吉布斯-汤姆森方程

B. Cantor
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摘要

材料的外表面具有不同于本体材料的原子或分子结构。材料内部的任何界面也是如此。正因为如此,正如吉布斯-汤姆森方程所描述的那样,材料或其中任何颗粒或粒子的能量随着其边界表面的曲率而增加。本章解释了表面如何控制新相的成核,如凝固和沉淀反应,热处理过程中颗粒的粗化和生长,晶体的平衡形状,以及溶质和杂质的表面吸附和偏析。早在吉布斯-汤姆逊方程之前,就有许多相关的方程;尚不清楚它是以j.j.汤姆森还是威廉·汤姆森(开尔文勋爵)的名字命名的;直到吉布斯、汤姆逊和开尔文之后,它才变成了现在通常的形式。j·j·汤姆森是剑桥大学第三任卡文迪什物理学教授。他发现了电子,这对世界产生了深远的影响,特别是托马斯·爱迪生发明了灯泡,随后建立了世界上第一个配电网络。威廉·汤姆森是格拉斯哥大学自然哲学教授。他取得了重大的科学进展,特别是在热力学方面,他帮助建造了第一条跨大西洋海底电报。由于他在科学上的卓越成就,温度的绝对单位开尔文就是以他的名字命名的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Gibbs-Thomson Equation
The external surface of a material has an atomic or molecular structure that is different from the bulk material. So does any internal interface within a material. Because of this, the energy of a material or any grain or particle within it increases with the curvature of its bounding surface, as described by the Gibbs-Thomson equation. This chapter explains how surfaces control the nucleation of new phases during reactions such as solidification and precipitation, the coarsening and growth of particles during heat treatment, the equilibrium shape of crystals, and the surface adsorption and segregation of solutes and impurities. The Gibbs-Thomson was predated by a number of related equations; it is not clear whether it is named after J. J. Thomson or William Thomson (Lord Kelvin); and it was not put into its current usual form until after Gibbs’, Thomson’s and Kelvin’s time. J. J. Thomson was the third Cavendish Professor of Physics at Cambridge University. He discovered the electron, which had a profound impact on the world, notably via Thomas Edison’s invention of the light bulb, and subsequent building of the world’s first electricity distribution network. William Thomson was Professor of Natural Philosophy at Glasgow University. He made major scientific developments, notably in thermodynamics, and he helped build the first trans-Atlantic undersea telegraph. Because of his scientific pre-eminence, the absolute unit of temperature, the degree Kelvin, is named after him.
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