Theory of the structural glass transition: a pedagogical review

IF 35 1区 物理与天体物理 Q1 PHYSICS, CONDENSED MATTER
V. Lubchenko
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引用次数: 52

Abstract

The random first-order transition theory of the structural glass transition is reviewed in a pedagogical fashion. The rigidity that emerges in crystals and glassy liquids is of the same fundamental origin. In both cases, it corresponds with a breaking of the translational symmetry; analogies with freezing transitions in spin systems can also be made. The common aspect of these seemingly distinct phenomena is a spontaneous emergence of the molecular field, a venerable and well-understood concept. In crucial distinction from periodic crystallisation, the free energy landscape of a glassy liquid is vastly degenerate, which gives rise to new length and time scales while rendering the emergence of rigidity gradual. We obviate the standard notion that to be mechanically stable a structure must be essentially unique; instead, we show that bulk degeneracy is perfectly allowed but should not exceed a certain value. The present microscopic description thus explains both crystallisation and the emergence of the landscape regime followed by vitrification in a unified, thermodynamics-rooted fashion. The article contains a self-contained exposition of the basics of the classical density functional theory and liquid theory, which are subsequently used to quantitatively estimate, without using adjustable parameters, the key attributes of glassy liquids, viz., the relaxation barriers, glass transition temperature, and cooperativity size. These results are then used to quantitatively discuss many diverse glassy phenomena, including the intrinsic connection between the excess liquid entropy and relaxation rates, the non-Arrhenius temperature dependence of α-relaxation, the dynamic heterogeneity, violations of the fluctuation-dissipation theorem, glass ageing and rejuvenation, rheological and mechanical anomalies, super-stable glasses, enhanced crystallisation near the glass transition, the excess heat capacity and phonon scattering at cryogenic temperatures, the Boson peak and plateau in thermal conductivity, and the puzzling midgap electronic states in amorphous chalcogenides.
结构玻璃化转换理论:教学回顾
以教学的方式回顾了结构玻璃跃迁的随机一阶跃迁理论。在晶体和玻璃状液体中出现的刚性具有相同的基本起源。在这两种情况下,它都对应于平动对称性的破坏;也可以用自旋系统中的冻结跃迁作类比。这些看似不同的现象的共同之处是分子领域的自发出现,这是一个值得尊敬和很好理解的概念。与周期性结晶的关键区别是,玻璃状液体的自由能景观是巨大的简并,这产生了新的长度和时间尺度,同时使刚性逐渐出现。我们摒弃了这样的标准观念:一个结构要具有机械稳定性,就必须在本质上是唯一的;相反,我们表明体积简并是完全允许的,但不应超过某个值。因此,目前的微观描述以一种统一的、基于热力学的方式解释了结晶和玻璃化后景观制度的出现。这篇文章包含了经典密度泛函理论和液体理论基础的独立阐述,随后用于定量估计玻璃状液体的关键属性,即弛豫势垒、玻璃化转变温度和协同度大小,而不使用可调参数。这些结果随后被用于定量讨论许多不同的玻璃化现象,包括过量液体熵和弛豫率之间的内在联系,α-弛豫的非arrhenius温度依赖性,动态非均质性,涨落耗散定理的违反,玻璃老化和返老返老,流变和机械异常,超稳定玻璃,玻璃化转变附近的增强结晶,超低温下的过剩热容量和声子散射,导热系数中的玻色子峰和平台,以及非晶硫族化合物中令人困惑的间隙电子态。
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来源期刊
Advances in Physics
Advances in Physics 物理-物理:凝聚态物理
CiteScore
67.60
自引率
0.00%
发文量
1
期刊介绍: Advances in Physics publishes authoritative critical reviews by experts on topics of interest and importance to condensed matter physicists. It is intended for motivated readers with a basic knowledge of the journal’s field and aims to draw out the salient points of a reviewed subject from the perspective of the author. The journal''s scope includes condensed matter physics and statistical mechanics: broadly defined to include the overlap with quantum information, cold atoms, soft matter physics and biophysics. Readership: Physicists, materials scientists and physical chemists in universities, industry and research institutes.
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