颗粒介质的结构及热力学

孙其诚

doi:10.7498/aps.64.076101

摘要

颗粒介质具有远程无序和近程有序的结构, 是产生动力学不均匀性(dynamical heterogeneity) 和复杂不可逆过程的根源. 本文分析了颗粒介质的结构特征、变形和能量耗散之间的内在关联, 讨论了颗粒介质的弹性, 提出了流变应变增量、耦合应变增量和弹性应变增量的应变增量分解方式. 沿用非平衡热力学框架, 引入表征运动无序的动理学颗粒温度Tk和表征弹性应力涨落的构型温度Tc, 作为非平衡态变量, 建立了双颗粒温度热力学(two-granular-temperature thermodynamics, TGT理论), 注重分析了不可逆过程中的热力学力和流, 并与著名的砂土内变量热力学进行了对比.

关键词:

Abstract

Granular materials posses disorder structures which are the origin of dynamical heterogeneity. On the basis of non-equilibrium thermodynamics, the structure characteristics, complex deformations, and energy dissipations are analysed. Based on the photoelastic tests, the granular elasticity is discussed. The strain increments are classified into three categories. By means of the non-equilibrium thermodynamics, two granular temperatures, Tk, Tc, are introduced as the state variables, which denote the fluctuations of the kinetic energy and the elastic energy, respectively. Further, a two-granular-temperature thermodynamics (i.e. TGT theory) are developed for granular materials. The thermodynamic forces and fluxes are particularly analyzed. TGT theory is also compared with the previous internal variable thermodynamics for sands (IVT theory) developed a few decades ago. It is found that from TGT the Gibbs free energy in the IVT theory can be deduced, and the energy dissipation function can be apparently expressed from TGT theory.

Keywords:

作者及机构信息

孙其诚

1.
清华大学水沙科学与水利水电工程国家重点实验室, 北京 100084

基金项目: 国家自然科学基金(批准号: 11034010, 11272048, 51239006)、欧盟Marie Curie 国际合作项目(批准号: IRSES-294976)和清华大学自主科研计划资助的课题.

Authors and contacts

Sun Qi-Cheng

1.
State Key Laboratory of Hydroscience and Engineering, Tsinghua University, Beijing 100084, China

Funds: project supported by the National Natural Science Foundation of China(11034010, 11272048, 51239006), European Commission Marie Curie Actions(IRSES-294976) and Tsinghua University Initiative Scientific Research Program

参考文献

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[13]	Sun Q, Jin F, Zhou G D 2013 Granular Mat. 15 119
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施引文献

[1]	Einstein A 1956 Investigations on the theory of the Brownian movement (New York: Dover)
[2]	Ogawa S, Umemura A, Oshima N 1980 ZAMP 31 483
[3]	Haff P K 1983 J Fluid Mech. 134 401
[4]	Lun C K K, Savage S B, Jeffrey D J, Chepurniy N 1984 J. Fluid Mech. 140 223
[5]	Jenkins J T, Savage S B 1983 Granular Mat. 130 187
[6]	Babic M, Shen H H 1989 J. Eng. Mech. 115 1262
[7]	Edwards S F, Oakeshott R B S 1989 Physica A 157 1080
[8]	Henkes S, O‘Hern C S, Chakraborty B 2007 Phys. Rev. Lett. 99 038002
[9]	Tighe B P, Vlugt T J H 2011 J. Stat. Mech. P04002
[10]	Tighe B P, Snoeijer J H, Vlugtc T J H, van Hecke M 2010 Soft Mat. 6 2908
[11]	Bi Z, Sun Q, Jin F 2011 Granular Mat. 13 503
[12]	Sun Q, Song S, Liu J, Fei M, Jin F 2013 Theoret. Appl. Mech. Lett. 3 021008
[13]	Sun Q, Jin F, Zhou G D 2013 Granular Mat. 15 119
[14]	Onsager L 1931 Phys. Rev 37 405
[15]	Prigogine I 1961 Introduction to Thermodynamics of Irreversible Processes (New York: Interscience)
[16]	Jou D, Casas-Vazquez J, Lebon G 2010 Extended Irreversible Thermodynamics (4th Ed.) (Berlin: Springer)
[17]	Ottinger H C 2005 Beyond Equilibrium Thermodynamics (New York:: Wiley-Interscience)
[18]	Collins I F, Houlsby G T 1997 Proceed. Royal Soc. A 453 1975
[19]	Houlsby G T, Puzrin A M 2007 Principles of Hyperplasticity: An Approach to Plasticity Theory Based on Thermodynamic Principles (Berlin: Springer)
[20]	Xu N 2011 Front. Phys. 6 109
[21]	Jiang Y M, Liu M 2009 Granular Mat. 11 139
[22]	Liu Z Y, Yang Y 2012 Intermetallics 26 86
[23]	Landau L D, Lifshitz E M 1986 Theory of Elasticity (3rd Ed.) (Butterworth-Heinemann)
[24]	Rice J R 1971 J. Math Phys. Solids 19 433
[25]	Jenkins J T 2006 Phys. Fluids 18 103307
[26]	Wang W H 2012 Prog. Mater. Sci. 57 487

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