CALPHAD modeling of molar volume

Databases concerning basic physical properties of materials, such as molar volume, density, thermal expansion coefficient, elastic constants, thermal conductivity, etc., are essential parts of the underlying knowledge for materials design. While thermodynamic databases provide chemical driving force...

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Bibliographic Details
Published in:Chinese science bulletin 2014-05, Vol.59 (15), p.1646-1651
Main Authors: He, Yan-Lin, Lu, Xiao-Gang, Zhu, Na-Qiong, Sundman, Bo
Format: Article
Language:English
Subjects:
atmospheric pressure
Chemistry/Food Science
Computer simulation
Earth Sciences
Elastic constants
energy
Engineering
Humanities and Social Sciences
Life Sciences
Mathematical models
melting point
microstructure
Molar volume
multidisciplinary
Phase transformations
phase transition
Physical properties
Physics
Progress
Science
Science (multidisciplinary)
thermal conductivity
Thermal expansion
属性数据库
摩尔体积
材料设计
热力学数据库
物理性质
相图计算
相平衡数据
计算模型
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Summary:Databases concerning basic physical properties of materials, such as molar volume, density, thermal expansion coefficient, elastic constants, thermal conductivity, etc., are essential parts of the underlying knowledge for materials design. While thermodynamic databases provide chemical driving forces and phase equilibrium data, physical property databases provide essential physical parameters, such as volume, lattice constant, lattice misfit, elastic energy, interfacial energy, etc., for phase transformation and microstructure simulations. Combined with thermodynamic databases, physical property databases established on the basis of the calculation of phase diagram (CALPHAD) method can be used to calculate physical properties together with phase equilibria, phase fractions, phase compositions, and thermodynamic properties for multi-component and multi-phase material systems and for the constituent phases. In this paper, we will discuss in detail various volume models based on the CALPHAD method which are capable of describing experimental data in a wide range from cryogenic temperatures to melting points, from the atmospheric pressure to high pressures for pure substances as well as multi-component and multi-phase materials.
ISSN:1001-6538
1861-9541
DOI:10.1007/s11434-014-0218-5