decrease in periodate concentration, indi­
cated that there was an appreciable difference in the consumption of
periodate between standard cellulose and cellulose acetates.over this
period of time.

The problem of synchronizing the electric stirring

motors, so as to produce an equal rate of stirring, still remained to
be solved.

The only logical solution to this problem appeared to lie

in the design and construction of a special standard mixing apparatus
that would not only fulfill the limitations of space and the necessity
of a constant temperature bath, but also permit the mixing of several
reaction mixtures under exactly the same conditions.
The thermostating and standard mixing apparatus is illustrated in
figure 3.

The specifications and construction of the standard mixing

apparatus are described below.
The main axis of rotation (2) was made from a 0.5-inch round steel
rod, 46 cm. in length.

A 1-cm. flat was machined along the top of this

rod, except for 2 cm. at the points of support.

The main axis was sup­

ported on the battery jar by two bearings that could be clamped firmly
to the jar, and held in place by cotter pins at the bearings.

Four

motor arms, 20 cm. in length were made to fit on the axis, and could be
fixed in any desired position by tightening a set screw on the flat of
the axis.

Three of the motor arms were fixed about 10.5 cm. apart on

-64

the main axis.

A 2-mm. hols was drilled in each end of these arms at

a point 6 cm. from the axis.

The fourth motor arm was fixed on the

right end of the axis, and was connected to the source of power by
means of a connecting rod attached 5 cm. off-center at the motor arm,
and 1.5 cm. off-center on a wheel at the power source.

The length of

the connecting rod could be adjusted and was free to move around a
bearing at the points of connection.
The source of power (4) was a one-third horse power, 1725 r.p.m.
electric motor coupled with a reducing gear (reduction ratio, 21.5)
by means of a 0.5-inch V belt operating on 1-inch pulleys.

The angular

speed of the power source was 80 r.p.m., so that the up and down motion
observed in the reaction flasks also took place at a rate of 80 cycles
per minute.
The reaction flask detail can be seen quite clearly in figure 4.
Ten matched sets of this apparatus were assembled.

The flask was a

250-ml. 3-neck round bottom pyrex flask, 10 cm. in diameter, and
selected for uniformity of dimensions.

The plunger was made of pyrex

glass by fusing a 6-mm. x 12.5-cm. rod to a cup, 2.5 cm, in outside
diameter and 3 cm. long.

A No. 12 cork was fitted with a sleeve made

from a 7-mm. (inside diameter) pyrex tube 5 cm. long, with a 1-cm.
jacket of 6-mm. rubber tubing at one end.

The glass rod portion of the

plunger was put through this snugly fitting sleeve •which acts as a
bearing in the up and down motion cycle of the plunger.

A 1-cm. length

of 6-mm. brass rod, containing a 2-mm. transverse hold drilled 2 mm.
from one end was fitted with a 1 x 1.4-cm. steel wire staple bent in

-65-

a \_] shape.

The bottom half of the small brass rod was connected to

the top of the plunger rod with a 1.5-cm. length of tough 4-mm. rubber
tubing.
wire.

This connection was wrapped with five turns of 1-mm. copper
The top part of the plunger rod was lubricated with a small

amount of silicone grease to facilitate the operation of the plunger
in the bearing sleeve.
The filter stick was made from a pyrex tube, 7 mm. in inside dia­
meter, and 14 cm. in length.

The diameter of the tube was carefully

reduced in an oxygen flame to 1 mm. at a point 1 cm. from one end.
The top of the filter stick was jacketed with a 1.5-cm. length of 6-mm.
rubber tubing.

The filter stick was held in position in one of the

side necks of the reaction flask by a No. 8 cork.

A cork of the same

size was used to stopper the other side neck.
The flasks were held in a rigid position in the constant tempera­
ture bath by specially constructed clamps.

These clamps were in turn

held by universal clamps attached to a transverse rod as shown in
figure 3.
as follows:

A flask clamp that would hold three 250-ml. flasks was made
three holes 3 cm. in diameter were drilled with 10.5 cm.

between centers along the width of a piece of wood 3 cm. thick, 5 cm.
wide, and 27 cm. long.

Eight-mm. holes were drilled transverse to the

width and halfway between the centers of the large holes.

The wood was

then cut in half along the width, and each half was sanded down so as
to fit comfortably between the necks of the flasks.
was bolted to a 20-cm. x 0.5-inch steel rod.

One of the halves

The clamps when in posi­

tion around the center necks of the three flasks were held together by
two bolts with wing nuts.

-66-

To assemble the standard mixing apparatus for an oxidation experi­
ment the main axis of rotation, with its motor arms, was mounted across
the diameter of the constant temperature bath.

Pieces of chamois

leather were placed between the glass and metal and the supports were
clamped firmly in place.

This part of the apparatus

place permanently if desired.

could be left in

The flasks containing samples to be

oxidized were arranged in the flask clamps and were fixed temporarily
in position in the bath.

The motor arms were tilted

up or down to per­

mit passage of the flask assembly, A plunger with cork was placed in
each flask and the wire staple at the top of the plunger rod was spread
apart and pressed into the small hole at the end of the motor arm,
small pair of pliers was used in this operation.
seated firmly in the neck of the flask.

A

The cork was then

The flask clamps were adjusted

to permit smooth operation of the plungers.

The mixing apparatus was

then connected to the source of power which had been carefully aligned
with the axis of rotation.

The flask clamps were readjusted if opera­

tion seemed noisy or caused excessive vibration.

Cross rods (not shown

in figure 3) were clamped permanently between the vertical rods support­
ing the source of power.

These rods maintained the alignment of the

apparatus and reduced the over-all vibration considerably.

When adjust­

ed properly the apparatus could be left in operation for periods as
long as a week without requiring any attention or servicing.

While in

operation the constant temperature bath was shielded from the electric
motor by a thick asbestos sheet.
motor operated at about 65° C,

This was found necessary because the
Bearings and plunger rods were occasion­

ally lubricated with silicone grease.

-67

Figure 3
Thermostating and Standard Mixing Apparatus
(1) Thermostat.
(2) Axis of rotation with motor arms.
(3) Reaction flasks.
(4) Source of power.

-68-

II II
f-'—
n t -----)
L _ ------------— h ------------- w~f

Figure 4A

Flask, 2S0 ml. J-neck R.B.

B

Filter stick

C

Glass plunger moving through distance

D

P'lexible connection

E

Motor arm, fixed on axis of rotation

1d 1

Oxidation experiments on cellulose and cellulose acetates No. 16
to 26 were performed in the standard mixing apparatus.
were performed at the same time.

Six oxidations

The procedure was as follows:

one-g.

samples of standard cellulose or cellulose acetate were weighed into
the reaction flasks and suspended in 150 ml. of water measured with a
standard 50-ml. pipet at 20° C.

The flasks were then assembled in

the constant temperature bath, and the plungers were placed in position
and connected with the motor arms.

The electric motor was started and

the aqueous suspension of linters was mixed for 1 hour.

Minor adjust­

ments in the alignment of the flask apparatus was made during this
time, so that the operation of the mixing apparatus was as smooth and
quiet as possible.
period.

The filter sticks were also prepared during this

A compact mass of pure glass wool was pressed into each fil­

ter stick cup and trimmed even with the end of the tube.

The six re­

action flasks were numbered from 1 to 6. At zero reaction time, 150ml. volumes of approximately 0.06 N HIO4 solution were measured with
a standard 50-ml. pipet at 20° C. and added to the reaction mixtures
in the order:

1, 2, 3, 4, 5, and 6.

minute intervals.

The additions were made at 5

A filter stick was placed in each reaction flask.

At each sampling time, i.e., at oxidation periods of:

12, 24, 36, 48,

and 60 hoursj a 10-ml. sample of the oxidizing solution was removed
from each flask through the filter stick with a 10-ml. pipet calibrated
for 30° C., and analyzed for excess periodic acid.

The 5 minute inter­

val between sampling of different reaction flasks was sufficient to
allow a short chilling period (30 seconds) and completion of the

70

arsenite titration for any sample before the next one was removed.
The standard arsenite solution was delivered from a 25-ml. buret.
Blanks were determined at 24 hour intervals.
At least two oxidations were performed for each cellulose ace­
tate No. 16 to 25.

No two oxidations of the same acetate were per­

formed during any one 60 hour period or in the same reaction flask.
This rule allows comparison of the reproducibility of results obtained
on different days and perhaps under slightly different conditions.
The data for oxidations of cellulose and cellulose acetates No. 16 to
25, for 60 hours with standard mixing, are recorded in table IX.
Calculation of the periodate consumption was made in the same manner
as described on page 60, and as illustrated in table VII.

Table X

shows the conversion of the average consumption of HIO^ in milliequivalents per gram to moles per unit molecular weight.

Figures

5 and 6 are graphs of the consumption of periodate in moles per unit
molecular weight plotted against reaction time.

It can be seen that

over a reaction period of 60 hours, the rate of periodate oxidation
of cellulose and cellulose acetates is approximately the same, but
the acetates, in the order of increasing degree of acetylation, con­
sume less periodate than is consumed by cellulose.

-71-

TABLE IX
OXIDATION OF CELLULOSE ACETATES FOR 60 HOURS WITH STANDARD MIXING.

Reaction
Time
hrs.

Temp.
°C.

Sample
Wgt.,
e*

Arsenite
Titer,
ml.

S.C.

00
12
24
36
48
60

2 9 .8 5

1.0012

S.C.

00
12
24
36
48
60

29.85

S.C.

00
12
24
36
48
60

S.C.

S.C.

Sample
Number

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

1 9 .7 5
1 7 .9 5
1 6 .8 0
1 5 .7 0
1 4 .7 0
1 3 .8 0

0 .0 1 5 0 6

0 .0 0 0 0
0 .8 2 0 0
1 .3 1 9 0
1 .7 8 6 0
2 .2 0 0 0
2 .5 4 8 0

1.0009

19.75
18.00
16.75
15.70
14. 70
13.70

0.01506

0,0000
0.7800
1.3270
1.7750
2.1800
2.5990

29.85

1.0001

19.75
17.95
16.90.
15.90
14.80
13.90

0.01506

0.0000
0.8100
1.2700
1.6955
2.1362
2.5132

00
12
24
36
48
60

29.85

0.9990

19.675
17.87
16.65
15.68
14.70
13.80

0.01506

0.0000
0.8200
1.3510
1.7600
2.1600
2.5130

00
12
24
36
48
60

29.85

1.0023

19.675
17.90
16.60
15.55
14.55
13.65

0.01506

0.0000
0.8000
1.3660
1.8060
2.2200
2.5700

(Cont'd next page)

-72-

TABLE IX - Continued

Arsenite
Titer,
ml.

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

0.01335

0.0000

Reaction
Time
hrs.

Temp.
°C.

Sample
Wgt.,
g.

00
12
24
36
48
60

29.e5

0.9973

00
12
24
36
48
60

29.85

1.0040

19.75
18.20
17.00
15.95
15.00
14.10

0.01506

0.0000
0.6980
1.2100
1.6600
2.0400
2.3950

CAc
No. 16

00
12
24
36
48
60

29.85

0.9995

19.55
18.05
16.90
15.90
14.90
13.85

0.01506

0.0000
0.6800
1.1780
1.6040
2.0100
2.4200

CAc
No. 1.7

00
12
24
36
48
60

29.es

1.0030

19.75
18.35
17.25
16.40
15.50
14.60

0.01506

0.0000
0.6380
1.1200
1.4700
1.8420
2.1900

CAc
No. 17

00
12
24
36
48
60

29.85

0.9998

19.75
18.30
17.40
16.40
15.12
14.20

0.01506

0.0000
0.6600
1.0445
1.4725
1.8965
2.2490

Sample
Number

S.C.

CAc
No. 16

21.72
18.40

1.3400

16.35

2.1320

(Cont'd next page)

73-

TABLE' IX - Continued

Hormality
of St.
Ars enite

hio4
Consumed,
meq./ g.

19.75
18.45
17.27
16.30
15.32
14.42

0.01506

0i0000
0.6000
1.1020
1.5120
1.9147
2.2657

1.0027

19.75
18.50
17.48
16.60
15.80
15.00

0.01506

0.0000
0.5680
1.0080
1.3840
1.7150
2.0140

29.85

1.0000

19.75
18.40
17.50
16.77
15.80
15.10

0.01506

0.0000
0.6100
1.0030
1.3145
1.7070
1.9945

00
12
24
36
48
60

29.85

1.0005

19.75
18.65
17.70
17.00
16.30
15.60

0.01506

0.0000
0,5000
0.9180
1.2110
1.5050
1.7700

00
12
24
36
48
60

29.85

1.0017

19.75
18.60
17.70
16.95
16.25
15.53

0.01506

0.0000
0.5190
0.9080
1.2310
1.5150
1.8000

Reaction
Time
hrs.

Temp.
°c.

Sample
Wgt..,
g*

00
12
24
36
48
60

29.85

1.0008

CAc
Ho. 18

00
12
24
36
48
60

29.85

CAc
Ho. 18

00
12
24
36
48
60

CAc
Ho. 19

CAc
Ho. 19

Sample
Humber

CAc
Ho. 17

Ars enite
Titer,
ml.

(Cont’d next page)

-74-

TABLE IX - Continued

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

19.75
18.60
17.62
16.90
16.10
15.45

0.01506

0.0000
0.519
0.938
1.252
1.578
1.830

1.0005

19.55
18.35
17.48
16.75
16.02
15.30

0.01506

0.000
0.540
0.923
1.230
1.531
1.810

29.85

0.9982

19.80
18.72
17.92
17.00
16.25
15.60

0.01506

0.000
0.482
0.840
1.220
1.535
1.780

00
12
24
36
48
60

29.85

0.9980

19.75
IB.85
17.70
16.90
16.10
15.40

0.01506

0.000
0.401
0.908
1.252
1.580
1.850

00
12
24
36
48
60

29.85

1.0006

19.55
18.35
17.60
16.90
16.10
15.45

0.01506

0.000
0.540
0.873
1.168
1.494
1.747

Sample
Number

Reaction
Time
hrs.

Temp.
°C.

Sample
Wgt.,
g»

CAc
No. 19

00
12
24
36
48
60

29.85

1.0018

CAc
No. 19

00
12
24
36
•48
60

29.85

CAc
No. 20

00
12
24
36
48
60

CAc
No. 20

CAc
No. 20

Arsenite
Titer,
ml.

(Cont'd next page)

-75-

TABLE IX - Continued

Normality
of St.
Arsenite

HI04
Consumed,
meq./ g.

19.80
18.20
17.15
16.15
15.40
14.45

0.01506

0.000
0.721
1.189
1.600
1.910
2.2 75

1.0013

19.75
18.10
17.15
16.20
15.30
14.35

0.01506

0.000
0.750
1.175
1.575
1.931
2.300

1.002 8

19.80
18.30
17.30
16.45
15.67
14.90

0.01506

0.000
0.669
1.110
1.460
1.782
2.085

1.0021

19.75
18.30
17.25
16.40
15.55
14.75

0.01506

0.000
0.659
1.112
1.471
1.904
2.130

1.0015

19.75
18.45
17.45
16.50
15.60
14.80

0.01506

0.000
0.640
1.030
1.427
1.800
2.103

Sample
Number

Reaction
Time
hrs.

Temp.
°C.

Sample
Wgt.,
g.

Ars enit e
Titer,
ml.

CAc
No. 21

00
12
24
36
48
60

29.85

0.9986

CAc
No. 21

00
12
24
36
48
60

29.85

CAc
No. 22

00
12
24
36
48
60

29.85

CAc
No. 22

00
12
24
36
48
60

29.85

CAc
No. 23

00
12
24
36
48
60

29.85

*
■

■K

(Cont’d next page)

-76-

TABLE IX - Continued

Normality
of St.
Arsenite

hio4
Consumed,
meq./ g.

19.75
18.40
17.35
16.45
15.60
14.85

0.01506

0.000
0.578
1.110
1.438
1.790
2.085

1.0021

19.55
18.15
17.10
16.30
15.40
14.50

0.01506

0.000
0.628
1.095
1.420
1.790
2.142

29.85

0.9989

19.75
18.58
17.50
16.65
15.80
15.05

0.01506

0.000
0.522
1.005
1.357
1.706
2.000

00
12
24
36
48
60

29.85

1.0028

19.75
18.35
17.50
16.60
15.85
15.05

0.01506

0.000
0.638
1.000
1.356
1.685
2.000

00
12
24
36
48
60

29.85

1.0003

19.55
18.20
17.28
16.50
15.70
14.80

0.01506

0.000
0.610
1.010
1.335
1.667
2.021

Sample
lumber

Reaction
Time
hrs.

Temp.
°c.

Sample
Wgt.,
g.

CAc
No. 23

00
12
24
36
48
60

29.85

1.0022

CAc
No. 23

00
12
24
36
48
60

29.85

CAc
No. 24

00
12
24
36
48
60

CAc
No. 24

CAc
No. 24

Arsenite
Titer,
ml.

(Cont'd next page)

-77-

TABLE IX - Concluded

Sample
Numb er

Reaction
Time
hrs.

Temp.
°C.

Sample
Wgt.,
g*

CAc
No. 25

00
12
24
36
48
60

29.85

1.0006

00
12
2436
48
60

29.85

CAc
No. 25

Normality
of St.
Arsenite

HI04
Consumed,
meq./ g.

19.80
18.50
17.40
16.72
15.95
15.20

0.01506

0.000
0.580
1.070
1.360
1.670
1.956

19.75
18.72
17.60
16.72
15.85
15.10

0.01506

Arsenite
Titer,
ml.

■

0.9994

-78-

'

0.000
0.460
0.960
1.335
1.683
1.964

TABLE X
COWERS ION OF PERIODATE CONSUMPTION FROM MILLI EQUIVALENTS PER GRAM TO
MOLES PER UNIT MOLECULAR -WEIGHT

Periodate Consumption
Reaction
Time,
hrs.

Mi1li equ ivalents
per Gram
(av.)

Moles per Unit
Molecular Wgt.

12
24
36
48
60

0.8080
1.3290
1.7645
2.1741
2.5460

0.0655
9.1077
0.1430
0.1760
0.2063

CAc
No. 16
0. 65% HOAc

12
24
36
48
60

0.689
1.194
1.632
2.025
2.407

0.0561
0.0972
0.1328
0.1647
0.1958

CAc
No. 17
5,13% HOAc

12
24
36
48
60

0.633
1.090
1.484
1.881
2.235

0.0532
0.0916
0.1247
0.1582
0.1878

CAc
No. 18
8.23% HOAc

12
24
36
48
60

0.590
1.005
1.349
1.711
2.004

0.0507
0.0864
0.1160
0.1471
0.1723

CAc
No. 19
12.09% HOAc

12
24
36
48
60

0.5176,
0.9216
1.231
1.532
1.800

0.0458
0.0815
0.1089
0.1368
0.1592

CAc
No. 20
14.14% HOAc

12
24
36
48
60

0.474
0.874
1.213
1.536
1.792

0.0426
0.0789
0.1090
0.1381
0.1611

Sample No.

S.C.

(Cont’d next page)
79

TABLE X - Concluded

Periodate Consumption
Reaction
Time,
hrs.

Milliequivalents
per Gram
(av.)

Moles per Unit
Molecular Wgt.

CAc
No. 21
3.40# HOAc

12
24
36
48
60

0.735
1.182
1.587
1.920
2.287

0.0610
0.0981
0.1317
0.1585
0.1900

CAc
No. 22
5.31# HOAc

12
24
36
48
60

0.6635
1.1110
1.465
1.843
2.107

0.0558
0.0935
0.1233
0.1552
0.1773

CAc
No. 23
6.60# HOAc

12
24
36
48
60

0.615
1.080
1.435
1.793
2.110

0.0522
0.0917
0.1216
0.1522
0.1792

CAc
No. 24
8.65# HOAc

12
24
36
48
60

0.590
1.005
1.350
1.686
2.007

0.0509
0.0867
0.1165
0.1455
0.1731

CAc
No. 25
9.94# HOAc

12
24
36
48
60

0.520
1.015
1.347
1.676
1.960

0.0452
0.0882
0.1171
0.1458
0.1705

Sample No.

-80-

Consumption

of hiu 4 , mods

per

unit

moiecuiar

weignt

0.20

0.10

O

Cotton cellulose

-+

Acetate No. 16, 0.65$ HOAc

A

Acetate No. 17, 5*13$ HOAc

•

Acetate No. 18, 8.23$ HOAc

A

Acetate No. 20,14.14$ HOAc

0.05

24
3
Time, hours

48

Figure 5
Periodate oxidation, 60 hours at 30°C., with standard mixing.
-81-

weight
molecular
unit
per
of H 1O4 , moIs
Consumption

0.10

O

Cotton cellulose

+

Acetate No. 21, 3.40^ HOAc

0.05
22,

•

5.31% HOAc

Acetate No. 24, 8.65% HoAc
Acetate No. 15, 12.09$ HOAc

Time, hours
Figure 6
Periodate oxidations, 60 hours at 30°C., with standard mixing.

Periodate Oxidation of Sulfuric Acid Hydrocelluloses.
The cellulose acetates used in this investigation were acetylated in the presence of sulfuric acid.
cellulose in two ways:

This acid may react with

(1) it may hydrolyze some of the glycosidic

linkages of cellulose, and thereby decrease the degree of polymeri­
zation of the cellulose and increase the number of terminal groups
(those that have three adjacent hydroxyl groups); (2) it may form
sulfoesters with the hydroxyl groups of cellulose.

In terms of the

reaction of periodic acid with cellulose, an increase in the number
of adjacent hydroxyl groups would increase the consumption of perio­
date, but, if some of the glycol hydroxyls are esterified with sulfuric
acid, the consumption of periodate would be decreased.
In order to find out which of the reactions of sulfuric acid with
cellulose had the greatest effect on the periodate oxidation of cellu­
lose, the following experiment was undertaken.

Four 5-g. samples of

fibrous standard cellulose (numbered 1, 2, 3 and 4) were treated with
100-ml, portions of 0.5 M sulfuric acid and thermostated at 30° C.
for 1, 2, 3 and 4 hours respectively.

At the end of each reaction

time, the sample was washed thoroughly until free from acid (ten 1liter portions of water).

It was then steeped in 600 ml. of water at

60° C. for 24 hours, after which it was washed with four 1-liter por­
tions of water.

The sample was pulled apart, dried in a vacuum oven

at 55° C. for 4 hours, cut to 20-mesh linters, and conditioned at 6h%
relative humidity for several days.

-83-

Hydrocellulose samples 2, 3 and 4 were oxidized for 60 hours
with standard mixing in exactly the same manner as used for the oxi­
dation of cellulose acetates under these conditions.
these oxidations are recorded in table XI.

The data for

The symbol H.C. is used

to designate hydrocellulose.
At the top of table XI the average consumption of periodate is
listed for standard cellulose.

If the periodate consumption of the

hydrocelluloses are compared with that of standard cellulose, it can
be seen that the periodate consumption decreases slightly for hydro­
celluloses according to increasing length of time that these hydro­
celluloses were steeped in 0.5 M sulfuric acid.

The sulfate content

for the hydrocelluloses was not determined, as it was only desired to
find out which of the two reactions of sulfuric acid with cellulose
was predominant.

The preparation of hydrocelluloses involved the

use of a total of 0.0308 mole of cellulose units and 0.05 mole of sul­
furic acid.

The mole ratio would be 1 : 1.623, as compared with 1 s

0.238 used in the preparation of cellulose acetates.

The concentra­

tion of sulfuric acid used in hydrocellulose preparations was 0.5 M as
compared to 0.056 M used in the preparation of cellulose acetates.
The reaction time was generally longer in the case of the cellulose
acetates, but the sulfuric acid available for esterification was less,
and the acid was more dilute.

The data for the oxidation of the

hydrocelluloses may show the effect of sulfuric acid on the consumption
of periodate, but this data, due to the differences in conditions,
cannot be accurately compared with that for the periodate consumption

-84-

TABLE XI
PERIODATE OXIDATION OF SULFURIC ACID HYDROCELLULOSE

Sample
No.

^ *
S. c«

Reaction
Time,
hrs.

Temp.
°C.

Sample
Wgt.,
, g«

Arsenite
Titer,
ml.

N of
Ars enite

00
12
24
36
48
60

hio4
Consumed
meq./ g.

hio4
Consumed
Moles per
Unit Mol.
Wgt.

0.0000
0.8080
1.3290
1.7645
2.1714
2.5460

0.0000
0.0655
0.1077
0.1430
0.1760
0.2063

H.C.
No. 2

00
12
24
36
48
60

29.85

0.9985

19.675
18.00
16.85
15.85
14.85
13.90

0.01506

0.0000
0.761
1.263
1.690
2.098
2.470

0.0000
0.0616
0.1022
0.137
0.170
0.200

H.C.
No. 2

00
12
24
36
48
60

29.85

0.7304

19.675
18.55
17.60
16.90
16.80
15.4-8

0.01506

0.000
0.700
1.260
1.680
2.070
2.450

0.0000
0.0567
0.1020
0.1360
0.1680
0.1985

H.C.
No. 3

00
12
24
36
48
60

29.85

1.0031

19.675
17.95
16.75
15.68
14.70
13.85

0.01506

0.000
0.778
1.300
1.752
2.150
2.483

0.0000
0.0630
0.1055
0.1420
0.1740
0.2010

H.C.
No. 4

00
12
24
36
48
60

29.85

1.002 6

19.675
18.15
16.88
15.85
14.95
14.10

0.01506

0.000
0.688
1.239
1.679
2.043
2.372

0.0000
0.0557
0.1004
0.1360
0.1655
0.1920

* Standard Cellulose values are taken from X.

-85-

of cellulose acetates.

Further periodate oxidations of sulfuric

acid hydrocelluloses was left as a subject for future research.

Oxidation of Acetone Soluble Cellulose Acetates.
c

tn

The work of Purves and coworkers *

on the lead tetra-acetate

oxidation of acetone soluble cellulose acetates shows that a very
small number of glycol groups may exist in these highly acetylated
celluloses.

It was thought that it would be interesting to determine

whether or not the existence of such small amounts of glycol groups
could be confirmed by the periodate oxidation method.

Acetone solu­

ble cellulose acetates of comparable specifications were oxidized in
the following experiment.
Four Eastman Kodak commercial cellulose acetate samples were
labeled as shown below.
No. 4644:

Acetone soluble, low viscosity, high acetyl.

No. 4650:

Acetone soluble, low-medium viscosity, high acetyl.

No. 4655:

Acetone soluble, high-medium viscosity, low acetyl.

No. 2314:

Cellulose triacetate.

The samples were in the form of a coarse powder.

Each sample

was inspected for uniformity and cut in the Wiley mill to a 20-mesh
or finer powder and conditioned for several days fet 65$ relative
humidity.

Sample No. 4644- was found to contain 3.5$ moisture.

Each

sample was analyzed for per cent combined acetic acid as described
on page

. The results are listed in table XII.

Powdered acetone soluble cellulose acetate was very difficult to
wet with water and floated on top of the aqueous oxidizing medium.

-86-

TABLE XII
ANALYSIS OF COMMERCIAL CELLULOSE ACETATES

Cellulose
Acetate
No.

EK4644

Analysis for per cent Combined
Acetic Acid
ml. of
N of
HOAc
Sample
st.
st.
vrgt.,
%
EOH
KOH
e«
0.5856
0.6253
0.5301
0.0000

36.65
38.40
34.15
9.40

0.1934

0.5406
0.5621
0.5779
0.0000

34.88
36.00
36.80
9.40

0.1934

0.6004
0.5086
0.5478
0.0000

37.20
33.05
34.75
9.40

0.1934

0.5369
0.5327
0.5311
0.0000

36.90
36.10
37.10
9.40

37.90

2.356

261.0

38.55

2.421

263,e

37.80

2.348

260.6

41.72

2.767

278J2

54.00
54.20
53.90
av. 54.03

EK2314

Unit Mol.
Wgt.

54.90
55.10
55.30
av. 55.10

EK4655

Degree of
Substitu­
tion.

54.00
54.10
54.40
av. 54.16

EK4650

Percent
Acetyl

59.65
58.40
60.80

■0.1934

av. 59.62

-87-

The problem of wetting and dispersion was solved by the use of a very
small concentration of detergent,

A 0,01% aqueous solution of ’’Duponol

Mn dry” was the smallest optimum concentration that would wet the
powder in 10 minutes.

A volume of this 0,01% solution of detergent,

when mixed with an equal volume of approximately 0.06 II HIO^, did
not consume any periodic acid when the mixture was allowed to stand
for 72 hours at room temperature.
The three acetone soluble cellulose acetates and the cellulose
triacetate were oxidized in the standard mixing apparatus for 72 hours.
A sample of standard cellulose and a blank made up with the detergent
solution were oxidized at the same time.

The method of oxidation was

the same as used for the 60 hr. oxidation of cellulose and cellulose
acetates with standard mixing, except that only three 10-ml. samples
were removed from the oxidation reaction, and these at 24 hour inter­
vals.

Over the 72 hour period the concentration of periodate in the

reaction flasks containing the four commercial cellulose acetates re­
mained constant.

This shows that no oxidation of the cellulose ace­

tates occurred.

The suspended solid particles appeared to be swollen

and translucent at the end of the oxidation period, and there was no
reason to believe that the oxidizing solution had not been able to
penetrate throughout each particle.
The proportions of materials present during the lead tetra-acetate
5 17
oxidation of cellulose acetate as performed by Purves *
were:

0.01

mole of cellulose acetate (unit mol. wgt. 259.e) dissolved in 100 ml.
of glacial acetic acid that was 0.025 N with respect to lead tetra-acetate.

-68-

The reaction temperature was 25° C.

After a reaction time of about

80 hours, a break in the oxidation rate curve was interpreted to
mean that true glycol oxidation had ended, and at this point the
consumption of oxidant corresponded to 0,01 mole of glycol per unit
molecular weight.

This is the same thing as saying that there is 1

glycol group in 100 glucose residues, all of the other glycol groups
having been blocked by acetyl groups.
The question remains whether this small amount (0,01 mole) of
glycol could be detected over a 72 hour period of oxidation with 0,03
N periodic acid.

The consumption of periodate by cellulose over a

period of 72 hours under standard mixing conditions and at 30° C, was
only ,227 mole per unit molecular weight, and therefore only about
22,1% of the total glycol content had been oxidized.

On the other

hand, a commercial acetate is far more amorphous in structure than
native cellulose and therefore should be penetrated and oxidized more
rapidly.

If the value of 0,01 mole of glycol per unit molecular weight

is converted to a figure that would represent a difference between
blank and sample titrations with 0,015 IT arsenite (such as observed
during the course of a periodate oxidation), this value would corres­
pond to 0,17 ml.

Although a titration difference of this order could

be observed, it is doubtful that a smaller difference, say ,05 ml,
(that would correspond to only partial oxidation of a cellulose ace­
tate), could be determined by the method of analysis used.
In conclusion, it was considered that the work of Purves had not
been confirmed.

IV

DISCUSSION

THE NATURE OF FIBROUS CELLULOSE ACETATES OF LOW ACETYL CONTENT

The Acetylation Reaction.
The reaction of cellulose -with acetic anhydride to form cellulose
triacetate may he expressed asj
C6H70 2 (0 H )3

+

3(CH3 C 0 )2 0

_____ ^

C6H70 2 (0C0CH3 ) 3

+

3CHgC00H

This equation shows that at least three moles of acetic anhydride are
required to completely esterify the hydroxyl groups of cellulose.
The acetylation of cellulose proceeds very slowly unless a so-called
catalyst is added to the reaction mixture.

Sulfuric acid was used as

the catalyst in the preparation of the cellulose acetates studied in
this investigation.

Some of the ideas that have been expressed concern­

ing the specific role of sulfuric acid in the acetylation reaction
should be reviewed briefly.

Franchimont'*'® considered that sulfuric acid

reacted with acetic anhydride to form acetyl sulfuric acid.

This acid

is the acetylating reagent and reacts with cellulose to regenerate the
sulfuric acids

,P

ch 3 - ci

0
CH3-C^
0
c 6h 9 o4 oh

Ost

47

+

HgS04 —

+

CHgCOOH

+

CH3C00S020H

H0S02 0C0CH3 ______ C6H9 0 4 0C0CH3 +H2 S 0 4

studied the esterification of cellulose with sulfuric acid

and the formation of cellulose sulfoacetates.

His results indicate

that the reaction of sulfuric acid with cellulose precedes the forma­
tion of acetyl cellulose, and that the sulfo group is replaced by the
acetyl group.

-90-

Heuser^ considers that:

’’the chief function of the sulfuric

acid is to aid in the swelling of the cellulesic material and to de­
grade it”.

Degradation during the acetylation may reduce the degree

of polymerization of the original material as much as 90%, depending
on the severity and duration of the acid treatment.
The effect of the moisture content of the cellulosic material on
the rate of acetylation was studied by El8d and Schmidt-Bielenberg.^0
They measured the time of reaction necessary to obtain a product of a
certain degree of substitution using celluloses that contained:
6.7%, and 24.4% water.

0.1%,

The following figures are taken from the rate

of acetylation curves of Elod:
Combined Acetic acid in the product

10%

20%

30%

40%

Reaction time (hrs.) for cellulose:
0.1% water

B

16.5

25.5

36

4

9.5

15.5

24

0"

0”

6.7% wat er
24.4% water

1.2

2.

The experimental conditions used by Elod were those for the preparation
of fibrous cellulose acetates.

Figure 1 on page 2 7, shows that there

is no appreciable difference between the rate of acetylation at 45° C.
of cellulose containing 0.1% water, and that for the acetylation of
cellulose containing less than 1% water at 27 to 29° C., (the later contitions were used for the preparation of the cellulose acetate samples
that were used in this study).

-91-

The Fibrous Structure of Cellulose and the Acetylation Reaction,
Cotbon fibers are single plant cells that vary in length from
1 to 5 cm. and from 12 to 42 y- in thickness.

Each cell is composed

of a primary wall about 0.5 y thick, a thicker secondary wall, and a
main central core called the lumen.

Haw cotton contains about 0.5 to

1.0$ each of pectin and waxes that, are considered to be a part of the
primary cell wall, and may be removed by boiling with dilute alkali.
The proof of the chemical structure of cellulose and the arrange­
ment of the long cellulose chains in crystalline and amorphous patterns
in the so-called micellar structure, are the results of almost 100
years of study.

X-ray studies have shown conclusively that there is a

considerable degree of order in fine structure of cotton fibers.

In

recent years the study of the proportion of crystalline and amorphous
regions in cellulose has received considerable attention^**^.

The mi­

celles that are made up of cellulose chains may have a certain perio49 50
dicity of structure * , in that some of the glycosidic linkages are
apparently more vulnerable to attack by even the most mild acidic or
oxidative treatment.
With the concept of the micellar and plant cell structures of
cellulose well in mind, one can proceed to discuss the reactions of
the hydroxyl groups of cellulose.

Any reagent that will react with

these hydroxyl groups must either proceed gradually inward from the
surface of the fiber, or promote some rapid transformation in the micel­
lar structure so that all of the hydroxyl groups can be reached.

These

are two extremes in reaction types, the first being called "topochemical” ,

-92-

and the second "permutiodal". The nitration of cellulose is a good
example of a permutiodal reaction, wherein the nitration of cellulose
is complete within a short time after the reaction begins.

The acetyl-

27
ation reaction proceeds quite slowly and in a topochemical fashion •
Hess2® has referred to the acetylation reaction as a ’’micellarheterogeneous” reaction.

The heterogeneous nature of the reaction may

vary according to the procedure of acetylation.

pA
Herzog and LondbergG*

have shown that an outer layer of cellulose acetate may be dissolved
away from a partially acetylated fiber with nitrobenzene, to leave a
residue of unchanged cellulose.

Kanamaru®^ has made photomicrographs

of partially acetylated cellulose fibers (acetic anhydride and benzene).
These photomicrographs show that the acetylation reaction starts at
several fairly equally spaced points along the fiber, and bands of
acetylated material start to form around these points of attack, and
finally the bands expand gradually until all of the fiber is acetylated.
Kanamaru concludes that the reaction at the surface of the fiber pro­
ceeds to the triacetate stage.

The attack of the acetylating reagent

at definite intervals along the fiber has been compared to that observed
by certain wood destroying fungi , and both proceed along certain planes
referred to as planes of hydrolysis.
The course of acetylation may be followed by X-ray techniques if
the fibrous structure of cellulose is retained2^.

Hess and Trogus2®

found that the X-ray pattern of the original cellulosic material did
not change upon acetylation until a degree of acetylation, corresponding
to 43% combined acetic acid, had been reached.

-93-

At this point the

pattern for triacetyl cellulose became noticeable and increased until
at 53/$ combined acetic acid, the X-ray pattern of cellulose was no
longer present.

From this it might be surmised that the acetylation

reaction may not proceed entirely to the triacetate stage until a
fairly high degree of acetylation is attained.
The course of acetylation and deacetyiation of cellulose fibers
has been studied thoroughly by Vermaas and Hermans

63

.

These investiga­

tors, being aware of the physical aspects of the cellulose structure,
have attempted to prepare homogeneous partially acetylated cellulose
filaments.

According to the modern concept a swollen cellulose gel con­

sists essentially of a molecular network structure.

"In the course of

a substitution reaction like acetylation, the degree of substitution at
any given moment and at a given locus, will be a function of the degree
of accessibility at that locus".

Standard filaments of regenerated

cellulose were pre-swollen in an ether-acetic anhydride acetylating
mixture without catalyst.

At the beginning of the reaction the catalyst

(HgSO^) was in a very small concentration which was increased after the
reaction was started.

A series of partially acetylated cellulose

fibers prepared in this manner was found to be microscopically homo­
geneous, but of increasing thickness and decreasing birefringence with
increasing duration of the acetylation.

Vermaas and Hermans concluded

from these experiments that acetylation took place from the beginning
of the reaction in both the intererystalline (amorphous) regions as well
as in the crystallites.

The rate of conversion was considered to be

greater in the amorphous regions of the gel.

X-ray investigation showed

that a gradual increase in the spacing in the cellulose crystal lattice
occurred due to the substitution of the large ester groups /which force
the glucose anhydride rings apart.

Other dimensions in the lattice

did not change.
The foregoing discussion may be best summarized with the statement
of Lorand and Georgias

’’There is evidence to support the view that

cellulose reactions do not follow a single pattern, and that the type
varies, depending upon the reaction partner, its concentration, the re­
action medium, temperature, etc.

It is quite probable that all the re­

action models, worked out for micro-heterogeneous systems, such as
surface reactions, topochemical macro-heterogeneous reactions, permutoid
or quasi-homogeneous reactions, as well as the previously mentioned
micellar heterogeneous reactions, may apply to cellulose in one case or
another, depending on circumstances.”
In conclusion, some of the factors that must be kept in mind when
discussing fibrous cellulose acetates of low acetyl content, such as
those prepared in this investigation, may be listed as follows:
(1) The laboratory variables such as the moisture content of cellu­
lose, the concentration of acetylating agent and catalyst, the
time of reaction, and the temperature of reaction, must be con­
trolled.
(2) Sulfuric acid present in the acetylating mixture reacts with
cellulose to form sulfoacetates and to degrade the cellulosic
chain.

■95

(3) The acetylation of cellulose under these conditions is hetero­
geneous and will proceed faster in certain areas of the fiber.
(4) Different degrees of acetylation will be present at different
l
points of attack, depending on the accessibility of the hydroxyl
groups at these points.
(5) A large proportion of the cellulose remains unchanged during the
acetylation reaction, and there is a high probability that the
proportion of such unchanged cellulose will be less in the amor­
phous regions of the cotton fiber.
(6) Any reaction to which cellulose may be exposed will yield re­
sults that are only average values and do not truly express
the stoichiometric relationships resulting from the reaction.

-96-

PERIODATE OXIDATION OF CELLULOSE

The Mechanism of Periodate Oxidation
The work of Criegee6 has been accepted by many authorities as a
satisfactory explanation of the oxidative cleavage of 1,2-glycols by
such reagents as lead tetraacetate and periodic acid.

It is postulated

that these reagents condense with the glycol group to form a cyclic
intermediate that is unstable and decomposes by cleavage of the 2,3carbon-carbon bond in the ring.

In the case of periodic acid, the inter­

mediate decomposes as follows:
I
-C-CK
|
io4h3

-- >

2 /C=0

+

H20

+

HI03

I
n*

Heidt and Purves

have listed the requirements that must be met

by any reagent that might conceivably perform this type of oxydation,
(1) The central atom of the oxidant must have a diameter of about
2,5 to 3,0 5 which is large enough to bridge the space between
the hydroxyl groups in a 1,2-glycol,
(2) The central atom must be able to coordinate with at least two
hydroxyl groups in addition to the groups already attached to
it.
(3) The valence of the central atom must be 2 units (and not 1 or
3) higher than the valence of its next lower stable state,
(4) The oxidant should have- a standard E0 oxidation potential in
the neighborhood of about -1,7 v. with respect to the next
lower stable state.

-97-

Reagents that fulfill the preceding requirements arej
HIO4 , UaBi03, anc* hydrated unstable Ag

Xx«L
.

Pb(0C0CH3 )4 ,

The last two have been

tested and found active towards glycol cleavage.

Commonly used oxidiz­

ing reagents such as HaOCl, KgCrgOy, KMn04 , and HWO3, lack one or two of
the above requirements.
As opposed to the cyclic mechanism of Criegee, Waters

64

has present­

ed a free radical mechanism that also explains the oxidative cleavage of
1,2-glycols.

The mechanism of Waters involves an auto-oxidation reaction

that is catalyzed by the oxidizing agent, and leads to a series of chain
reactions that end with glycol cleavage.

The following mechanism was

proposed for the lead tetraacetate oxidation of glycolss

Pb(0C0CH3)4
H
R-C-OH
I
R-C-OH
I
H

2

1?
R-C-O*
|
R-0-OH
H
(a)

+

Pb(OCOCH3)2

*0COCH '

>

♦

H
R-C-O*
|
R-C-OH
t
H
(a)

?

>

R-C-OH
|
R-C-OH
H

2 *0C0CH3

+

?.

+

HOCOCH,

.

R-C-O*
I
R-0-0*
H
(b)

H
-- *- 2 R-C=0

The acetate free radicals react with the glycol group to form new free
radicals (a), which may collide to form the biradical (b).

The biradi­

cal (b) is stabilized more easily by the symmetrical fission of a C-C
bond than by further action involving a-O-H bond.

Waters postulates

that in the case of periodic acid a corresponding free radical reaction

-98-

may be started by ’’atomic hydrogen abstraction by an 1=0 bond”.

The

biradical is formed in one step:

H
/// |
-C-0:H
1:0:
/
:6!.'i:0: H
-o-o;h
|"
s'

H
-C-Q------ ►
-o-o.

A \

+■ H90
2

+ HIO,

H

This mechanism would be in agreement with the requirements of space and
configuration as outlined by Heidt and Punres

23

, but does not involve

actual condensation or chelation of the oxidizing agent in a cyclic
structure such as proposed by Criegee.

Periodate Oxidation of Cellulose
Jackson and Hudson30 (1936) were the first investigators to apply
the so-called Malaprade reaction to cellulose chemistry.

The work of

Hudson and Jackson has been extended considerably and at the present
time the periodate oxidation of cellulose is finding application as an
analytical method in certain phases of cellulose chemistry

ca Crt
* .

The

literature cited for Jackson and Hudson, Jayme3^, and Pacsu30, deals
mainly with the theoretical reaction and with the identification of oxi­
dation products, and does not furnish data that might be useful in a
study of the rate of periodate oxidation of cellulose under different
conditions.
g

Davidson

has made an extensive study of this oxidation reaction

and the properties of periodate oxycelluloses.

He found that the ideal

reaction of periodic acid with cellulose did not stop at the point where

-99-

1 anhydroglucose unit had been oxidized by 1 mole of HI04 , as shown in
the reaction;

CH-OH
c— 0

?/H
/
0 \oH
/

CHpOH
a— 0

\ /
c
h /'A H

HI04

\ /
CH

0

c— 6
H

E/S

►
/

OH

\

/

c=o c»o
<.

^

H

The actual oxidation, and especially during the later stages of
the reaction, gave rise to measurable quantities of carbon dioxide,
formic acid, and formaldehyde.

Some of these products might be expected

as a result of the normal oxidation of end groups along the cellulose
chain.

The periodate oxidation of an end groups may be written:
HC=0

(l)

HCOOH

HC-OH

(2)

HCOOH

HC-OH
I
GliO-CH

(3)
(4)

HC-OH

(5)

HC=0
I
Gl-O-C-H
I
HC=0

I

HI04

I
HC-OH
H

(6)

H2C=0

The symbol Gl is used to designate an anhydroglucose residue.

The forma­

tion of formic acid results from the oxidation of carbons Ho, 1 and 2,
and the formation of formaldehyde, from carbon No, 6,

Further oxidation

of formic acid may account for the carbon dioxide.
In a typical oxidation experiment, Davidson oxidized 1 g, of cellu­
lose with 100 ml, of a solution of 0,2 N HI04 . After about 350 hours,

the cellulose had consumed 1 mole of HIO^ per unit molecular weight,
and had produced COg, HCOOH, and HgC£Q, in the amount of:
and 0.035 moles per unit molecular weight respectively.

0.096, 0.226,
These figures

correspond to a formation of these products to the extend ofs
COg, 1 mole per 10 anhydroglucose units
HCOOH, 1 mole per 4 or 5 anhydroglucose units, and
HgC=0, 1 mole per 33 anhydroglucose units.
It is obvious from these figures that these products did not arise
solely from the end groups, but must have been formed as a result of
side reactions.

This particular experiment represents an extreme in

side reactions.

If periodate oxidations are carried out at pH values

of between 2 and 5, and if the concentration of the oxidant is reduced
to about .05 N, the production of COg, HCOOH, and HgC-0 is decreased
considerably.
Harris

53

and Purves

20

have studied periodate oxidation of cellulose

and have determined the amounts of dialdehyde present in samples that
were oxidized for various time periods.

Purves found that a properly

prepared oxycellulose contained at least 90% of the dialdehyde (as deter­
mined by the ainitrophenylhydrazone method) that would be expected from
the periodate consumption.

Purves further considers that the reaction

(for starch) is only selective between the pH values of 2 and 5 and at
temperatures below 20° C.

"Oxidation of starch or cellulose with

aqueous periodate takes place in a heterogeneous system and it is possi­
ble that some of the oxidant is dissipated in secondary reactions at

-101-

the surfaces while the interiors of the granules or fibers contain un­
changed starch or cellulose.
The initial rate of periodate oxidation of cellulose is much faster
than that observed for the over-all reaction. . Mark^ and Timell®® have
shown that this initial rapid oxidation corresponds to the attack of
periodate on the amorphous portions of cellulose.

If a curve is drawn

to show the rate of oxidation of cellulose over a considerable period of
time, (see figure 9), it can be seen that in the early stages of oxida­
tion the observed rate of reaction is the net result of two reactions,
one being the fast oxidation of the amorphous, and the other, the slower
oxidation of the crystalline regions of cellulose, both of which take
place at the same time.
O
Davidson has studied the effect of periodate oxidation on the
X-ray diagram of filter paper cellulose.

As the degree of oxidation

increased the X-ray pattern of the original cellulose became more and
more diffuse.

This indicates that no new crystalline structure is pro­

duced, and that the original crystalline order is gradually destroyed as
oxidation proceeds.

The conclusion would be that the crystalline areas

are gradually opened up during the course of periodate oxidation.
Figure 7 shows the reaction rate curves for 8 periodate oxidations
of cotton cellulose.

Curves IV and VI were plotted from data obtained

in this investigation; all other curves were plotted from data obtained
from the references cited.

An oxidation period of seven hours would cover

mostly the rapid periodate oxidation of the amorphous regions of cellulose.

-102-

KIO4
pH 4.2

/KIO4
/ pH 4

VI (p «)
0.03 N
/ HICU

IV ( M 5)

0.03 N
/HIO4
pH 2

0.03

0.02

0.089 N
KIO 4

of

RIO 4 , moles

per

unit

molecular

weight

0.04

VIII (*°) VII
0.05 N
0.1 N

III ( ss)
0.021 N

Consumption

KIO 4
pH 4.6

0.01
0.01 N

HIO 4
pH 2

Time, hours

Figure 7
Periodate Oxida tio n of Cellulose Under
Various Conditions.

A study of figure 7 would lead to the following observations:
(1) The rate of oxidation increases with an increase in the con­
centration of the oxidizing agent, as would be expected*
(2) The effect of swelling of the fiber on the rate of oxidation
is indicated very clearly by the difference between curve VIII
and all others.

Curve VIII was obtained by Purves

20

from data

resulting from the oxidation of cotton linters that had been
pre-swollen, and Purves claimed that after such swelling the
internal surfaces, directly available to any aqueous solution,
contained from 10 to 20% of all the hydroxyl groups present in
the fiber.

Therefore, in any oxidation study, one must take

into account the effects of pre-swelling treatments, and also
the swelling effects resulting from the presence of certain re­
agents in the oxidizing mixture.
(3) The effect of vigorous stirring is shown by a comparison of
curve VI with curve IV.

All of the conditions were the same

in both experiments, the only difference being that the re­
action mixture was vigorously stirred in the case of curve VI.
It is clearly seen that the oxidation rate is much faster when
the reaction mixture is stirred vigorously, and this could be
considered as evidence that the availability of the glycol
groups is increased.

Vigorous stirring might also increase

the diffusion gradient of the oxidant in the fiber, which in
turn would cause a greater probability of reaction between
periodate and glycol.

-104-

(4) Apparently the rate of oxidation is not affected appreciably
by differences in pH between 2 and 5.

Factors that Influence the Reproducibility of Results and the Rate of
Oxidation of Cellulosic Materials.
If conclusions are to be drawn from any series of periodate oxida­
tions of cellulosic materials, certain experimental conditions and fact­
ors must be kept in mind:
(1) The reaction flask apparatus should be free from oxidizable
impurities or impurities that might catalyze the decomposition
of periodic acid.

After glassware has been cleaned it should

be filled or treated with dilute HI04 solution and allowed to
stand for at least 24 hours.

After oxidation experiments the

flasks should be rinsed with distilled water and dried in an
inverted position,
(2) Oxidation experiments should be carried out on samples that
have been standardized as to physical form,
(a) The state of division of the materials should be
approximately uniform,
(b) The moisture content of the materials should be
controlled so as to permit accurate weighing.
(c) Any swelling treatment prior to oxidation should
be standardized.
(3) Extremes in reaction conditions should be avoided:
(a) The concentration of the oxidant should not be much
more than 0,1 K and not less than 0.02 N.

-105-

(b) If a measure of the true rate of reaction is to be
obtained, the volume of oxidant per gram of material
should be selected so that the reaction period can
be completed without decreasing the concentration of
the periodic acid to an extent that would effect the
reaction rate.
(c) The reaction media should have a pH between 2 and 5.
A reaction mixture that is too acid yields an exces­
sive amount of by-products caused by side reactions.
A mixture that is alkaline causes degradative re­
arrangements of the periodate oxycellulose.
(d) All oxidation experiments should be performed at the
same controlled temperature.

Temperatures between

20 and 30° C. are suggested.
(e) The selection of a reaction time should be governed
by the nature of the cellulosic material and the con­
centration of the oxidant to be used.

Short reaction

periods show almost stoichiometric selective oxidation
according to the ideal reaction, whereas, prolonged
oxidation periods may involve side reactions.

The

amorphous areas of cellulose will be attacked rapidly
during the early stages of the reaction, and as the
oxidation of these areas becomes complete, the re­
action rate will be that corresponding to the oxidation
of the crystalline areas of the cellulosic material.

-106-

(f) The contents of the reaction flask should be mixed
at a moderate standard rate that permits the main­
tenance of a homogeneous suspension of the cellu­
losic material in the oxidizing solution,
(4) The method of analysis for excess periodate should be stand­
ardized, and blank determinations of the concentration of
the periodic acid should be made at least once every 24 hours
during the course of a oxidation reaction.

-107-

PERIODATE OXIDATION OF CELLULOSE ACETATES OF LOW ACETYL CONTENT

The Rate of Oxidation of Cellulose and Cellulose Acetates.
Figures 5 and 6 show the reaction rate curves for a series of cellu­
lose acetate oxidations as plotted from data recorded in table X.

All

of the oxidation data resulted from experiments where the possible factors
that might influence the rate of oxidation were kept standard.

The con­

sumption of periodate, in moles per unit molecular weight, listed in
table X is the average consumption for six experiments in the case of
standard cellulose, and the average of at least two experiments in which
each cellulose acetate was oxidized.
The rate of the oxidation reaction has been shown by plotting perio­
date consumption against time.

The progress of the reaction may also be

shown by plotting the periodate consumption against the amount of free
hydroxyl present in the cellulose acetates.

The amount of oxidation of

any cellulose derivative will be a function of the total number of free
hydroxyl groups in that particular derivative.

The percent of free

hydroxyl in each cellulose acetate may be calculated from the equation:

Percent of free hydroxyl K (S - D.S.) 100
3
where D.S. is the degree of substitution (table II), and 3 is the maxi­
mum degree of substitution for an anhydroglucose unit.

The conversion

of D.S, to percent free hydroxyl for cellulose acetates No. 17 to 25 is
recorded in table XIII.

-108-

TABLE XIII

CONVERSION OF DEGREE OF SUBSTITUTION TO PERCENT FREE HYDROXYL

CAc
No.

17
16
19
20
21
22
23
24
25

Percent
Combined
HOAc
5.13
8.23
12.09
14.14
3.40
5.31
6.60
6.65
9.94

Degree of
Substitution

Percent Free
Hydroxyl

0.1436
0.2360
0.3560
0.4235
0.0940
0.1490
0.1668
0.2490
0.2880

95.21
92.13
88.18
85.87
96.87
95.03
93.77
91.70
90.40

-109-

Figure 8 is a graph of the consumption of periodate plotted against
the percent free hydroxyl for various cellulose acetates of low acetyl
content.

The values for cellulose are recorded at 100?£ free hydroxyl.

The reaction rate curve for cellulose is shown in figure 9.

This

curve may be analyzed in terms of the oxidation of amorphous and crys­
talline regions of cellulose19*60.

If the straight-line portion of the

curve is extrapolated to zero time and displaced downward to the origin
(line C) this straight line may be considered to represent the rate of
oxidation of crystalline cellulose.

If the differences between the act­

ual observed curve and this line for any series of time values are
plotted on this same coordinated system, the result will be curve A,
which represents the oxidation of amorphous cellulose.

Curve A showB that

the oxidation of amorphous cellulose is for all practical purposes com­
plete after a 24— hour oxidation period under the oxidation conditions
used.
The basic problem that must be solved at this point may be suggest­
ed by the question:

How many hours would be required to complete the

periodate oxidation of cellulose (the oxidation of all glycol groups in
cellulose, i.e., one glycol group per unit mol. wgt.)?

A few assumptions

must be made:
i
(1) That the ideal reaction holds true during the 60 hour period
under these very mild conditions of oxidation.
(2) That the degree of periodate consumption at 24 hours (0.1077
moles per unit mol. wgt.) represents the end of the oxidation
of amorphous cellulose.

-110-

0„l5

0.10

Consumption

of HIO.,

moles

per

unit

molecular

weight

0 o20

0.05
Oxidation Period
o
+
^
•
a

60
48
36
24
12

hours
hours
hours
hours
hours

0

85

90
95
Percent free hydroxyl
Figure 8

Periodate Oxidation of Cellulose and Cellulose Acetates
at 30°C., with Standard Mixing.
- I ! i-

100

3

o.i5

r-i

4-3
•H

(U

CU

o

0.10

s

o
M

<W

o
a
o

•H
-P
P.

e
p

03

c
o
O

o,o5

Rate of Oxida tio n of amorphous
Rate of oxidation of crystalline,

and

Observed rate of oxidation of cellulose

24
Time, hours

48

Figure 9
Oxidat ion of Amorphous and Crystalline
Cellulose
-

112-

(3) That the remainder of the reaction is governed by the rate
of oxidation dM (0.0275 moles per unit mol. wgt. per hour)
dt
calculated from the slope of the line C in figure 9, where
M represents the consumption of periodate in moles per unit
molecular weight.
The consumption of periodate at the end of the theoretical reaction
is 1 mole per unit mol. wgt.

The consumption at 24 hours is 0.1077, so

that the balance (or 0.8923) must be oxidized at the rate of 0.0275 mole
per unit mol. wgt. per hour.
hours.

This corresponds to a time period of 325

The time period for the total reaction would then be 325 + 24 or

roughly 350 hours.
The same procedure could be followed to determine the rate of oxida­
tion of each cellulose acetate, but since the total number of glycol
groups present in the acetates will be decreased by acetylation, it
would be difficult to arrive at the correct time period during which the
theoretical reaction is complete.

The interest lies mainly in the

difference (AM) between the periodate consumption of cellulose and that
of any cellulose acetate.
greater and greater.

As oxidation proceeds this difference becomes

Cellulose acetate samples Wo. 21, 23, 24, and 20

were chosen as representative of the series of cellulose acotates and
the data for these samples will be used in the remainder of this discus­
sion.

The difference, A M , between the consumption of periodate by

cellulose and cellulose acetate at the time intervals of 12, 24, 36, 48
and 60 hours are recorded in table XIV.

A few of these figures were

corrected slightly to correspond with figure 8.

-113-

Figure 10 is a graph of

weight
molecular
unit
per
moles
consumption,
periodate
in

Cellulose Acetate No. 20
Cellulose Acetate No. 24C ellulose Acetate No. 23

AM,

Difference

dt

0.01

Cellulose Acetate No. 21

24
Time,

48
hours

Figure 10
The Change of A M

wi th Respect to Time

-114-

the difference, A m , in periodate consumption per unit mol. wgt. plotted
against time.

For every acetate sample the points plotted can be

joined by a straight line, even down to 12 hours.

This would indicate

that the value A M changes at the same rate, d(AM) , and if it is assumdt
ed that this rate holds true during the theoretical reaction period
(350 hours), the total difference between the periodate consumption of
cellulose and any cellulose acetate may be calculated.

The difference

A M at 24 hours may be added to the difference A M over a period of
32 6 hours to obtain the total differences
Total difference,

A M KKn

=

AMr,A + (326) d( AM)
dt

These figures are recorded in table XIV.
Allowing a margin of error of * 24 hours in the calculation of the
period of time required to complete the theoretical reaction, this would
correspond to a difference of t 6f0 in the value

AMggQ.

The Course of the Acetylation Reaction.
In the preceding discussion certain fundamental assumptions were
made that permitted the calculation of the difference between the perio­
date consumption of cellulose and any cellulose acetate at the end of
the theoretical reaction.

Partial justification for making these assump­

tions may be granted from the standpoint that all of the experiments were
carried out under the same controlled conditions, and that oxidations of
all cellulose acetates were compared at every reaction period with the
corresponding oxidation of the standard cellulose from which they were
prepared.

It is considered that the increase in end groups (that have 3

-115-

TABLE XIV

CALCULATION OF AMg50

Reaction
Time,
hrs.

AM
moles per
unit
mol. wgt.

d( A M )
dt
(moles per
unit
mol. wgt.
per hour)

^350
moles per
unit
mol. wgt.

CAc No. 21
3.4# HOAc

12
24
36
48
60

0.0073
0.0096
0.0113
0.0140
0.0163

0.000192

0.0722

CAc No. 23
6.6% HOAc

12
24
36
48
60

0.0133
0.0160
0.0205
0.0238
0.0271

0.0003

0.1138

CAc No. 24
8.65% HOAc

12
24
36
48
60

0.0165
0.0210
0.02 65
0.0305
0.0350

0.000388

0.1475

CAc No. 20
14.14# HOAc

12
24
36
48
60

0.0229
0.0288
0.0340
0.0379
0.0452

0.000458

0.1783

Sample
Number

adjacent hydroxyl groups), caused by degradation during the acetylation
reaction, is offset by a small amount of combined sulfuric acid that
■mill block some of the hydroxyl groups which might otherwise be oxidized
(see page 84).
The value

is the difference between the consumption of perio­

date by cellulose and a cellulose acetate at the end of the theoretical
reaction.

This value corresponds to the amount of glycol groups that

were esterified by acetic anhydride when the cellulose acetate was pre­
pared.

When cellulose is acetylated the reaction may take place with

the hydroxyl groups on carbons No. 2,3, and 6.

If either the No. 2 or

3 hydroxyl group is acetylated, the glycol group will be blocked and
would not be oxidized by periodic acid.

However, if the No. 6 hydroxyl

is acetylated the glycol group is free (not blocked) and can be oxidized
i

by periodic acid.

The values for AMggQ as shown in table XV are the

observed (experimental) values for the amount of glycol that must have
been blocked by acetylation.
Table XV contains some of the calculated data for cellulose acetates
No. 21, 23, 24 and 20 which were chosen as representative of the series
of cellulose acetates prepared.

Column B shows the average degree of

substitution of the acetyl groups in each cellulose acetate, and this
value may also be thought of as the moles of hydroxyl groups that are
blocked by acetyl groups.

Columns D, E, F and G represent hypothetical

distributions of this total amount of blocked hydroxyl among the three
hydroxyl groups of an anhydroglucose unit.

Both columns D and E repre­

sent the distribution of acetyl groups between carbons 2 or 3.

-117-

TABLE XV
DISTRIBUTION OF SUBSTITUENTS IN CELLULOSE ACETATE*

CAc
No.

21

23

24

20

Percent
Combined
HOAc

Total -OH
Acetylated

A

B

3.4

0.094

6.6

8.65

14.14

0.1868

0.249

0.4235

Blocked
Glycol
Found

C
0.0722

0.1138

0.1475

0.1783

Distribution of Acetylated hydroxyl groups
-OH No.
2 or 3

-OH No.
2 or 3

-OH No.
6

D

E

F

0.0722

0.0218

0.000 min.

0.0722

0.0000

0.0218 max.

0.1138

0.0730

0.0000 min.

0.1138

0.0000

0.0730 max.

0.1475

0.1015

0.0000 min.

0.1475

0.0000

0.1015 max.

0.1783

0.1783

0.0669 min.

0.1783

0.0000

0.2452 max.

* The units of the figures in columns B through G are expressed in
moles per unit molecular weight.

If Product
is a
triacetate
G
0.031

0.0623

0.083

0.141

The purpose of this investigation was to determine if possible
where the initial acetylation of cellulose takes place; whether it is
at the primary hydroxyl group (carbon No. 6), or at one of the second­
ary hydroxyl groups (carbon No. 2 or 3).

It is felt that the figures

in table XV can be used to answer this question.

For example, cellulose

acetate No. 21 (3.4% HOAc) has an average degree of substitution of
0.094 moles per unit mol. wgt.

This is the number of moles of hydroxyl

per anhydroglucose unit that have been acetylated.

Periodate oxidation

of CAc No. 21 showed that 0.0722 moles of glycol were blocked.

The

hydroxyl groups (0.094 moles per unit mol. wgt.) that are acetylated in
this particular cellulose acetate may be distributed according to the
following two extremes:
(1)

0.0722 moles of acetylated hydroxyl on carbon 2,
0.0218 on carbon 3, and
0.0000 on carbon 6.

(2)

0.0722 moles of acetylated hydroxyl on carbon 2,
0.0000 on carbon 3, and
0.0218 on carbon 6.

The figures for these two extremes are shown in table XV.

The first

extreme would leave a minimum amount of acetyl on carbon 6, and the sec­
ond extreme would leave the maximum.
From the data in table XV the following conclusions may be drawn
regarding the course of the acetylation reaction:
(1) The observed amount of esterification on the 2 or 3 position
of the glycol rules out the probability of the formation of
anhydroglucose triacetate (as postulated by Kanamaru®^) in
any phase of the initial reaction.

-119-

For example, if this were

the case, the distribution of acetyl groups would be l/3 on
each hydroxyl (column G table XV) and the amount of blocked
glycol that should be observed would be approximately 40 to
75% of what was actually observed for samples containing
from 3.4?? to 14,14/? combined acetic acid,
(2) It appears from results of this investigation that at the
beginning of the acetylation reaction the secondary hydroxyls
are more vulnerable to attack by acetic anhydride esterification than the primary.

It is clearly evident from the figures

shown in table XV that it might be possible to acetylate cotton
to the extent of 5% combined acetic acid or even as much as
9?? HOAc, and have no acetylation take place on hydroxyl No, 6,
However, if cotton is acetylated to a greater extent (for ex­
ample 14.14?? HOAc) some of the No, 6 hydroxyls must be acetylat8d.

The figures in table X? do not prove that no acetyla­

tion takes place at the No. 6 hydroxyl during the early stages
of the reaction, but they do show that this is a possibility.
If the other extreme (maximum acetylation of No. 6 hydroxyl)
is considered, it is found that when cotton is acetylated to
the extent of 3?? HOAc, the maximum amount of acetylation that
could take place at the No. 6 hydroxyl is about 0.02 moles
per unit mol, wgt.

This amounts to about 23?? of the total

moles of acetylated hydroxyl.

If cotton is acetylated to the

extent of 14?? HOAc, the maximum amount of No. 6 hydroxyl that
could be acetylated is about 0.25 moles per unit mol. wgt.

-120-

■which is about 60$ of the total.

The increase in the maxi­

mum probability of acetylation at the Ho. 6 hydroxyl is to
be expected.

During the early stages of acetylation the

secondary hydroxyl groups are attacked to a greater extent
then the primary and as acetylation proceeds, the number of
secondary hydroxyl groups decreases, and it would be expected
that more acetylation would take place at the Ho. 6 hydroxyl.
Sonnerskog®® (1948) has studied the etherification of
cellulose by alkyl halides.

His observations also lead to

the conclusion that the secondary hydroxyl groups of cellu­
lose are attacked first.
(3) As a corollary to the above conclusion (2), it can be said
that in the early stages of acetylation the primary hydroxyl
groups of cellulose are attacked to a lesser extent than the
secondary.

The reason for this may be that the primary

hydroxyls are either less reactive or less available for re­
action.

The availability of the primary hydroxyl groups of

cellulose may be small due to hydrogen bonding which is
assumed to occur between polymer chains in the cellulose
micelle®®.

This would be true in cellulose, but when cellu­

lose is acetylated the introduction of acetyl groups forces
the cellulose chains apart.

This would break many hydrogen

bonds and increase the availability of primary hydroxyl
groups.

X-ray measurements confirm this hypothesis®®.

-121-

It is well known that in general a primary alcohol is
more reactive than a secondary.

The apparent reversal of

this rale in the acetylation of cellulose can be explained
as resulting, not from a decrease in the reactivity of the
primary hydroxyl, but from the fact that the primary hydroxyl
is less available at the beginning of the reaction, due to
hydrogen bonding.

The hydrogen bonding is slowly eliminated

as the polymer chains are spread apart.

-122-

LITERATURE CITED

1.

Adams, Roger, "Organic Reactions", John Wiley & Sons Inc.,
New York, Yol II, 1944, p. 341-375.

2.

Badgley, W., Frilette, Y. J., and Mark, H., Ind. Eng. Cham.,
37, 227-31 (1945).

3.

Bailey, I. W. , Ind. Eng. Chem., 30, 40-7 (1938).

4.

Cramer, F. B., and Purves, C. B., J. Am. Chem. Soc., 61,
3458-62 (1939).

5. Cramer, F. B., Hockett, R. C., and Purves, C. B., J. Am. Chem.
Soc., 61, 3463-4 (1939).
6. Criegee,

R.,Kraft, L., and Rank, B., Ann., 507, 159 (1933).

7. Cross, C. F. and Bevan, E. J., "Researches on Cellulose",
Longmans, Green and Co., London, 2nd Ed. 1901, Yol. I,
p. 40.
8. Davidson, G. F., J. Textile Inst., 29, T 195-218(1938);
31, T81-96 (1940); 3£, T 109-131 (1941).
9. Duke, F.

R.,J. Am. Chem. Soc., 69, 3054-5 (1947).

10. Elo'd, E. and Schmidt-Bielenberg, H., Z. physik. Chem., B29,
27-51 (1934).
11.

Fleury,

P., and Boisson, R., Compt. rend., 208, 1509-12 (1939).

12. Fleury, P., and Boisson, R., J. pharm. Chim., 30, 145-62 (1939);
30, 307-16 (1939).
13. Fleury,

P., and Curtois, J., Compt. rend., 209, 219-21 (1939).

14. Fleury,

P., and Lange, J., Compt. rend., 195, 1395-7 (1932).

15. Fleury, P., and Lange, J., J. pharm. Chim., 17, 107-13 (1933);
17, 196-208 (1933).

16.

Franchimont, M., Compt. rend.,
(1881).

89, 711-13 (1879); 92, io54-6

17. Gardner, T. S., and Purves, C. B., J. Am. Chem. Soc., 64,
1539-42 (1942).

-123-

18.

Genung, L. B. and Mallatt, R. C., Ind. Eng. Chem., Anal. Ed.,
13, 369-72 (1941).

19.

Goldfinger, G., Mark, H., and Siggia, S., Ind. Eng. Chem., 35,
1083-6 (1943).

20.

Grangaard, D. H., Gladding, E. K., and Purves, C. B., Paper
Trade J., 115, (7) 41-8 (1942).

21

.

Hartsuch, B. E., unpublished results.

22

.

Head, F. S. H., J. Textile Inst., 38, T 389-407 (1947).

23.

Heidt, L. J., Gladding, E. K., and Purves, C. B., Paper Trade
J., 121, (9) 35-43 (1945).

24.

Herzog, R. 0., and Londberg, G., Ber., £7, 329-32 (1924).
(See also, Herzog, R. 0., J. Phys. Chem., 30, 457-69
(1936)i)

25.

Hess, K., and Ljubitsch, N., Ber., 61, 1460-2 (1928).

26.

Hess, K., and Trogus, C., Z. physik. Chem., B5, 161-76 (1929)j
B7, 1-24 (1930); B9, 160-72 (1930); B15, 157-222 (1931).

27.

Heuser, Emil, ’’The Chemistiy of Cellulose", John Wiley & Sons,
Inc., Hew York, 1944, 660 pp.

28.

Heuser, E., and Schlosser, P., Ber., 56, 392-5 (1923).

29.

Howlett, F., and Martin, E., J. Textile Inst., 35, T 1-6 (1944).

30.

Jackson, E. L., and Hudson, C. S., J. Am. Chem. Soc., 59,
2049-50 (193 7); 60, 989-91 (1938).

31.

Jayme, G., and Maris, S., Ber., B77, 383-92 (1944).

32.

Kanamaru, K., Helv. Chim. Acta, 17, 1429-40 (1934).

33.

Ketoid Co., Brit.

34.

Knoevenagel, E., Z. angew. Chem., 2 7, 505-9 (1914).

35.

Kraemer, E. 0., and Lansing, W. 0., J. Phys. Chem., 39, 153-67
(1935).

36.

Kruger, D., and Tschirch, E., Ber., 64, 1874-8 (1931).

37.

Lorand, E. J., and Georgi, E. A., J. Am. Chem. Soc., 59, 116670 (193 7).

237, 591, July 22, 1924.

-124-

38.

Mahoney, J. P., and Purves, C. B., J. Am. Chem. Soc., 64, 9-15
(1942); 64, 15-19 (1942).

39.

Malaprade, M. L., 3ull. soc. chim. France, (4) 43, 683-96 (1928).

40.

Malaprade, M. L., Compt. rend., 186, 382-4 (1928).

41.

Malm, C. J., and Clarke, H. T., J. Am. Chem. Soc., 51, 2 74-78
(1929).

42.

Malm, C. J., Tanghe, L. J., and Laird, B. C., J. Am. Chem. Soc.,
70, 2740-7 (1948).

43.

Middleton, E. B., (to E. I. Du Pont de Nemours & Co.).
1,685,220, Sept. 25, 1925.

44.

Miles, G. W.

45.

Muller, S. and Friedberger, 0., Ber., 3_5, 2652-9 (1902).

46.

Nightingale, D. A., U.

47.

Ost, H., Z.angew. Chem., 32, 66-70 (1919).

48.

Ostrnld, ¥. and Ortloff, H., Kolloid-Z., 59, 25-32 (1932).

49.

Pacsu, E., J. Polymer Sci., 2_, 565-82 (1947).

50.

Pacsu, E., Textile Research J., 15, 354-61 (1945); 16, 243-8
(1946); 17, 405-18 (1947).

51.

RedfaEp.,C. A., and Boyle, M. C. J., Brit. Plastics, 20, 63-4
(1948).

52.

Reeves, A. E., Ind. Eng. Chem.,

53.

Rutheford, H. A., Minor, F. W., Martin, A. R., and Harris, M.,
J. Research Natl. Bur. Standards, 2_9, 131-41 (1942).

54.

Sakurada, I., and Kitabatake, T., J. Soc. Chem. Ind. Japan, 37,
suppl. bind. 604-5 (1934). (C.A.) 29, 1243* (1935).)

55.

Schutzenberger, M. P., Compt. rend., 61, 485-6 (1865).

56.

Sonnerskog, S., Svensk Papperstidn., 51, 50-1 (1948).

57.

Spurlin, H. M., J. Am. Chem. Soc., 61, 2222-7 (1939).

58.

Staudinger, Hermann, "Die Hochmolekularen Organischen verbindungen Kautschuk und Cellulose", Julius Springer, Berlin,
1932, p. 451.

TJ. S.

TJ. S. 838,350, 1904.

S. 1,604,471, Oct. 2 6, 1924.

35, 1281 (1943).

-125-

59.

Staudinger, H., and Hauer, W., Bar., 63, 222-34 (1930).

60.

Timell, T., Svensk Papperstidn., 52_, 61-3 (1949); 52, 107-12
(1949).

61.

Tinsley, J. .S., J. Chem. Ed., 25, 94-6, 107 (1948).

62.

Unruh, C. C., and Kerryon, W. 0., Textile Research J., 16, 1-12
(1946).

63.

Vermaas, 0., and Hermans, P. H., J. Polymer Sci., 2, 397-406
(1947); 2, 406-11 (1947).

64.

Waters, W. A., Trans. Faraday Soc., 42_, 184-90 (1946).

65.

Willard, H. H., and Furman, H. H., "Elementaiy Quantitative Analy­
sis”, D, Van Hostrand Co., Inc., Hew York, 3rd Ed. 1940, p.
141, 221, 273, 277.

66. Wilson, R. E., Ind. Eng. Chem., 13, 326-31 (1921).
67.

Wohl, A., Z. angew. Chem., 16,285 (1903).

-126-