Method of making soluble squaraine dyes

The present invention provides a novel process for the production of organic solvent soluble squaraine dyes. More specifically, the invention describes how a difficult to prepare tetrahydroxy squaraine intermediate can be prepared in an organic solvent system in the presence of water. This intermediate can then be esterified in pyridine to form the soluble squaraine dye which can then be easily isolated from the reaction mixture. The invention also provides the dyes prepared according to this method.

FIELD OF THE INVENTION 
The present invention provides a novel method for the production of organic 
solvent soluble squaraine dyes. More specifically, the invention describes 
how a difficult to prepare tetrahydroxy squaraine intermediate can be 
prepared in an organic solvent system in the presence of water. This 
intermediate can then be esterified in pyridine to form the soluble 
squaraine dye which can then be easily isolated from the reaction mixture. 
Soluble squaraine dyes are important as antihalation and acutance dyes in 
photothermographic products and other applications where infrared 
absorbing materials are needed. The invention also provides the dyes 
prepared according to this method. 
BACKGROUND OF THE INVENTION 
Squaraine dyes are known to possess photoconductive and semiconductive 
properties. These features have made them very attractive for various 
industrial applications such as xerographic photoreceptors, organic solar 
cells, optical recording media, antihalation dyes and acutance dyes. 
The general structure of squaraine dyes is shown in dye 1. In this 
##STR1## 
structure, R is generally N or O while R.sub.1, R.sub.2, R.sub.3, and 
R.sub.4 can be H, organic substituents or together form another aromatic 
ring. 
The synthesis of squaraines (dye 1) wherein R.sub.1 and R.sub.2 together 
form a second phenyl ring has been reported. Bello describes squaraine 
synthesis in n-butanol and toluene with azeotropic removal of water (K. A. 
Bello, S. N. Corns, and J. Griffiths, J. Chem. Soc., Chem. Commun., 1993, 
452-454). U.S. Pat. Nos. 5,380,635 and 5,360,694 describe the synthesis of 
squaraine dyes in the same manner. None of these references attempts to 
describe optimal conditions for preparation, nor do they comment on 
preferred synthetic procedures. 
Other synthetic procedures for squaraine dyes have been reported. These 
methods describe the preparation of squaraines (dye 1 ) wherein R.sub.1, 
R.sub.2, R.sub.3, and R.sub.4 are H or simple organic substituents and do 
not form a second aromatic ring. These dyes were first reported by H. 
Sprenger and W. Ziegenbein (Angew. Chem. Internat. Ed. Engl., 5, 894 
(1966)). Their procedure consists of heating in benzene and n-butanol, 
with azeotropic removal of water. 
K. Law, F. C. Bailey, and L. J. Bluett (Can. J. Chem., 64, 1607-1619 
(1986)) describe the synthesis of this dye 1 (R=dialkylamino, R.sub.1 =H 
or a ring to R, R.sub.2 =H, methyl, F, ethyl, or methoxy, R.sub.3 =H, 
R.sub.4 =H) in either toluene or benzene with butanol, with azeotropic 
removal of water. They note the increase in solubility of dyes with longer 
alkyl chains and the decrease in the isolated yields of these dyes which 
"might be attributable to secondary reactions of squaraines with 
N,N-dialkylanilines in the reaction mixture". They also noted that "in 
controlled experiments that squaraines react with N,N-dialkylanilines to 
form colorless products", which they do not identify. They do not suggest 
any cures for these synthetic difficulties. Their yields of the soluble 
dyes were less than 9%. Column chromatography was required to purify these 
dyes. On the other hand, dyes with shorter alkyl chains precipitated 
directly from the reaction mixture and after simple filtration and solvent 
washing were said to be analytically pure. Yields for these less soluble 
dyes ranged from 9.5 to 60%. 
K. Law and F. C. Bailey looked further into the synthetic procedure (Can. 
J. Chem., 64, 2267-2273 (1986)). They contrasted two synthetic procedures, 
one they referred to as the "acid route" and the other the "ester route." 
The acid route is the traditional method and involves heating squaric acid 
and N,N-dialkylaniline in azeotropic solvent, including an alcohol. The 
ester route involves heating a diester of squaric acid and an 
N,N-dialkylaniline in an alcoholic solvent, and requires additional water. 
Heating di-n-butyl squarate and N,N-dimethylaniline in freshly dried 
n-butanol gave no dye. Incremental addition of water in the presence of an 
acid (sulfuric, oxalic, trichloroacetic, or toluenesulfonic) resulted in 
increased yields of dye. The highest yields were obtained in 
water-saturated n-butanol. Increasing the concentration of the acid (with 
water present) resulted in first an increase, and then a decrease in the 
dye yield. They suggested these results indicate that the reactive 
intermediate in the reaction is the half ester of squaric acid, 2. Too 
much acid protonates some of the N,N-dialkylaniline, reducing its 
reactivity. 
##STR2## 
Law and Bailey also found that in the "acid route", no squaraine dye is 
formed if a non-hydroxylic solvent, or a secondary or tertiary alcohol is 
used as solvent. This is ascribed to the slower rate with which such 
alcohols can esterify squaric acid. They also noted that the necessity of 
having water in the reacting solvent in the ester route is in contrast to 
the acid route where water is removed continuously by an azeotropic 
solvent during the course of the reaction. 
Law and Bailey also examined the effect of the alcohol in the "ester 
route." Short chain alcohols were found to give higher yields than longer 
chain alcohols: dimethyl squarate gave 52%, di n-propyl-47%, di 
n-butyl-45%, and di n-heptyl-27%. This they ascribe to an increased steric 
effect retarding the initial hydrolysis to 2. They also demonstrated that 
the ideal amount of N,N-dimethylaniline to be used is the expected 2:1 
molar ratio to squarate. 
Law and Bailey examined the role of water in the "ester route" by closely 
monitoring the boiling point of the water/saturated n-butanol reaction. 
They found that the initial boiling point (96.degree. C.) slowly increased 
over 8 hours to 118.degree. C. as the water/n-butanol azeotrope lost water 
(due to both hydrolysis of the ester and azeotropic removal from the 
reactor) and the medium became dry n-butanol. This removal of water from 
the system drives the reaction to product. 
Law and Bailey further investigated the rate of addition of the 
N,N-dialkylaniline on the reaction. They added the N,N-dialkylaniline very 
slowly (over 6 to 8 hours) to the reaction mixture. They proposed that 
this suppresses side reactions and encourages the aniline to react with 2 
(which is slowly formed from the dialkyl squarate). They said that the 
slow addition is especially important with highly reactive anilines (such 
as N,N-dimethyl-3-hydroxyaniline). Yields decreased by 30 to 50% when the 
aniline was added in a single batch at the beginning of the reaction. 
In J. Imaging Sci., 31, 172-177 (1987), K. Law and F. C. Bailey found that 
the squaraine dyes prepared by their "ester route" contained fewer 
impurities than the same dyes made by the "acid route." This resulted in 
better xerographic properties for the "ester route" samples. 
Further work by K. Law and F. C. Bailey (Dyes and Pigments, 9, 85-107 
(1988)), examined the synthesis of N-benzyl substituted squaraine dyes. In 
this case, they compared the "acid route" at 70 torr in either n-butanol 
and toluene, or in n-heptanol. Higher yields were found using n-heptanol, 
but at the expense of lowered purity. Impurities of structure 3 were found 
in the n-heptanol reactions. Also, some dyes could only be prepared in 
n-heptanol, no yield was obtained in butanol. 
##STR3## 
Symmetrical and unsymmetrical squaraine dyes have also been produced by an 
alternative route (See K. Law and F. C. Bailey, J. Chem. Soc., Chem. 
Commun., 1990, 863-864; K. Law and F. Court Bailey, J. Chem. Soc., Chem. 
Commun., 1991, 1156-1158; K. Law and F. C. Bailey, J. Org. Chem., 57, 
3278-3286 (1992)) and are summarized in the reaction scheme shown below. 
Here the intermediate aryl hydroxy cyclobutenedione 4 is prepared by a 
ketene-olefin cycloaddition. The dye is then prepared in a separate step. 
This synthetic scheme is covered in U.S. Pat. Nos. 4,886,722; 4,922,018; 
and 5,030,537. 
##STR4## 
U.S. Pat. No. 4,524,219 (1985) (K. Law) is an example of the ester route 
and covers the reaction of a dialkylsquarate with an aniline in an alcohol 
with an acid catalyst. Water is not specifically mentioned in this patent, 
although the alcohol is referred to as "dry". 
U.S. Pat. No. 4,525,592 (1985) (K. Law and F. C. Bailey) covers the same 
ester route as U.S. Pat. No. 4,524,219, but this time the examples 
indicate that water was added to the solvents. 
U.S. Pat. No. 4,524,220 (1985) (K. Law) covers the reaction of squaric acid 
in n-butanol and benzene with an aniline, but with an added aliphatic 
amine. The resulting dyes are said to have improved photoconductive 
properties. The role of the added amine is not speculated upon. 
U.S. Pat. No. 4,523,035 (1985) (J. F. Yanus) describes the use of a higher 
alcohol (such as heptanol) at reduced pressure with or without an acid 
catalyst to prepare squaraine dyes. The advantages stated are that the 
water separates more readily from heptanol than from butanol, that the 
reaction can be more readily scaled up, that competitive reactions are 
reduced, and that diester formation is reduced. This patent states that 
the butanol reactions cannot be scaled up beyond a batch size of 0.5 mole 
whereas the higher alcohol reactions are scaleable. 
In summary, soluble squaraine dyes are known to be quite unstable in normal 
reaction mixtures leading to extensive decomposition during the synthesis 
of the squaraine system, as indicated by K. Law, F. C. Bailey, and L. J. 
Bluett (Can. J. Chem., 64, 1607-1619 (1986)). The squaric ester route 
described above by K. Law and F. C. Bailey (Can. J. Chem., 64, 2267-2273 
(1986)), required lower alcohols, like propanol, for high yield and the 
exact balance of water in the reaction was critical. This type of process 
would be very difficult to scale up. It should be noted that there is no 
indication in the related art regarding the beneficial effects of 
additional water in the "acid route". Typically, the preparation of 
soluble dyes requires extensive purification of the final product by 
solvent extraction, recrystallization, and/or chromatography. These steps 
are time consuming, expensive and can generate hazardous waste. 
A need exists for a simple cost effective method for the production of 
soluble squaraine dyes. Dyes of this type when prepared by known methods 
are difficult to scale up and isolate in good yield and purity. 
SUMMARY OF THE INVENTION 
The present invention represents a simple cost effective method for the 
production of soluble squaraine dyes. In the method of the present 
invention, we prepare a relatively insoluble intermediate squaraine dye 
and convert it to an organic solvent soluble dye by a very mild 
esterification process. The method of the present invention can be carried 
out in standard chemical processing equipment. The process time is 
relatively short, and the dye is obtained in good yield. The dye is 
obtained directly from the reaction mixture in pure enough form for use in 
most imaging constructions. 
The method of the present invention can be illustrated by the following 
reaction scheme: 
##STR5## 
wherein R' is --(CH.sub.2).sub.n H wherein n=1 to 7. 
The preparation of Intermediate 2 is done using a mixed solvent system. We 
have discovered that the use of a mixed solvent system described below is 
required to obtain the highest yields and purity of the tetrahydroxy 
Intermediate 2. This solvent mixture seems to provide optimal solubility 
for the reactants while allowing the product to precipitate before 
decomposition can occur. It also provides an optimal rate for the 
azeotropic removal of water during the reaction. The solvent system is 
preferably an octanol/cyclohexane mixture. 
We have also discovered that a small amount of water is critical to start 
the reaction for the preparation of Intermediate 2. The addition of a 
small amount of water, or even the use of slightly wet solvents insures 
the start of the reaction. This is very surprising because one of the keys 
to obtaining high purity of this intermediate is the azeotropic removal of 
water during the reaction. It is important to have the water present at 
the very start since addition after heating will not initiate the 
reaction. 
The Intermediate 2 dye is isolated by simply collecting it on a filter and 
washing it with ethanol to remove all of the octanol. Intermediate 2 can 
then be washed with ethyl acetate to remove the ethanol. There is then no 
need to dry the material. It is used directly in the esterification step. 
The squaraine dye is made soluble in conventional organic coating solvents 
(methyl ethyl ketone, or acetone for example) by the incorporation of 
multiple long alkyl chains. The process of the present invention 
incorporates solubilizing alkyl groups in the final step using very mild 
low temperature esterification conditions and a very efficient isolation 
procedure. 
The esterification of Intermediate 2 with an aliphatic acid chloride 
comprising about 2 to about 8 carbons is conveniently carried out at 
fairly high yields using pyridine as a solvent and base. It was 
stirprising to find that, while the squaraine dyes are very susceptible to 
attack by nitrogen bases such as triethyl amine which is commonly used in 
these types of esterifications, they are completely stable in pyridine at 
ambient temperatures or below. While the reaction can be done at room 
temperature (about 20.degree. to 30.degree. C.) in this system, we 
obtained higher purlties and higher yields at lower temperatures (below 
about 10.degree. C.). 
We also discovered an extremely effective precipitation procedure to 
isolate pure dye directly from the reaction mixture so no further 
purification is needed even for use in imaging constructions. We 
discovered that by adding ethyl acetate followed by the addition of water 
and enough hydrochloric acid to convert all of the pyridine to its water 
soluble hydrochloride salt, the squaraine dye precipitated in extremely 
pure form. Preferably the mixture is warmed to about 20.degree.-30.degree. 
C. The dye is then collected by filtration followed by washing with 
methanol, and air drying. 
The present invention thus provides a novel method of making squaraine 
dyes. The invention provides a method of making a compound comprising the 
steps of: 
(a) forming a first mixture comprising: 
(I) a compound of the structure 
##STR6## 
(II) a compound of the structure 
##STR7## 
wherein the molar ratio of the compound of (a)(I) to the compound of 
(a)(II) is 0.5:1 or greater; and 
(III) about 50 to about 90 percent by weight of a solvent selected from the 
group consisting of ethanol, n-propanol, isopropanol, and mixtures 
thereof, based upon the total weight of the first mixture; 
wherein the first mixture is free of acid catalyst; 
(b) heating the first mixture to allow the first mixture to react in order 
to form a first intermediate of the formula 
##STR8## 
wherein the first mixture is agitated during step (b); 
(c) cooling the mixture of step (b) to a temperature below about 30.degree. 
C. followed by isolating the first intermediate by filtration from the 
mixture of step (b); 
(d) washing the first intermediate with a solvent selected from the group 
consisting of ethanol, propanol, isopropanol, and mixtures thereof; 
(e) forming a second mixture, wherein the second mixture comprises: 
(I) the first intermediate; 
(II) squaric acid; 
wherein the molar ratio of the first intermediate to squaric acid is about 
2:1 to about 1.7:1; 
(III) a solvent selected from the group consisting of heptanol, octanol, 
and mixtures thereof; 
(IV) a cosolvent selected from the group consisting of n-hexane, 
cyclohexane, heptane, and mixtures thereof, 
wherein the volume ratio of the solvent of (e)(III) to the cosolvent of 
(e)(IV) ranges from about 60:40 to about 90:10; 
wherein the total amount of the solvent of (e)(III) plus the cosolvent of 
(e)(IV) present in the second mixture ranges from about 60 to about 95 
percent by weight based upon the total weight of the second mixture; 
(V) water, wherein the amount of water added in step (e) is sufficient to 
initiate the reaction of the first intermediate and squaric acid upon 
heating in step (f); 
(f) heating, with agitation, the second mixture to reflux until consumption 
of the first intermediate ceases in order to form a second intermediate of 
the formula 
##STR9## 
optionally removing water from the mixture via azeotrope during step (f); 
(g) cooling the second mixture to a temperature of about 10 to about 40 
degrees C; 
(h) isolating the second intermediate by filtration from the mixture of 
step (g); 
(i) washing the second intermediate in ethanol to remove any remaining 
octanol or heptanol, followed by washing the second intermediate in ethyl 
acetate to remove any remaining ethanol; 
(j) forming a third mixture comprising: 
(I) the second intermediate; and 
(II) pyridine; 
wherein about 15 to about 40 molar equivalents of pyridine are present in 
the third mixture based on the second intermediate; 
(k) forming a fourth mixture by adding, with agitation, about 4 to about 6 
molar equivalents of an aliphatic acid chloride comprising about 2 to 
about 8 carbon atoms, based on the second intermediate, to the third 
mixture; wherein the fourth mixture is not allowed to reach a temperature 
greater than about 50 degrees C by virtue of one or both of the following 
(I) cooling the mixture; (II) controlling the rate at which the aliphatic 
acid chloride is added; in order to form a compound of the formula 
##STR10## 
wherein R' is --(CH.sub.2).sub.n H wherein n=1 to 7. 
wherein essentially anhydrous conditions are maintained throughout steps 
(j) and (k); 
(l) isolating the compound of step (k) by adding an acetate ester selected 
from the group consisting of ethyl acetate, isopropyl acetate, amyl 
acetate, methyl acetate, propyl acetate, butyl acetate, and mixtures 
thereof and an aqueous HCl solution to the fourth mixture in order to form 
a final mixture from which the compound precipitates out, wherein the 
molar equivalent of the aliphatic acid chloride included in step (k) plus 
the molar equivalent of HCl included in step (l) approximately equals the 
molar equivalent of pyridine included in step (j); 
wherein the weight ratio of acetate ester plus water to pyridine is about 
3:1 to about 8:1; and 
wherein the weight ratio of acetate ester to water is about 0.5:1 to about 
2:1; 
(m) isolating the compound by filtration from the final mixture which is 
optionally warmed to solubilize any impurities prior to filtration; and 
(n) washing the compound with ethyl acetate followed by methanol in order 
to purify the compound.

DETAILED DESCRIPTION OF THE INVENTION 
As indicated previously the first step of the method of the invention 
involves forming a first mixture comprising: 
(I) a compound of the structure 
##STR11## 
(II) a compound of the structure 
##STR12## 
wherein the molar ratio of the compound of (I) to the compound of (II) is 
0.5:1 or greater (preferably about 0.5:1 to 0.7:1); and 
(III) about 50 to about 90 percent by weight of a solvent selected from the 
group consisting of ethanol, n-propanol, isopropanol, and mixtures 
thereof, based upon the total weight of the first mixture; 
wherein the first mixture is free of acid catalyst. 
The first mixture includes a solvent selected from the group consisting of 
ethanol, n-propanol, isopropanol, and mixtures thereof. The purpose of 
this solvent is to provide solubility for the reactants and furthermore 
cause the desired product to crystallize upon cooling to facilitate the 
isolation. These solvents also provide for an ideal reflux temperature to 
facilitate the reaction. 
As indicated above the first mixture must be free of acid catalyst. For 
example, the use of an acid catalyst such as para-toluenesulfonic acid to 
accelerate the reaction would have adverse effects later in the process 
causing the final dye mixture to become nearly impossible to filter. 
In the second step the first mixture is heated, with agitation, to reflux 
in order to form a first intermediate of the formula 
##STR13## 
The first mixture is typically heated to a temperature range of about 30 
degrees C. to about 150 degrees C., preferably about 60 degrees C. to 
about 100 degrees C., and most preferably about 75 degrees C. to about 100 
degrees C. The reaction typically takes place in about 0.5 to about 6 
hours, more typically about 1 to about 3 hours. 
The next step involves cooling the first mixture to a temperature below 
about 30.degree. C., preferably about 20.degree. to about 25.degree. C., 
followed by isolating the first intermediate by filtration. This can be 
accomplished by a number of methods including but not limited to vacuum 
filtration and centrifuge filtration. It is important to cool to below 
30.degree. C. to assure complete crystallization of Intermediate 1 from 
the reaction mixture. 
Next, the first intermediate is washed with a solvent selected from the 
group consisting of ethanol, propanol, isopropanol, and mixtures thereof. 
These solvents work well due to the low solubility of the product in them, 
while traces of starting materials present would be soluble and thus 
removed. 
The next step involves forming a second mixture, wherein the second mixture 
comprises: the first intermediate; squaric acid; a solvent selected from 
the group consisting of heptanol, octanol, and mixtures thereof; a 
cosolvent selected from the group consisting of n-hexane, cyclohexane, 
heptane, and mixtures thereof; and water. 
It is critical in this step that the molar ratio of the first intermediate 
to squaric acid is about 2:1 to about 1.7:1. Excess squaric acid would 
retard the reaction which would lead to more decomposition of the desired 
product. 
The solvent is selected from the group consisting of heptanol, octanol, and 
mixtures thereof. The use of these solvents enables one to form the 
required monoester of squaric acid, and at the same time facilitate the 
removal of water from the reaction mixture. Preferably the solvent is 
octanol. Lower alcohols such as C.sub.1-6 are not suitable, as such lower 
alcohols would be very difficult to remove from the product. Long drying 
times (several days) at elevated temperature (200 degrees C.) would be 
required to remove these lower alcohols. Such drying conditions are 
undesirable due to the observed thermal instability of Intermediate 2 
prepared by such a method. 
It is also important to use a cosolvent selected from the group consisting 
of n-hexane, cyclohexane, heptane, and mixtures thereof. These cosolvents 
serve to create an azeotrope with water and the solvent (octanol and/or 
heptanol) at a temperature high enough to provide a convenient rate of 
reaction but low enough to prevent decomposition of the product. 
Additionally, these are non-solvents for the product, ensuring product 
precipitation. If cosolvents such as toluene were used the mixture would 
have a higher azeotrope temperature resulting in lower purlties. 
Preferably the cosolvent is cyclohexane in order to obtain highest yields 
and purities. 
It is also critical that the volume ratio of the solvent to the cosolvent 
in this step ranges from about 60:40 to about 90:10. It is important to 
maintain this range as this is the range in which the azeotrope 
temperature is high enough to allow reaction but low enough to cause 
little decomposition of the product. If the volume ratio fell below about 
60:40 the reaction temperature would be too low for reaction to occur in a 
reasonable amount of time. If the volume fell above the ratio of about 
90:10, purity would drop due to the higher azeotrope temperature. 
Preferably the volume ratio of the solvent to the cosolvent ranges from 
about 65:35 to about 80:20 for reasons of highest yield and purity. 
It is also critical that the total amount of the solvent plus the cosolvent 
present in the second mixture ranges from about 60 to about 95 weight 
percent based upon the total weight of the second mixture for the 
following reasons. Amounts of solvent outside this range result in 
problems related to material handling (stirring, filtration, etc.). 
Preferably the total amount of solvent plus cosolvent present in the second 
mixture ranges from about 75% to about 85% based upon the total weight of 
the second mixture for reasons of optimum yield and purity. 
It is also critical that about 0.05 to about 3 percent by weight water, 
based on the total weight of the solvent plus the cosolvent be included 
during this step. If the water were not present the reaction would fail to 
start. Preferably the amount of water included in this step is about 0.1 
to about 0.5 percent by weight based on the total weight of the solvent 
plus the cosolvent. 
The next step involves heating the second mixture to reflux, with 
agitation, until consumption of the first intermediate ceases in order to 
form a second intermediate of the formula 
##STR14## 
while optionally removing water from the mixture via azeotrope during this 
step in order to provide higher yields and purity. It is thus preferred to 
remove water during this step. Typically this procedure takes about 1 to 
about 4 hours, more typically about 3 hours. 
The next step involves cooling the second mixture to a temperature of about 
10 to about 40 degrees C. which is a convenient and relatively safe 
temperature for handling the mixture under normal circumstances. 
The next step involves isolating the second intermediate by filtration from 
the mixture. This can be done by a number of methods such as, for example, 
vacuum filtration and centrifuge filtration. 
The next step involves washing the second intermediate with ethanol to 
remove any remaining octanol and/or heptanol. Ethanol washing is 
convenient to remove octanol and/or heptanol. Ethanol provides a low cost, 
low toxicity solvent which can easily be removed by ethyl acetate. The 
next step involves washing the second intermediate in ethyl acetate to 
remove any remaining ethanol. It is important to use ethyl acetate because 
ethyl acetate works well to remove all of the ethanol and will not 
interfere in the next step. It is important to remove all alcohols because 
they would react in the next step and lower the yield. If ethyl acetate is 
used it is not necessary to dry the second intermediate prior to use in 
the next step. It is advantageous to avoid a drying step due to the 
thermal instability of the second intermediate. 
In the next two steps essentially anhydrous conditions are maintained 
throughout, as the presence of water would decrease the yield. It is 
important to minimize or eliminate water present in order to minimize 
losses due to hydrolysis. 
The purity of Intermediate 2 prepared according to the invention typically 
is at least about 65%, preferably at least 80% as determined by NMR. 
The next step involves forming a third mixture comprising the second 
intermediate and pyridine, wherein about 15 to about 40 molar equivalents 
of pyridine are present in the third mixture based on the second 
intermediate. If less than about 15 molar equivalents were present the 
reaction mixture would become too thick to stir effectively. If greater 
than about 40 molar equivalents were present precipitation of the final 
dye would be incomplete. It is important that the second intermediate be 
well dispersed in the pyridine solvent. This can be achieved by careful 
addition of the intermediate to the pyridine under high agitation or by 
the use of a homogenizer or similar equipment. Preferably about 20 to 
about 30 molar equivalents of pyridine are present in the third mixture 
based upon the second intermediate in order to optimize mixing and 
precipitation. 
The next step involves forming a fourth mixture by adding, with agitation, 
about 4 to about 6 molar equivalents of an aliphatic acid chloride 
(preferably n-hexanoyl chloride) based on the second intermediate to the 
third mixture; wherein the fourth mixture is not allowed to reach a 
temperature greater than about 50 degrees C by virtue of one or both of 
the following: (I) cooling the mixture; (II) controlling the rate at which 
the aliphatic acid chloride is added; in order to form a compound of the 
formula 
##STR15## 
wherein R' is defined above. Preferably R' is C.sub.5 H.sub.11. 
If greater than about 6 molar equivalents of aliphatic acid chloride were 
added the yield could decrease greatly. Preferably the molar equivalents 
of aliphatic acid chloride in the fourth mixture ranges from about 4.6 to 
about 5 for reasons of optimum yield. 
It is important that the fourth mixture not be allowed to reach a 
temperature greater than about 50 degrees C. in order to avoid 
decomposition of the product, preferably not greater than about 10 degrees 
C. to further minimize decomposition. 
The next step involves isolating the compound by adding an acetate ester 
selected from the group consisting of ethyl acetate, isopropyl acetate, 
amyl acetate, butyl acetate, propyl acetate, methyl acetate, and mixtures 
thereof and an aqueous HCl solution to the fourth mixture in order to form 
a final mixture from which the compound precipitates. It is critical that 
the molar equivalent of aliphatic acid chloride included in a previous 
step plus the molar equivalent of HCl included in this step approximately 
equal (preferably equal) the molar equivalent of pyridine. If the HCl is 
used in an amount insufficient to neutralize all the pyridine, the 
pyridine will be difficult to remove. 
It is also critical that the weight ratio of acetate ester plus water to 
pyridine is about 3:1 to 8:1 and that the weight ratio of acetate ester to 
water is about 0.5:1 to 2:1. If these ratios are not satisfied the product 
will not precipitate in good yields. Preferably, in this step the ratio of 
acetate ester plus water to pyridine is about 4:1 to 5:1, and the ratio of 
acetate ester to water is about 1: 1 to about 1.5:1. It is preferred to 
warm the mixture to solubilize the impurities prior to filtration, 
preferably about 10 to about 30 degrees, and most preferably about 20 to 
about 30 degrees C. 
The next step involves isolating the compound by filtration. This can be 
done by a number of methods including but not limited to vacuum filtration 
and centrifuge filtration. 
The next step involves washing the compound with an acetate ester selected 
from the group consisting of ethyl acetate, isopropyl acetate, amyl 
acetate, methyl acetate, propyl acetate, butyl acetate, and mixtures 
thereof, followed by methanol in order to purify the compound. The acetate 
effectively removes byproducts from the reactants. Methanol effectively 
removes pyridine hydrochloride. 
The purity of the compound prepared according to the invention typically is 
at least about 80 percent of theoretical, preferably at least about 90 
percent as determined by NMR or ultraviolet spectroscopy. 
The reaction vessel and conditions under which the compound is made can 
vary but typically glass vessels capable of heating, cooling, reflux and 
azeotropic removal of water are used. The yields of dye obtained via the 
method of the invention are typically from about 40 percent or greater, 
preferably about 85 percent or greater, based upon the theoretical yield. 
EXAMPLES 
The following examples further illustrate but do not limit the present 
invention. All parts, percentages, ratios, etc. are by weight unless 
indicated otherwise. 
EXAMPLE 1 
Preparation of Intermediate 1 
477 g (3.015 moles) of 1,8-diaminonaphthalene, 295 g (1.635 moles) of 
1,3-dihydroxyacetone dimer, and 2.7 liters of 1-propanol were combined in 
a 5 liter glass flask fitted with a mechanical stirrer and reflux 
condenser. The resulting mixture was then heated to reflux. After 1 hour 
at reflux, the mixture was cooled to 25.degree. C. The product which 
crystallized from the reaction mixture upon cooling was collected via 
vacuum filtration and washed with 500 ml of 1-propanol. The tan solid was 
then recrystallized from another 2 liters of 1-propanol, filtered via 
vacuum filtration and air dried. The yield was 528 g (76% yield). 
EXAMPLES 2-5 
Preparation of Intermediate 2. Investigation of Solvent Effects on Yield 
and Purity of Intermediate 2. 
General procedure: A mixture of 1.00 g (4.35 mmol) of Intermediate 1, 0.248 
g (2.17 mmol) of squaric acid, 5 ml of 1-octanol, and 2 ml of the 
cosolvent (see Table 1 ) was heated with magnetic stirring at reflux with 
a Dean-Stark trap under nitrogen for 1 hour. After cooling to room 
temperature (about 25 degrees C.), the product was filtered off, washed 
with ethanol, and dried. The purity of the product was determined by 
proton NMR analysis in DMSO-d.sub.6 using 2,3,5-triiodobenzoic acid as an 
internal standard. The crude yield, purity, and actual yield are recorded 
in Table 1. 
TABLE 1 
______________________________________ 
Cosolvent Crude Actual 
Boiling Point 
Yield Purity 
Yield 
Example 
Cosolvent (.degree.C.) 
(%) (%) (%) 
______________________________________ 
2 toluene 110 86 75 64 
3 heptane 98 90 80 72 
4 cyclohexane 
81 96 85 82 
5 hexane 69 92 87 80 
______________________________________ 
EXAMPLE 6 
Esterification of Intermediate 2 (Example 2) 
10.00 g of crude intermediate 2 as obtained from Example 2, 37 ml of 
pyridine and 11 ml of ethyl acetate were combined with mechanical stirring 
in a 500 ml flask under nitrogen. Next, 11.6 ml of hexanoyl chloride were 
added dropwise to this mixture over 5 minutes. The mixture was cooled 
during the hexanoyl chloride addition using a water bath. After 1 hour, 75 
ml of ethyl acetate was added, the mixture stirred for 20 minutes, and 
then cooled in an ice/water bath. 38.9 g of concentrated hydrochloric acid 
in 50.7 ml of water were added slowly, keeping the temperature below 
17.degree. C. The mixture was warmed to room temperature for 40 minutes 
and the product was vacuum filtered off, washed with 300 ml of water, 
partially air dried, stirred with 85 ml of methanol for 38 min, vacuum 
filtered, and dried. The resulting yield was 57%. 
EXAMPLE 7 
Esterification of Intermediate 2 (Example 4) 
10.00 g of crude Intermediate 2 as obtained from Example 4, 37 ml of 
pyridine, and 11 ml of ethyl acetate were combined with mechanical 
stirring in a 500 ml flask under nitrogen. Next, 11.6 ml of hexanoyl 
chloride were added dropwise over 5 min. The mixture was cooled during the 
hexanoyl chloride addition using a water bath. After 1 hour, 75 ml of 
ethyl acetate was added, the mixture stirred for 20 min, and then cooled 
in an ice/water bath. 38.9 g of concentrated hydrochloric acid in 50.7 ml 
of water were added slowly, keeping the temperature below 17.degree. C. 
The mixture was warmed to room temperature for 40 min, and the product was 
vacuum filtered off, washed with 300 ml of water, partially air dried, 
stirred with 85 ml of methanol for 38 min, vacuum filtered, and dried. The 
resulting yield was 64%. In comparison with Example 6, the purer lot of 
Intermediate 2 used in this example gave the higher yield of final dye 
product. 
EXAMPLE 8-12 
Preparation of Intermediate 2. Comparison of Solvent Ratio and Added Water 
General procedure: 20 g of Intermediate 1 (0.087 moles), 4.95 g of squaric 
acid (0.0434 moles), cyclohexane, toluene, and water charges indicated in 
Table 2 were combined in a 500 ml flask fitted with a mechanical stirrer, 
a Dean-Stark trap and a reflux condenser. The mixture was heated to reflux 
and was held at reflux for a total of 1 hour. At the end of the reflux 
period, the mixture was cooled to room temperature (about 25.degree. C.). 
The solid Intermediate 2 was collected by vacuum filtration, washed with 
ethanol until the washings were light yellow, and air dried overnight. The 
results are summarized in Table 2. Note that the octanol was not dried, so 
water was present in all reactions in this table. 
TABLE 2 
______________________________________ 
Cyclo- Added 
hexane Octanol Water Temp. Yield Purity 
Example 
(ml) (ml) (ml) (.degree.C.) 
(g) (%) 
______________________________________ 
8 53 80 1 95.5 10.3 63 
9 27 107 1 111.5 19.9 72 
10 53 80 0 97.9 15 80 
11 27 107 0 114.5 21 74 
12 40 93 0.5 110 21.3 79 
______________________________________ 
EXAMPLE 13 
Preparation of Intermediate 2 Without Azeotropic Water Removal 
20 g of Intermediate 1 (0.087 moles), 4.95 g of squaric acid (0.0434 
moles), 40 ml of cyclohexane, and 93 ml of octanol were combined in a 500 
ml flask fitted with a mechanical stirrer, and a reflux condenser. The 
mixture was heated to reflux and held at reflux for a total of 1 hour. At 
the end of the reflux period, the mixture was cooled to room temperature 
(about 25.degree. C.). The solid Intermediate 2 was collected by vacuum 
filtration, washed with ethanol until the washings were light yellow, and 
air dried overnight. The resulting yield was 17.7 g and the purity by 
proton NMR was only 68%. This illustrates that the removal of water from 
the reaction mixture via azeotropic distillation is important to obtaining 
high purity. 
EXAMPLE 14 
Intermediate 2 preparation 
50 g of Intermediate 1 (from Example 1), 12.38 g of squaric acid, 100 ml of 
cyclohexane, 232.5 ml of octanol and 1.0 ml of water were combined in a 1 
liter flask fitted with a thermometer, mechanical stirrer, and a Dean 
Stark trap. The mixture was heated to reflux. After 3 hours, the 
accumulation of water in the trap had stopped. The reaction was cooled to 
room temperature (about 25 degrees C.). The solid product collected on a 
Buchner funnel, washed with 900 ml of ethanol and 900 ml of ethyl acetate 
and sealed in a bottle. The dry yield was calculated after air drying a 
sample overnight to be 95.04% and NMR analysis indicated that it was 82% 
pure. 
EXAMPLE 15 
Soluble Dye Preparation Using 5.0 Molar Equivalents of Hexanoyl Chloride 
25 g (0.046 moles) of Intermediate 2 (prepared similar to, but not 
identical to, Example 14, and having a purity of 66%) and 90 g ofpyridine 
(1.137 moles) were combined in a 1 liter flask under a dry nitrogen 
atmosphere. The mixture was cooled to &lt;5.degree. C. with an ice bath. 31.2 
g (0.232 moles) of hexanoyl chloride was added slowly keeping the 
temperature below 10.degree. C. The total addition time was 1 hour. After 
the addition was complete, stirring was continued for 1 hour at 5.degree. 
C. 243 g of ethyl acetate were then added. A premix of 126 g of water and 
91 g of 37% hydrochloric acid was then slowly added keeping the 
temperature below 10.degree. C. After this addition was complete the 
mixture was stirred for 20 minutes at 5.degree. C. The solid product was 
collected via filtration. The resulting solid was washed on the filter 
with 100 ml of ethyl acetate and 400 ml of methanol. After air drying, the 
yield was 57%, which when taking the purity of the Intermediate 2 (66%) 
into account the true yield was 86%. The final dye was 83% pure with 11% 
unreacted Intermediate 2. 
EXAMPLE 16 
Soluble Dye Preparation Using 5.6 Molar Equivalents of Hexanoyl Chloride 
25 g (0.046 moles) of Intermediate 2 (prepared similar to, but not 
identical to, Example 14, and having a purity of 66%) and 90 g of pyridine 
(1.137 moles) were combined in a 1 liter flask. The mixture was cooled to 
&lt;5.degree. C. with an ice bath. 35.0 g (0.260 moles) of hexanoyl chloride 
were slowly added keeping the temperature below 10.degree. C. The total 
addition time was 1 hour. After the addition was complete, stirring was 
continued for 1 hour at 5.degree. C. 243 g of ethyl acetate were then 
added. A premix of 126 g of water and 91 g of 37% hydrochloric acid was 
then slowly added keeping the temperature below 10.degree. C. After this 
addition was complete the mixture was stirred 20 minutes at 5.degree. C. 
The solid product was then collected via filtration. The resulting solid 
was washed on the filter with 100 ml of ethyl acetate and 400 ml of 
methanol. After air drying, the yield was 42%, which when taking the 
purity of the Intermediate 2 into account (66%) the true yield was 57%. 
The final dye was 92% pure with 2% unreacted Intermediate 2. 
While this invention has been described in connection with specific 
embodiments, it should be understood that it is capable of further 
modification. The claims herein are intended to cover those variations 
which one skilled in the art would recognize as the chemical equivalent of 
what has been described here.