The Method of Direct and Reverse Phase Portraits As a Tool for Systematizing the Results of Studies of Phase Transitions in Solutions of Thermosensitive Polymers

Overview

Journal Gels

Date 2024 Jun 26

PMID 38920941

Authors

Akhat Bakirov

Eldar Kopishev

Kaisarali Kadyrzhan

Elvira Donbaeva

Aigerim Zhaxybayeva

Marat Duisembiyev

Faiziya Suyundikova

Ibragim Suleimenov

Affiliations

Soon will be listed here.

Abstract

It is shown that a more than significant amount of experimental data obtained in the field of studying systems based on thermosensitive hydrophilic polymers and reflected in the literature over the past decades makes the issue of their systematization and classification relevant. This, in turn, makes relevant the question of choosing the appropriate classification criteria. It is shown that the basic classification feature can be the number of phase transition stages, which can vary from one to four or more depending on the nature of the temperature-sensitive system. In this work, the method of inverse phase portraits is proposed for the first time. It was intended, among other things, to identify the number of phase transition stages. Moreover, the accuracy of this method significantly exceeds the accuracy of the previously used method of direct phase portraits since, for the first time, the operation of numerical differentiation is replaced by the operation of numerical integration. A specific example of the application of the proposed method for the analysis of a previously studied temperature-sensitive system is presented. It is shown that this method also allows for a quantitative comparison between the results obtained by the differential calorimetry method and the turbidimetry method. Issues related to increasing the resolution of the method of direct phase portraits are discussed.

Citing Articles

Advanced Applications of Polymer Hydrogels in Electronics and Signal Processing.

Suleimenov I, Gabrielyan O, Kopishev E, Kadyrzhan A, Bakirov A, Vitulyova Y Gels. 2024; 10(11).

PMID: 39590071 PMC: 11593912. DOI: 10.3390/gels10110715.

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