WO2018064735A1 - Process for producing carboxy metallo-phthalocyanines that can be used for producing dyes and pigments - Google Patents

Abstract

The present invention patent application relates to a novel process for producing carboxy metallo-phthalocyanines that can be used for producing dyes and pigments for the textile industry, inter alia, which is more efficient in producing said molecule, with a lower cost and an extremely low waste production level; the process in question comprises five steps, wherein the first step is that of a cyclization reaction and formation of the intermediate iron tetraimidophthalocyanine (TI-FePc) with a yield of approximately 35%; the second step is that of purifying the insoluble TI-FePc using a solution of HCl recovered in the fifth step; the third step is the step of a basic hydrolysis reaction using the solution recovered in the fourth step, generating the intermediate iron octacarboxyphthalocyanine (OC-FePc); the fourth step is the step of precipitating with calcium ions, separating the CaOC-FePc pigment and recovering the NaOH solution reused in the third step; and the fifth step is the step of acidification using hydrochloric acid and conversion of CaOC-FePc into the product HOC-FePc and recovery of the acid solution for reuse in the second and fifth steps.

Description

 "CARBOXI PRODUCTION PROCESS METALO-FTALOCIANINES FOR

EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS. "FIELD OF APPLICATION

 This application relates to a process for the production of functional dyes and pigments based on carboxy metallophthalocyanines for use in the textile field, among others.

PREAMBLE

 This application relates to an innovative process for the production of carboxy-metallophthalocyanines usable in the production of dyes and pigments, as well as the carboxy-metallophthalocyanines thus obtained. STATE OF THE TECHNIQUE

Phthalocyanines (Pc) are a class of aromatic planar macrocyclic compounds with 18 π electrons delocalized on the carbon and nitrogen atoms. ¹ ' ³ Its structure resembles that of a square and is formed by four isoindole units connected by imine bridges (-N =) forming a ring with a cavity having four internal nitrogens. The central cavity of this class of macrocyclic compounds can accommodate 2H ⁺ (base-free phthalocyanine) or bind metal ions, especially transition metal ions in various oxidation states, producing derivatives called metallophthalocyanines (MPcs). In fact, these compounds macrocycles can generate complexes with the great majority of metallic elements of the periodic table. ⁴

Such singular electronic and molecular structure causes them to be photochemically, electrochemically and catalytically active, and such properties can be controlled / adjusted as a function of the central metal ion and its oxidation state, the substituents at the periphery of the ring, and also in function the way and the degree of intermolecular association, generating the diverse properties that are being explored in science and technology. For example, they tend to aggregate by forming stacking structures as a function of the strong intermolecular interactions π (ττ-stacking), which can become excellent conductors when doped. In addition, the base-free phthalocyanine as well as its metal complexes exhibit strong coloration which together with their thermal and photochemical stability are responsible for their wide application as dyes and pigments particularly in textiles and in the printing and inks industry generally. Also, due to their electronic and redox properties, phthalocyanines and their metallic derivatives are materials used in several technological fields such as molecular electronics, solar and photovoltaic cells, photonic devices, electrochromic displays, gas sensors, nonlinear optics, photodynamic therapy, liquid crystal, catalysis and electrocatalysis and nanotechnology. ¹

 Thus, unsubstituted phthalocyanines metallized with iron, nickel, cobalt, zinc, magnesium, etc. are produced in large scale to meet the demands, mainly by the pigments sector, in view of the simplicity and high efficiency of the reactions of cyclization. However, the efficiency of this fundamental reaction is dependent on the type and number of substituent groups present at the periphery of the ring, becoming significantly smaller in the case of reactive substituents such as carboxylic acid / carboxylate. In fact, the yield tends to decrease further as a function of the number of carboxyl groups attached to the ring, making them less economically competitive. However, these molecules exhibit interesting catalytic properties, particularly with respect to oxidation reactions, more specifically, molecular oxygen activation reactions. Thus, biocidal and odor removal properties have been reported as interesting for the development of new applications and products. Thus, more efficient, large-scale production processes of carboxylated metallophthalocyanines, and consequently lower production costs, may enable the development of new products and applications, particularly as dyes, pigments and functional additives for various sectors, including textile industry.

Phthalocyanines can be prepared from the condensation of various types of precursors such as 1,2-dicyanobenzene (phthalonitrile), benzene-1,2-dicarboxylic acid, carboxylic acid anhydrides, 1,2-dicarboxamidabenzene, phthalimide, and 1,3- diiminoisoindoline. ^{1 '5> 6} The free base phthalocyanine may be prepared by the reaction of strong base with ftalonitrila in alcohol under heating. ⁵ It is also possible to obtain via demetalation in the middle of MGPC concentrated strong acid previously obtained by heating the ftalonitrila in the presence of magnesium metal. The MPCS ^5, wherein M = metal ions can be obtained by heating anhydrous metallic salts of ftalonitrila (Fig.1) in a suitable solvent of high boiling point. In case the starting reagent is a carboxylic acid derivative such as anhydrides and amides, as well as phthalimide and 1,3-diiminoisoindoline, the metallocated phthalocyanines being prepared by heating said derivatives in nitrobenzene in the presence of the respective metal salts, a catalyst and urea having a melting temperature ^Q C and 133 acts as a high-boiling solvent and, in some cases, as a source of nitrogen atoms. ⁵

PCCs and MPCs substituted with carboxylic acid groups (carboxy metallophthalocyanines) are manufactured from the above-mentioned precursors but substituted with carboxylic acids or their derivatives, or nitriles at the desired positions. Thus, in the cyclization process the respective imide derivatives, which act as protecting groups to increase the yield of the reaction, are generated which are then hydrolyzed in alkaline medium to generate the corresponding carboxylic acid derivatives. ^{2 '7> 8} For example, MPC substituted tetra (Figure 2) with the imido group are obtained from the reaction of the acid anhydride or trimellitic acid (acid 1, 2,4-tricarboxibenzóico) with the metal salt of interest, urea and a catalyst at temperatures of about 200 ^Q C. then, the imide groups are hydrolyzed with a strong base yielding the corresponding metallated octacarboxiftalocianinas (OC-MPCs).

 Among the routes available for the preparation of metallated octacarboxyphthalocyanines, one based on the thermally induced reaction of pyromellitic dianhydride or 1,2,4,5-tetracyanobenzene in the presence of a desired metal salt and a catalyst, generally ammonium molybdate or DBU (1 , 8-diazabicyclo [5.4.0] undec-7-ene in a high boiling solvent is one of the most efficient. MPC formation is symmetrically substituted with four phthalimide groups which are subsequently hydrolyzed with strong base to eight carboxylate groups with strong base, and finally converted into carboxylic acid groups via acidification and precipitation, as shown in figure 3.

The carboxylate groups impart negative charge and solubility to the OC-MPc. In fact, such functional groups can be used both for binding of the fibers and as sites for binding of substituents with suitable characteristics. Thus, the addition of strong mineral acids leads to the neutralization of the negative charges by protonation generating poorly soluble carboxylic acid derivatives, as shown in figure 3. ^{2> 9 '10} The manufacturing process of both tetra-substituted and octa-substituted MPCs is performed in two steps, as shown in Figures 2 and 3, respectively. The first step involves the cyclization reaction, where the formation of the macrocycle ring occurs, generating a dark solid resulting from the mixture of MPc (insoluble) with impurities generated in the process. In the second hydrolysis step, the reaction of the phthalimide group is carried out with a concentrated aqueous solution of strong base, about 50% by mass of sodium or potassium hydroxide, in order to liberate the carboxylate groups. This high concentration is necessary since it also has the function of solubilizing and enabling the elimination of the organic impurities coming from the first stage. ^{7 '11} Finally, the solution is acidified to pH 2.0 for precipitation of the dye.

 In Japanese Patent No. 10-101673 issued on behalf of Orient Chemical Co., Osaka, Japan, the solvent used in the first step of the manufacturing process, ie, in the cyclization step and formation of the macrocyclic ring is polyethylene glycol dialkyl ether, which according to patent does not need to be removed by evaporation at the end of the reaction, making it possible to manufacture metallated phthalocyanines by the urea method with high yield, low cost, by a safe and simple method. Obviously the solvent and its decomposition products are removed in the second stage of the process and correspond to much of the organic filler in the residual sodium hydroxide solution.

However, due to the high amount and high concentration of the base used in the hydrolysis step, there is a high acid consumption in the acidification step, besides the formation of large amounts of salt, which precipitates together with the desired product and makes it difficult to separate the octacarboxy derivatives and metallocated tetracarboxyphthalazines of interest to the by-products of the reaction. In fact, the carboxyphthalocyanines co-precipitate with sodium chloride to form very small particles and difficult to separate by conventional methods of filtration or decantation, even considering the possibility of solubilizing the salt (most of the mixture) with water. It is important to emphasize that these two factors create difficulties for the large-scale production of tetracarboxy and octacarboxyphthalocyanine complexes metalloated with transition metal ions, both by raising production costs and by generating low value contaminated waste that needs to be treated and discarded. In addition, although sodium and potassium chlorides are not toxic, discarding large quantities of them in ponds or streams of freshwater or even saltwater can cause unacceptable environmental impacts and can be controlled by environmental monitoring agencies . Thus, it is necessary to develop manufacturing processes that minimize or even do not lead to the generation of salts and wastes in the process of obtaining those products, in order to minimize costs and reduce possible environmental impacts, generating more sustainable processes. This can be achieved by developing new routes and optimizing the respective parameters of the manufacturing process.

 PROBLEMS OF THE STATE OF THE TECHNIQUE

The iron octacarboxyphthalocyanine (HOC-FePc) production scheme by the Japanese methodology is shown in figure 4. The first step consists of the cyclization reaction and formation of the phthalocyanine ring. Reagents iron chloride (III) (FeC), pyromellitic dianhydride, urea (CH ₄ N ₂ O), ammonium molybdate ((ΝΗ ₄ ) 6Μθθθ 24.4Η²θ) and dialkyl ether polyethylene glycol are mixed and the temperature raised to 180 ° C. In this step tetraimidophthalocyanine (TI-FePc), precursor of HOC-FePc, is produced, because urea acts as a donor of nitrogen atoms by converting the anhydro acid groups to imide groups. In this first step, high amounts of impurities are formed because the reaction yields are relatively low (<50%) generating large quantities of solid by-products, including those from urea, the catalyst, the solvents, and the reactants. It is important to mention that the tetraimidophthalocyanine intermediate product (TI-FePc) obtained in this step is a solid insoluble in most organic solvents and in water, and contains significant amounts of contaminants including insoluble or poorly soluble alkali metal oxide-hydroxides such as iron. Thus, even the use of concentrated solutions of sodium hydroxide (41.6 g of NaOH per gram of HOC-FePc is used in the Japanese process, figure 4) at 100 ° C, used in the second step of the hydrolysis of the group and formation of carboxylate groups generating the soluble OC-FePc product may not be sufficient for the removal of those types of contaminants. These iron oxide-hydroxide type contaminants are supposed to be removed in treatment with subsequent muriatic acid for acidification and protonation of carboxylate groups to carboxylic acid, yielding the poorly soluble HOC-FePc product which can be separated by physical methods. However, in this process all excess NaOH added should be neutralized and an excess of hydrochloric acid should be added to bring the pH down to about 1, suitable for precipitation of the product, generating large amounts of sodium chloride (about 61 g NaCl per gram HOC-FePc), which precipitates together with the desired product to give a blue slurry. In fact, the consumption of hydrochloric acid is also very great using 102.75 g of 37% HCl solution per gram of HOC-FePc produced. Thus, the product impregnated into the salt is extracted with NaOH solution and reprecipitated with HCl solution.

 Another relevant aspect that must be improved is the yield of the process. Comparative spectrophotometric studies performed with the commercial product and the one produced according to the present patent application clearly show that the dark blue marketed solid contains large amounts of impurities. As shown in Figure 6, the bulk percentage of impurities amounts to more than 2/3 so that the reported yield of 42% (according to Japanese Patent 10-101673 of 1998) is far from reality, decreasing to about 14% when corrected for pure product content. In the present patent application alternatives are presented to make the process more efficient and sustainable, in addition to enabling the production of insoluble products suitable for application as pigments.

SUMMARY

As mentioned previously, there is a need to minimize the formation of by-products and residues in the process of manufacturing octacarboxyphthalocyaninate iron (HOC-FePc) acid. The great majority of the methodologies described in the literature and in Japanese Patent 10-101673 of 1998 utilize a high volume of a 50% by weight solution of sodium or potassium hydroxide which requires a high amount of hydrochloric acid solution to neutralize the solution and isolating the product, thereby generating large amounts of sodium chloride or potassium chloride as waste. ^{7 '11} Thus, using the structural and chemical characteristics of this type of molecule, a new, more efficient synthetic route was developed, which leads to the production of a product with a high purity, with a lower cost and practically no production residues (mainly salts) when compared to traditional methodologies as well as the method of Japanese patent 10-101673 of 1998, making the process ecologically more sustainable. This innovation was achieved by the addition of two strategic steps in the process: a) purification of the iron tetraimidophthalocyanine precursor (TI-FePc) obtained after the cyclization reaction with hydrochloric acid solution, eliminating most impurities of oxide-hydroxides of iron, and b) separating the product after hydrolysis with dilute aqueous sodium hydroxide solution using a calcium salt as a calcium chloride as the precipitating agent, thus enabling the reuse of the alkaline NaOH solution in the hydrolysis step and avoiding undesired production of sodium chloride. In short, the incorporation of the aforementioned strategic steps results in a double base and acid economy, in addition to preventing the formation of salt, an undesirable by-product that hinders the separation of the HOC-FePc product. In addition, it makes possible the production of another poorly soluble CaOC-FePc product. The iron ion can easily be replaced by other metal ions, just as the calcium ion can be replaced by other divalent cations generating dye and pigment raw materials.

GOALS

 In view of the prior art described, the subject matter of this application has been developed which has as one of its objectives to provide a process for the production of carboxy-metallocothocyanins, which has a higher efficiency in the production of such a molecule with lower cost and very low level of waste production when compared to conventional processes.

 It is a further object of this application to enable the preparation of high purity carboxy metallophthalocyanines and insoluble derivatives suitable for application as pigments.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter of this application and which addresses the process for the production of carboxy-metallophthalocyanines for use in the production of dyes and pigments, as well as the carboxy-metallophthalocyanines thus obtained will be described in detail with reference to the following figures, in which: Figure 1 shows the organic precursors for the preparation of metallophthalocyanines, phthalonitrile (a), benzene-1,2-dicarboxylic acid (b) phthalic anhydride (c) and 1,3-diiminoisoindoline (d).

 Figure 2 shows the organic precursors for the preparation of the tetra-carboxyphthalocyanine acids, MH-MPc with M = Fe (II) or Fe (III) or Co (II) or Co (III) or Cu (I) or Cu ) or Zn (II) or Ni (II) or Mn (II) or Mn (III) or Cr (II) or Cr (III) or Mg (II), as well as other metal elements.

 Figure 3 shows the organic precursors for the preparation of octa-carboxyphthalocyanine acids, HOC-MPc with M = Fe (II) or Fe (III) or Co (II) or Co (III) or Cu (I) or Cu ) or Zn (II) or Ni (II) or Mn (II) or Mn (III) or Cr (II) or Cr (III) or Mg (II), as well as other metal elements.

 Figure 4 shows the traditional synthetic route for the production of OC-FePc and HOC-FePc.

 Figure 5 shows the new synthetic route for the production of Tl-FePc, OC-FePc, HOC-FePc and CaOC-FePc.

Figure 6 shows a plot of the electron absorption spectrum of two OC-FePc samples in 0.1 mol L ¹ NaOH solution. The continuous line refers to the spectrum of a commercial sample, produced by the methodology of the Japanese patent. The dotted line refers to the sample spectrum produced by the new methodology.

LEGEND OF FIGURES

Figure 4:

4.1 - "one step"

4.2- "Impurities"

4.3- "excess"

4.4- "step 2, hydrolysis"

 4.5- "excess"

 4.6- "excess"

 4.7- "excess"

4.8- "Impurities"

 4.9 - "3- Step - precipitation"

 4.10- "4-Step, repurification"

4.1 1 - "Impurities" Figure 5:

 5.1 - "Difenileter"

5.2 ^- "Step 1"

 5.3- "Difenileter"

5.4- "Impurities"

 5.5- "Step 2, purification"

5.6 ^- Step 3, hydrolysis

 5.7- "excess"

 5.8- "4-Step, precipitation"

5.9- "filtration"

 5.10- "excess"

5.1 1 - "Step 5, substituting Ca ^2+"

DETAILED DESCRIPTION OF THE INVENTION

 The innovation in the production process refers to the implementation of two strategic steps in the general process described in the literature and Japanese Patent 10-101673 of 1998, are: a) purification of the iron tetraimidophthalocyanine precursor (TI-FePc) obtained after cyclization reaction with hydrochloric acid solution, eliminating most of the impurities of iron oxide-hydroxides, and b) separating the product after hydrolysis with dilute aqueous sodium hydroxide solution using as the precipitating agent a calcium salt as the calcium, thereby enabling the reuse of the alkaline NaOH solution in the hydrolysis step, thus avoiding undesired production of large amounts of sodium chloride. Purification of the iron tetraimidophthalocyanine precursor (Ti-FePc) with hydrochloric acid solution, and separation of the CaOC-FePc product with the calcium chloride precipitating agent, as well as the recycling and reuse of the acid and base solutions are illustrated in 5 and is described in detail below. In fact, the new process can be divided into 5 steps:

 - first step: cyclization reaction and formation of intermediate iron tetraimidophthalocyanine (TI-FePc) in about 35% yield,

- second step: purification of insoluble TI-FePc with HCI solution recovered in the fifth step, - third step: basic hydrolysis reaction using solution recovered in the fourth step generating the iron octacarboxyphthalocyanine (OC-FePc) intermediate,

 - fourth stage: precipitation with calcium ions, separation of the CaOC-FePc pigment and recovery of the NaOH solution reused in the third stage,

- fifth step: acidification with hydrochloric acid and conversion of CaOC-FePc into the product HOC-FePc and recovery of acid solution for reuse in the second and fifth stages.

 In the first stage of formation of the metallophthalocyanine ring, the reactants iron chloride (III) (FeCl3), urea (CH4N2O), ammonium molybdate tetrahydrate ((NH4) 6Mo7O24.4H2O) and pyromellitic dianhydride are intimately mixed and their temperature raised to 180 ° C in diphenylether, promoting the cyclization reaction. In view of the relatively low yield of about 35% of the reaction, a number of solid by-products, in particular iron oxide-hydroxides, molybdenum compounds and urea decomposition products are produced in addition to the TI-FePc iron tetraimidophthalocyanine precursor and of the diphenylether solvent. This is worsened by the low yields so that the traditional method used is not efficient enough for the removal of large amounts of solid impurities impregnated in the product.

Substitution of the polyethylene glycol dialkyl ether solvent by the diphenylether (from this patent application) proved to be very advantageous, as it enabled a yield of up to 150% greater in the metallocphthalocyanine production reaction compared to the process described in Japanese Patent 10-101673 of 1998. In addition, in order to increase the degree of purity of the final product and to minimize the amount of sodium hydroxide used, a purification step (second step) has been introduced which removes most of the solid impurities generated in the first step. In fact, they are probably coating the Tl-FePc particles by slowing down the hydrolysis reaction of this derivative. This purification process (second step) consists of treating the solid obtained in the first stage with a solution of hydrochloric acid to solubilize the organic and inorganic species, which are formed in the reaction medium. During purification of the precursor TI-FePc remains as solid which facilitates its separation of the hydrochloric acid solution. It is important to mention that this solution does not need to be neutralized, and the hydrochloric acid solution could be treated and reused for the purification of TI-FePc. However, we must remember that a less contaminated and suitable solution for this process is produced in the fifth step. The reagent reuse process is represented by dashed arrows in figure 5.

In the third step, the purified TI-FePc precursor is hydrolyzed with sodium hydroxide. Due to the higher purity of the precursor, this step can be carried out with a more dilute base solution than in the traditional methodology. In this new methodology, only 2.0 g of sodium hydroxide is used for the production of 1 g of dye, representing an economy of approximately 95% when compared to the methodology described in Japanese Patent 10-101673 of 1998. At the end of this step, a solution of OC-FePc soluble in the reaction medium is obtained as a function of the eight negative charges. In the subsequent step (fourth step), a calcium chloride solution is added as a precipitating agent enabling separation of CaOC-FePc, without the need for mineral acid addition for neutralization of the carboxylate groups of the molecule. Thus, instead of using mineral acid for protonation, a cation is used which binds selectively by connecting the OC-FePc molecules, thus promoting the formation of CaOC-FePc as an insoluble solid that enables the separation of iron phthalocyanine without the need to neutralize the NaOH solution. Thus, the resulting solution contains sodium hydroxide which can be recovered by addition of sodium sulfate (Na 2 SO 4, responsible for the precipitation and separation of Ca ²⁺ ions in the form of CaSO 4 (s)) and employed in the hydrolysis of the intermediate TI-FePc, in the third step. The solid obtained in this step could be used as a functional pigment. Finally, in order to obtain the carboxylic acid derivative HOC-FePc it is necessary to replace the Ca ²⁺ ions with H ⁺ . This is accomplished by reacting the solid CaOC-FePc with HCl solution. In this way the desired product is separated from the acid chloride calcium solution, which can be reused in this same protonation / displacement step of Ca ²⁺ ions from another batch, or in the second stage of purification of the TI-FePc intermediate. Before, however, the solution should be treated with sulfuric acid and the precipitate of CaSO4 separated. As can be seen, all acid and base solutions used in the novel process are reused resulting in high reagent economy. In fact, the new method allows an economy of about 95% of base (NaOH) and also of acid. With regard to the consumption of hydrochloric acid solution, as in the present process it is employed in the purification of the precursor and for protonation of OC-FePc. It has been estimated that 15 g of a 37% HCl solution per batch is used, representing an economy of 85% relative to Japanese methodology. In addition, significant part has been replaced by a cheaper acid, that is, sulfuric acid. As sodium hydroxide and hydrochloric acid solutions are reused in the next batch, there is no production of undesirable sodium chloride in the process. The only salt formed during the process is calcium chloride or calcium sulfate itself, but in small amounts. The strategy of using a calcium salt as the precipitating agent does not result in an increase in the cost of the process, as this is a cheap reagent (its price is about one fifth of the price of hydrochloric acid) and non-toxic.

 As mentioned above, all this saving of reagents is the result of the use of calcium chloride in the production process allowing the recovery and reuse of the sodium hydroxide solution as hydrochloric acid, avoiding the formation of undesirable species such as sodium chloride in large amounts. If we consider the production of 2 g of the HOC-FePc product in two batches, the saving of sodium hydroxide and hydrochloric acid amounts to 97% and 92%, respectively.

In addition to the synthetic route being more economically feasible, it is desirable to obtain products with a high purity. The purity of the samples can be easily verified by techniques such as ultraviolet (UV) and visible (vis) absorption spectroscopy. The metal-phthalocyanines show very characteristic electronic spectra both in the visible and UV, ^{1 <5} , which enables the use of these molecules such as pigments and dyes in textile industry. Its electronic spectrum has an intense absorption band in the region between 600 and 700 nm denominated band Q, in addition to a second band of lower intensity around 600 nm. In the UV region there is a band of moderate intensity around 350 nm called the Soret band. The electronic absorption spectrum of two OC-FePc samples, one commercial and the other produced according to the present process, are shown in figure 6. The plot is presented in the form of molar absorptivity (ε) as a function of the length of to compare the purity of the two samples. In continuous line is the spectrum of the commercial sample produced using the methodology of Japanese patent 10-101673 of 1998. One can observe bands with maximum intensity in the visible region at 682 and 620 nm plus one shoulder at 654 nm, which is not usual in the metallophthalocyanine spectra. There is also a UV band at 344 nm, more intense than the band at 682 nm. The dashed line refers to the spectrum of the sample obtained by the new production process (from this patent). Similarities can be noted between the two spectra, such as the absorption maxima at 682 and 620 nm, for example, indicating that it is the same compound. However, the Soret band at 351 nm is less intense than the band at 682 nm, as expected in metallophthalocyanines. ^{1 '5} is worth mentioning that the phthalocyanine derivatives in the band 600 to 700 nm region is usually more intense than the band in the UV region. ^{1 '5} Thus these findings are strong evidence of the presence of impurities in the sample produced by the method described in Japanese Patent 10-101673 of 1998. The most pronounced difference between the spectra of the two samples is the high molar absorptivity (ε) of all bands absorbing the sample produced by the process described in this patent application (dashed line). Knowing that the molar absorptivity ε is an intrinsic property of each substance, and determined by the following equation:

A = e b C

where: A is the absorbance of the sample at a given wavelength, ε is molar absorptivity (L mol ^"1 cm ¹ ) at said wavelength, C is the concentration (mol L ^-1 ) of the solution and b is the optical path of the sample , generally 1.00 cm.

As can be seen in Figure 6, the molar absorptivity at 682 nm of the product prepared by the new process (dashed line) is about 3.34 times greater than that of the material prepared by the Japanese process. Although ε is an intrinsic property of each substance, the actual concentration of a given compound in the solution is directly influenced by the degree of purity of the substance. In fact, impurities cause a decrease of ε values proportional to their relative quantity in the sample. In this way a low value of ε is the result of a smaller amount of the compound in a given mass. In others In the words, the sample produced by the methodology described in the Japanese patent has a high amount of impurities, about 70%, when compared to the material produced by the process proposed in this patent application. That is, in order to have the same mass as HOC-FePc, it would be necessary to weigh the triple mass of the material produced by the Japanese methodology 10-101673 of 1998. Thus, by discounting the impurities present, the yield of the Japanese patent application 10-101673 of 1998 is about 12%, while the yield of the new process is about 36%. In this way the new process, besides being more economically viable and efficient, generates a product with a higher degree of purity and as a consequence makes the production of those functional materials (dyes and pigments) much more competitive.

 A scheme comparing the Japanese process and the novel process described herein is shown in Figures 4 and 5, respectively. Typical examples for the preparation of HOC-FePc are given below.

EXAMPLES

Example 1:

 2.8 g of FeCl2.4H2O, 10.0 g of pyromellitic dianhydride, 1.4 g of ammonium molybdate, and 22.9 g of urea were carefully ground, and the solid mixture added over 40 g of diphenylethane under stirring and the temperature of the reaction mixture raised to 180 ° C for 4 hours. The dark solid was filtered, washed with ethanol, refluxed for 6 hours with 100 mL of a 1.5 M NaOH solution, and diluted with 300 mL of water. Then, a solution of CaCl 2 (4.8 g in 30 mL of water) was added and the precipitate separated by filtration. Then the filtered solid was treated with 100 mL of 3.0 M HCl for 30 minutes under stirring, filtered, washed with water and dried. Yield: 3.0 g of HOC-FePc.

Example 2:

7.40 g of FeCl, 10.0 g of pyromellitic dianhydride, 1.4 g of ammonium molybdate, 22.9 g of urea were carefully ground, and the solid mixture was added over 40 g of diphenylether under stirring and the temperature of reaction mixture raised to 180 ° C for 4 hours. The dark solid was filtered, washed with ethanol and treated with 100 mL of 3.0 M HCl solution for 6 hours under stirring, filtered, and refluxed with 100 mL of a 1.5 M NaOH solution for 6 hours . A solution of CaCl2 (4.8 g in 300 mL of water) was added and the precipitate separated by filtration. Thereafter the solid was treated with 100 ml of 3.0 M HCl for 30 minutes under stirring, the solid filtered, washed with water and dried. Yield: 4.0 g of HOC-FePc.

Example 3:

 3.70 g of FeCl, 10.0 g of pyromellitic dianhydride, 1.4 g of ammonium molybdate, 22.9 g of urea were carefully ground, and the solid mixture was added over 40 g of diphenylether under stirring and the temperature of reaction mixture raised to 180 ° C for 4 hours. The dark solid was filtered, washed with ethanol and treated with 100 mL of 3.0 M HCl solution for 6 hours under stirring, filtered, and refluxed with 100 mL of a 1.5 M NaOH solution for 6 hours . A solution of CaCl 2 (4.8 g in 300 mL of water) was added and the precipitate separated by filtration. Then the solid was treated with 100 mL of 3.0 M HCl for 30 minutes under stirring, the solid filtered, washed with water and dried. The degree of purity can be increased by repeating the washing procedure. Yield: 1.5 g of HOC-FePc.

Example 4:

 5.45 g of C 12 Cl 2 .6H 2 O, 10.0 g of pyromellitic dianhydride, 1.4 g of ammonium molybdate, 22.9 g of urea were carefully triturated, and the solid mixture added on 40 g of diphenylether under stirring and temperature of the reaction mixture raised to 180 ° C for 4 hours. The dark solid was filtered, washed with ethanol and treated with 100 mL of 3.0 M HCl solution for 6 hours under stirring, filtered, and refluxed with 100 mL of a 1.5 M NaOH solution for 6 hours . A solution of CaCl 2 (4.8 g in 300 mL of water) was added and the precipitate separated by filtration. Then the solid was treated with 100 mL of 3.0 M HCl for 30 minutes under stirring, the solid filtered, washed with water and dried. The degree of purity can be increased by repeating the washing procedure. Yield: 4.0 g of HOC-CoPc.

Example 5:

5.0 g of Zn (CH 3 CO 2) 2 H 2 O, 10.0 g of pyromellitic dianhydride, 1.4 g of ammonium molybdate, 22.9 g of urea were carefully ground, and the solid mixture added on 40 g of diphenylether under stirring and the temperature of the reaction mixture raised to 180 ° C for 4 hours. The dark solid was filtered, washed with ethanol and treated with 100 mL of 3.0 M HCl solution for 6 hours filtered, and refluxed with 100 mL of a 1.5 M NaOH solution for 6 hours. A solution of CaCl 2 (4.8 g in 300 mL of water) was added and the precipitate separated by filtration. Then the solid was treated with 100 mL of 3.0 M HCl for 30 minutes under stirring, the solid filtered, washed with water and dried. The degree of purity can be increased by repeating the washing procedure. Yield: 2.0 g of HOC-ZnPc.

 The procedures of examples 1, 2, 3, 4 and 5 may undergo some changes which will be mentioned below, these changes may have influence on the yield of the reaction as well as on the purity of the final products. Obviously the exchange of the metal ion salt in the process by another metal element will generate metallated octacarboxyphthalocyanines with different metals and generate different dyes and pigments.

 The ratio of the reactants in examples 1, 2, 3, 4 and 5 is expressed as a function of the number of moles of the catalyst (ammonium molybdate), ie 1 mol of ammonium molybdate; to 12.43 mol of iron (II) chloride tetrahydrate in example 1; 40.47 mol of FeCl in Example 2; 20.23 mol of FeCl in Example 3; 20.23 mol of CO2Cl2.6H2O in example 4 and 20.23 mol of Zn (CH3 CO2) .2H2O in example 5; 40.47 mol of pyromellitic dianhydride, 336.58 mol of urea and 207.45 mol of diphenylether. The proportions of the reactants may range from 1 to 50 mols for the iron (II) tetrahydrate chloride and the other salts used in the examples from 2 to 5, 1 to 162 mols for pyromellitic dianhydride, 1 to 1500 mols for the urea and from 0 to 2000 moles for the diphenylether, generating reaction mixtures with compositions suitable for the production of the TI-FePc intermediate.

 In Examples 1 to 5, the ammonium molybdate can be replaced by 1,8-diazabicyclo [5.4.0] undec-7-ene (DBU), 1,5-diazabicyclo [4.3.0] non-5-ene ( DBN), triethylamine, 2-aminoethanol, diethylolamine or triethanolamine.

In Examples 1 to 5, the iron (II) chloride tetrahydrate may be substituted by other metal salts, typically transition metal salts (anhydrides or hydrated) such as Fe (II), Fe (III), Co (II) , Li (II), Cu (II), Ni (II), Mn (II), Mn (III), Cr (II), Cr (III) (1), among others, with anions such as halides, carboxylates (formate, acetate, oxalate), nitrate, sulfate, perchlorate, trifluoroacetate, triflate, tetrafluoroborate and hexafluorophosphate, among others. In Examples 1 to 5 the pyromellitic dianhydride may be substituted by 1,2,4,5-tetracyanobenzene, benzene-1,2,4,5-tetracarboxylic acid, 1,2,4,5-tetracarboxyamidabenzene, and pyromellitic diimide.

 In Examples 1 to 5 the pyromellitic dianhydride may be replaced by trimellitic anhydride (1,2,4-tricarboxybenzoic acid-1,2-anhydride or 1,2,4-tricarboxybenzoic acid 1,2-anhydride) (Figure 2) or 1,2,4-tricarboxybenzoic acid or 1,2-anhydridotrimellitic acid or 1,2,4-tricarboxamidabenzene acid.

 In Examples 1 to 5 the reaction temperature may range from 50 to 250 ° C.

 In examples 1 to 5 the reaction time may vary from 1 to 12 hours.

 In examples 1 to 5 the diphenylether solvent may be substituted by other high boiling solvents such as dimethylformamide, diethylformamide, nitrobenzene, 2-aminoethanol, diethanolamine, triethanolamine, ethylene glycol, diethyleneglycol, polyols, diallyl esters of polyols, polyethylene glycol dialkyl ether, among others .

 To carry out the washing step in examples 1 to 5 solvents such as methanol, acetone, acetonitrile, propanol, isopropanol, butanol, ethyl ether, among others may be used.

 In examples 1 to 5 the volume of hydrochloric acid solution used for the treatment may range from 10 to 3000 ml and its concentration may range from 0.001 to 12 M. Hydrochloric acid may be replaced by strong acids such as sulfuric, nitric, perchloric , hydrobromic, hydroiodic and trifluoroacetic acid. The reaction time may vary from 30 minutes to 12 hours. In examples 1 to 5 the base concentration may vary from 0.001 to 25 M of sodium or potassium hydroxide, among others.

 In Examples 1 to 5 the hydrolysis temperature may range from 50 to 120 ° C, and the reaction time from 0.1 to 24 hours.

 In Examples 1 to 5 the mass of CaCl 2 may range from 0.1 to

10.0 g, and the volume used to solubilize the salt may range from 1 to 1000 mL.

In Examples 1 to 5, the calcium chloride may be replaced by salts (anhydrides or hydrated) such as nitrate, bromide, formate, acetate and triflate, or by hydroxide (anhydrous or hydrated) among others of Ca (II), Ba (II), Mg (II), Sr (II) or salts of transition or lanthanide metals.

 In Examples 1 to 5 the precipitating agent may be replaced by strong acids such as hydrochloric acid, hydrobromic acid, hydroiodic acid, sulfuric acid, perchloric acid, trifluoroacetic acid, triflic acid, among others.

 In examples 1 to 5 the volume of hydrochloric acid (or other acids) may vary between 10.0 and 1000 ml of a solution having a concentration in the range of 0.001 to 16 M.

 In Examples 1 to 5 the acid treatment time may range from 0.1 to 6 hours.

REFERENCES

 1 . Mack, J., Kobayashi, N., Low Symmetry Phthalocyanines and Their Analogues. Chemical Reviews, 201 1. 1 1 1 (2): p. 281 -321.

 2. Dumoulin, F .; Durmuç, M .; Ahsen, V., Nyokong, T., Synthetic pathways to water-soluble phthalocyanines and close analogs. Coordination Chemistry

Reviews, 2010. 254 (23-24): p. 2792-2847.

 3. Rio, Y .; Salomé Rodriguez-Morgade, M., Torres, T., Modulating the electronic properties of porphyrinoids: a voyage from the violet to the infrared regions of the electromagnetic spectrum. Organic & Biomolecular Chemistry, 2008. 6 (11): p. 1877-1894.

 4. Sorokin, A. B., Phthalocyanine Metal Complexes in Catalysis. Chemical Reviews, 2013. 13 (10): p. 8152-8191.

 5. Kudrevich, S. V., van Lier, J.E., Azaanalogs of phthalocyanine: syntheses and properties. Coordination Chemistry Reviews, 1996. 156: p. 163-182.

6. Nemykin, V. N., Lukyanets, E.A., Synthesis of substituted phthalocyanines. Arkivoc, 2010. 2010 (1): p. 136-208.

 7. Boston, D.R., Bailar, J.C., Phthalocyanine derivatives from 1,2,4,5-tetracyanobenzene or pyromellitic dianhydride and metal salts. Inorganic Chemistry, 1972. 11 (7): p. 1578-1583.

8. Nackiewicz, J., Kliber, M., Synthesis and selected properties of metallo and metal-free 2, 3, 9, 10, 16, 17, 23, 24-octacarboxy phthalocyanines. Arkivoc, 2015. 2015 (1): p. 269-299. 9. Shaposhnikov, GP; Maizlish, VE; Kulinich, VP, Carboxy-substituted Phthalocyanine Metal Complexes. Russ J Gen Chem, 2005. 75 (9): p. 1480-1488.

10. Shirai, H .; Maruyama, A .; Kobayashi, K .; Hojo, N., Urushido, K., Functional metal porphyrazine derivatives and their polymers, 4. Synthesis of poly (styrene) bonded Fe (III) - as well as Co (II) -4,4 ', 4 ", 4 "-tetracarboxyphthalocyanine and their catalase-like activity. Die Makromolekulare Chemie, 1980, 181 (3): p. 575-584.

1 1. Sakamoto, K., Ohno, E., Synthesis of cobalt phthalocyanine derivatives and their cyclic voltammograms. Dyes and Pigments, 1997, 35 (4): p. 375-386.

Claims

1 . METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, which provides for a first stage of formation of the metallocphthalocyanine ring, in which the reactants iron chloride (III) (FeC), urea ( CH ₄ N ₂ O), pyromellitic dianhydride and ammonium molybdate tetrahydrate (ΝΗ ₄ ) 6Μθ7θ24.4Η2θ), are intimately mixed and their temperature raised to 180 ° C in diphenylether, promoting the cyclization reaction, in which reaction are produced in addition to the precursor TI-FePc iron tetraimidophthalocyanine, various solid by-products, mainly iron oxide-hydroxides, molybdenum compounds and decomposition products of urea and diphenylether solvent; the process being characterized by providing a second purification step which removes most of the solid impurities generated in the first step; the purification step (second step) consists in treating the solid obtained in the first stage with a solution of hydrochloric acid to solubilize the organic and inorganic species, which are formed in the reaction medium, and during purification the precursor TI-FePc remains as solid; a third step in which the purified precursor TI-FePc is hydrolyzed with a solution of sodium hydroxide, at the end of which a solution of OC-FePc soluble in the reaction medium is obtained as a function of the eight negative charges; a fourth step, in which a calcium chloride solution is added as a precipitating agent enabling the separation of CaOC-FePc; the resulting solution containing sodium hydroxide is recovered via addition of sodium sulfate (Na 2 SO 4) to promote the precipitation and separation of the Ca ²⁺ ions in the form of CaSO 4 and the solution employed in the hydrolysis of the intermediate TI-FePc in the third step; and a fifth step consisting of acidification with hydrochloric acid and conversion of CaOC-FePc into the product HOC-FePc and recovery of acid solution for reuse in the second or fifth steps.

2. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the first step is a cyclization reaction step and formation of the intermediate iron tetraimidophthalocyanine (TI-FePc) in about 35% yield.

 3. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR USE IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the solid obtained in the fifth step of the process can be used as a functional pigment.

 4. METHOD-FTALOCYANIN CARBOXI PRODUCTION PROCESS FOR USE IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the hydrochloric acid solution employed in the fifth step is treated and reused for the purification of TI-FePc .

5. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that after the fourth step of the process, to obtain the carboxylic acid derivative HOC-FePc is made the substitution of Ca ²⁺ ions for H ⁺ , by reaction of solid CaOC-FePc with HCl solution, promoting their conversion to HOC-FePc; the desired product is separated from the calcium chloride acid solution which can be reused in this same Ca ²⁺ ion protonation / displacement step of another batch, or in the second purification step of the Tl-FePc intermediate, such solution being previously treated with sulfuric acid and the precipitate of CaSO 4 separated.

 6. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the sodium hydroxide solution employed in the fifth step is treated and reused for the hydrolysis of TI- FePc.

7. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the salt of iron (III) may be replaced by salts of other transition metals, rare earths and representative metals such as magnesium, zinc, nickel, cobalt, manganese, chromium, vanadium, cerium, neodymium, gadolinium, and metallocated carboxyphthalocyanines with the respective ions metallic.

8. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the catalyst ammonium molybdate tetrahydrate ((ΝΗ ₄ ) 6θθθθ 24.4Η²θ) can be replaced by (DBU), 1,5-diazabicyclo [4.3.0] non-5-ene (DBN) or other catalysts) and the pyromellitic dianhydride may be substituted by their derivatives or the trimellitic anhydride and its derivatives, generating the respective metallocated carboxyphthalicyclins.

 9. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the diphenylether solvent can be replaced by high-boiling solvents such as dimethylformamide, diethylformamide, nitrobenzene , 2-aminoethanol, diethanolamine, triethanolamine, ethylene glycol, diethyleneglycol, polyols, diallylesters of polyols, and polyethylene glycol dialkyl ether.

 CARBOXI PRODUCTION PROCESS FOR METALO-FTALOCYANINES FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the production process generates dyes and pigments of high purity.

 1 1. METHOD OF PRODUCTION OF CARBOXI METALO-FTALOCYANINS FOR EMPLOYMENT IN THE PRODUCTION OF COLORS AND PIGMENTS, according to claim 1, characterized in that the calcium salt used as precipitating agent can be substituted by representative, transition or earth metal salts metal hydroxides or mineral acids and organic acids to obtain insoluble products.