SYNTHESIS OF AROMATIC POLYESTERS BASED ON NORBORNANE-CONTAINING DIOLS Текст научной статьи по специальности «Химические науки»

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SYNTHESIS OF AROMATIC POLYESTERS BASED ON

NORBORNANE-CONTAINING DIOLS

Givi Papava, Ia Chitrekashvili, Eter Gavashelidze, Marina

Gurgenishvili, Nora Dokhturishvili, Shalva Papava

Givi Papava, Ia Chitrekashvili, Eter Gavashelidze, Marina

Gurgenishvili, Nora Dokhturishvili, Shalva Papava. (2022)

Synthesis of Aromatic Polyesters Based on Norbornane-

Containing Diols. World Science. 4(76). doi:

10.31435/rsglobal_ws/30062022/7830

https://doi.org/10.31435/rsglobal_ws/30062022/7830 14 May 2022 11 June 2022 22 June 2022

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This work is licensed under a Creative Commons Attribution 4.0 International License.

© The author(s) 2022. This publication is an open access article.

SYNTHESIS OF AROMATIC POLYESTERS BASED ON NORBORNANE-CONTAINING DIOLS

Givi Papava, Professor, Doctor, Chief Scientific researcher

Ia Chitrekashvili, Doctor, Senior researcher

Eter Gavashelidze, Doctor, Senior researcher

Marina Gurgenishvili, Doctor, Chief Scientific researcher

Nora Dokhturishvili, Doctor, scientific worker

Shalva Papava, Doctor, Senior researcher

TSU Petre Melikishvili Institute of Physical and Organic Chemistry, Tbilisi, Georgia DOI: https://doi.org/10.31435/rsglobal_ws/30062022/7830 ARTICLE INFO ABSTRACT

Received: 14 May 2022 Aromatic polyesthers were synthesized on the base of

Accepted: 11 June 2022 policiclicbisphenols and dichloroanhydride of aromatic dicarboxylic acid

Published: 22 June 2022 by the method of equilibrium polycondensation in solvent. The obtained

- polymers are characterized by high heat-and thermal stability, are well

KEYWORDS soluble in chlorinated hydrocarbons and they form transparent films from

solutions which are characterized by good mechanical and dielectric

Aromatic, Polyester, Bisphenol, properties.

Dichloroanhydride, Polycondensation properties.

Macromolecule, Films, Fibres, Plasticity, Flexibility.

Citation: Givi Papava, Ia Chitrekashvili, Eter Gavashelidze, Marina Gurgenishvili, Nora Dokhturishvili, Shalva Papava. (2022) Synthesis of Aromatic Polyesters Based on Norbornane-Containing Diols. World Science. 4(76). doi: 10.31435/rsglobal_ws/30062022/7830

Copyright: © 2022 Givi Papava, Ia Chitrekashvili, Eter Gavashelidze, Marina Gurgenishvili, Nora Dokhturishvili, Shalva Papava. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) or licensor are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

Introduction.

Development of a series of branches of new technology, such as space engineering, aviation, rocket technology, radio electronics and others ask for the creation of new type materials, which should preserve high strength at strict conditions of exploitation at high temperature, at high mechanical charges. With this in view the polymers, which are characterized by high heat- and thermal resistance, high strength and other significant indices are most interesting.

As has been shown by the researches, with the view of heat- and thermal stability, the polymers with macromolecules which contain aromatic and heterocyclic rings are most perspective materials, but because of high rigidity of recurrent cycles of such polymers, often it becomes impossible to use them for obtaining films, fibres and other articles, where materials must possess high plasticity, flexibility, high dielectric and other specific properties. General method to obtain such polymers is creation of the polymers, macromolecules of which, together with aromatic and heterocyclic rings would contain relatively more flexible groups such as ester, ether and the like bonds; creation of such macromolecules can be achieved either in the process of polymer synthesis, when such bonds are formed in the reaction process, e.g. polyarylates, polyimides, epoxy, silicium-containing or other polymers, or by inculcation of such fragments into polymer chain by the use of the monomers, which contain such groups. With this in view the so-called card-type polymers are perspective polymers, which in their recurrent ring contain side cyclic groups, one of the atoms of which simultaneously is in the composition of a macromolecule structure. Presence of such groups grants specific properties to the polymers, when high thermal stability of a polymer is fused with its good solubility [1-4]. It is especially important for aromatic heterocyclic polymers of rigid structure,

when softening temperature of such polymers is close, or even is higher than polymer destruction temperature, which, of course complicates the process of obtaining articles from such materials.

Considering the above stated the card-type polymers, aromatic polyimides, polyamides, polyoxazoles, which in their polymer chain contain phthalide, norbornane and the like card-type groups they become important [5,6].

In special literature there are rather scarce data about the polymers, which contain norbornane type card groups, which are very interesting because of their original spatial structure, creating closed three-dimensional, volumetric cycles. Such structure distinguishes them from other card groups. This is why it was expected that for building macromolecules, it would be interesting and perspective to use the monomers, which as substituted groups contain norbornane type and other cyclic groups characterised by non -coplanar structure.

Materials and Methods.

For obtaining of heterochain polymers we used the norbornane type monomers, which contain biatomic phenols in which phenol hydroxyl groups were in various nuclei of benzol. In their synthesis we used the easily accessible material such as wastes of gas and petroleum treatment.

For the synthesis of polymers we used the following norbornane type polycyclic bisphenols:

4,41-(2-norbornyliden)diphenol;

4,41-(2-norbornyliden)di-ortho-cresol;

4,41-(-(2-norbornyliden)bis-2-chlorophenol;

4,41-(hexahydro-4,7-methylenindan-5-yliden)diphenol;

4,41-(hexahydro-4,7-methylenindan-5-yliden)-di-ortho-cresol;

4,41-(hexahydro-4,7-methylenindan-5-yliden)bis-2-chlorophenol;

4,41-(decahydro-1,4,5,8-dimethylennaft-2-yliden)-di-ortho-cresol;

4,41-(decahydro-1,4,5,8-dimethylennaft-2-yliden)-bis-2-chlorophenol.

As an acid component we used 4,41-(diphenyldicarboxylic acid dichloroanhydride. Synthesis of polymers was performed by the method of equilibrium polycondensation in ditolylmethane. Properties of the synthesized polymers are given in Table 1.

Results and Discussion.

IR- spectroscopic studies of the synthesized polymers showed an absorption band in the 1770 cm-1 zone in IR spectrum, which is characteristic for polymer ester groups and an absorption band in the 1460 cm-1 zone, which is characteristic for bisphenol lCH2 groups.

As is seen from the data of Table #1 the polymers obtained on the base of polycyclic bisphenols and aromatic dicarboxylic acid are characterized by high thermal stability. High softening temperature of the polymers is explained by high rigidity of polymer chain, which is conditioned by non-coplanarity of norbornane type cycles. These cycles have significant dimensions in all directions. This is why these groups are not capable to orientate in any definite direction, hence they can't move in a small space between macromolecules similar to that taking place in case of alkyl or phenyl groups. By the same reason free circulation of two phenyl groups which are linked to norbornane cycle carbon atom is complicated. Due to the fact that the polymer softening and melting temperatures are associated with movement of certain definite zones of macromolecules towards each other, presence of non-coplanar polycyclic structure in polymer recurring ring conditions high softening temperature of polymers.

Polymer thermal stability was investigated by the method of thermogravimetric analysis, at heating on air (sample heating velocity - 4,5o/min). As is seen from the data of Table #1, polymers are characterized by high thermal stability. Decrease of their mass at heating on air commences above 300-400 o C. Especially high heat resistance is inherent to the polymers obtained on the base of chlorine substituted bisphenols, destruction of which (for example polymers 16 and 20) commences only at 470-480oC.

As has been shown by the studies polyarylates which contain the polycyclic bisphenols are characterized by high resistance to water. Films prepared on the base of these polymers are characterized also by high resistance to 20% sodium alkaline solution and to ultraviolet rays. At the long-term impact of ultraviolet rays polymers factually remain unchanged. Chlorine containing polymers are characterized also by refractory properties.

Table 1. Properties of polyesters obtained in solvent by equilibrium polycondensation

№ P Structure of polymer recurring ring Decrease of polymer mass at heating on air Yield, % 0.5% polymer solution in chloroform «20. . y finished, dl./g Softening temperature, 0C Polymer structure according to X-ray diffraction analysis

start by 10% by 5% in capillary according to thermo mechanical curves

1 2 3 4 5 6 7 8 9 10

1 -ocV^V w wco° ^A/wo 366 410 535 80 0,65 330-345 220 Amorphous

2 -oc-^V w ch3 /ch3 O^/O ch 1 0 360 380 510 80 0,50 339-340 227 Amorphous

3 -oc-^V w O^/O ch -/\./ch3 365 400 525 80 0,65 345-360 235 Amorphous

4 -oc-^V oc w ch3 ^ch3 O^^/CK 360 365 510 70 0,70 340-352 245 Amorphous

5 -oc-Q- O-^/O Q 370 415 540 90 0,52 345-350 250 Amorphous

6 -oc-Q- ch3 O-^/O Q 370 400 515 70 0,55 320-330 290 Amorphous

7 -oo-^V w w-^/O-8 450 480 560 85 0,48 355-360 305 Amorphous

8 -oc-Q- ch3 ö-^/ö- 435 440 500 94 0,40 345-355 300 Amorphous

9

450 510 580 94 0,40 360-365 325 Amorphous

10 ch3 -O-O-i^O-

ch3 445 490 500 80 0,88 340-345 320 Amorphous

Conclusions.

Heterochain polyesters were synthesized on the base of polycyclicbishenols and dichloroanhydride of dicarboxylic acid by the use of equilibriumpolycondensation method. The obtained polymers are characterized by high heat- and thermal stability, are well soluble in chlorinated hydrocarbons. In solutions they form transparent films, which are characterized by good mechanical and dielectric properties.

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