Nonlinear Theory of the Growth of New Phase Particles in Supercooled Metal Melts

IF 0.7 4区化学 Q4 CHEMISTRY, PHYSICAL

Russian Journal of Physical Chemistry A Pub Date : 2024-10-28 DOI:10.1134/S0036024424701619

M. V. Dudorov, A. D. Drozin, V. E. Roshchin, G. P. Vyatkin

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Abstract

A new variational theory of the growth of particles of a new phase in supercooled multicomponent melts is developed. The crystallization of supercooled metal melts is characterized by various nonlinear effects on the surface of a growing crystal. A new variational means of nonequilibrium thermodynamics is developed to consider such effects, based on the principle of minimum entropy production. The approach allows the growth of an embryo of a new phase to be considered by allowing for the interrelated influence of thermal and diffusion processes, along with non-stationary effects associated with deviations from the local equilibrium on the surface of the growing embryo. The transfer of components across the phase boundary is described in the form of chemical reactions. An advantage of the theory is the possibility of obtaining a generalized theoretical description of nonlinear effects on the crystal’s surface. Expressions of crystal growth are given for different types of multicomponent metal systems to demonstrate the use of the approach.

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过冷金属熔体中新相粒子生长的非线性理论

提出了过冷多组分熔体中新相颗粒生长的新变分理论。过冷金属熔体结晶的特点是晶体生长表面的各种非线性效应。根据最小熵产生原理，开发了一种新的非平衡热力学变分方法来考虑这种效应。这种方法允许考虑热和扩散过程的相互影响，以及与偏离生长胚表面局部平衡有关的非稳态效应，从而考虑新相胚的生长。以化学反应的形式描述了跨相界的成分转移。该理论的一个优点是可以对晶体表面的非线性效应进行广义的理论描述。我们给出了不同类型多组分金属体系的晶体生长表达式，以演示该方法的应用。

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来源期刊

Russian Journal of Physical Chemistry A 化学-物理化学

CiteScore

1.20

自引率

14.30%

发文量

376

审稿时长

5.1 months

期刊介绍： Russian Journal of Physical Chemistry A. Focus on Chemistry (Zhurnal Fizicheskoi Khimii), founded in 1930, offers a comprehensive review of theoretical and experimental research from the Russian Academy of Sciences, leading research and academic centers from Russia and from all over the world. Articles are devoted to chemical thermodynamics and thermochemistry, biophysical chemistry, photochemistry and magnetochemistry, materials structure, quantum chemistry, physical chemistry of nanomaterials and solutions, surface phenomena and adsorption, and methods and techniques of physicochemical studies.