Abstract
Solubility of gas in polymers is an important physico-chemical property of foam materials and widely used in the preparation and modification of new materials. Under the conditions of high temperature and high pressure, the dissolution process is a nonlinear, non-equilibrium and dynamic process, so it is difficult to establish an accurate solubility calculation model. Inspired by particle dynamics and evolutionary algorithm, this paper proposes a hybrid model based on chaotic self-adaptive particle dynamics evolutionary algorithm (CSA-PD-EA), which can use the iterative process of particles in evolutionary algorithms at the dynamic level to simulate the mutual diffusion process of molecules during dissolution. The predicted solubility of supercritical CO2 in poly(d,l-lactide-co-glycolide), poly(l-lactide) and poly(vinyl acetate) indicated that the comprehensive prediction performance of the CSA-PD-EA model was high. The calculation error and correlation coefficient were, respectively, 0.3842 and 0.9187. The CSA-PD-EA model showed prominent advantages in accuracy, efficiency and correlation over other computational models, and its calculation time was 4.144–15.012% of that of other dynamic models. The CSA-PD-EA model has wide application prospects in the computation of physical and chemical properties and can provide the basis for the theoretical calculation of multi-scale complex systems in chemistry, materials, biology and physics.
Highlights
Solubility of supercritical CO2 in polymers is the key factor affecting the performance of foamed materials and widely used in the extraction and separation of various chemicals and the preparation and modification of new materials, displaying good prospects in theoretical research and application [1,2,3,4,5,6]
Particle dynamics refers to statistics of physical, chemical and mechanical properties of a system based on the motion state of each particle
This paper explored the evolution process of supercritical carbon dioxide particles and the density and radial distribution function (RDF) of polymer population
Summary
Solubility of supercritical CO2 in polymers is the key factor affecting the performance of foamed materials and widely used in the extraction and separation of various chemicals and the preparation and modification of new materials, displaying good prospects in theoretical research and application [1,2,3,4,5,6]. Our team had carried out related studies, including but not limited to the group evolution algorithm combined with the BP algorithm [39], clustering and diffusion theory and proposed several solubility prediction models of supercritical CO2 in polymers under several macroscopic scales in order to improve the local search speed [40,41]. These models achieved better results in calculation accuracy, efficiency, correlation and comprehensive performance. The innovation and contribution of this paper are summarized as follows. (i) Through combining 3 particle dynamics with evolutionary algorithms, a mixed model is proposed. (ii) In the model, the swarm evolution algorithm replaces various integral algorithms in traditional dynamics. (iii) This model has broad application prospects in multi-scale and dynamics calculation
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