Abstract
Two formulae were developed to express sublimation enthalpy and Young’s modulus on a thermodynamic basis. The first formula reveals how the sublimation enthalpy is correlated with the thermal expansion coefficient and heat capacity of solids, whereas the second formula relates the Young’s modulus with sublimation enthalpy and equilibrium interatomic (intermolecular) distance. While the formulae themselves divulge the physical nature of the macroscopic properties such as sublimation enthalpy, coefficient of thermal expansion and Young’s modulus, these two formulae provide alternative ways to quantitatively estimate thermodynamic or mechanical properties of great importance in the development of new materials. Built upon these formulae, the effective connection among mechanical, thermodynamic properties along with the microscopic feature, the interatomic potential, was found fairly useful in the areas such as medicinal designing, environmental research, evaluation of the contamination in specific, and the development of lithium ion batteries, superconducting and even architectural materials, wherein either thermodynamic or mechanical properties or both are imperative.
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Notes
According to Moore and Sward, the first known mention of this game was contained in the book Wuzazu by the Chinese Ming-dynasty writer Xie Zhaozhi; he wrote that the game—called shoushiling—had origin back to the time of the Han dynasty (206 BC–220 AD). The game is also mentioned in the book Note of Liuyanzhai by Li Rihua. See Moore, M. E.; Sward, J. “Introduction to the game industry” (2006) Upper Saddle River, NJ: Pearson Prentice Hall. p. 535.
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The authors are grateful to Ms Meruyert Mukhitkyzy for her helpful bibliographic research. EB thanks the Fund from Bingtuan Oasis at Shihezi University (Xinjiang, China). HF thanks Nazarbayev University small Grant 110119FD4542.
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Benassi, E., Fan, H. Thermodynamic properties, mechanical properties and interatomic potential in solids: a Shou-Shi-Ling ( ) game. Continuum Mech. Thermodyn. 33, 639–652 (2021). https://doi.org/10.1007/s00161-020-00935-8
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DOI: https://doi.org/10.1007/s00161-020-00935-8