个人简介
1995-1999 江苏科技大学,焊接专业 学士 1999-2006 中科院金属所,材料科学与工程专业 博士; 2006-2007 中科院物理所,凝聚态物理专业 博士后; 2007-2008 德国Ulm大学,微纳米技术研究所,博士后; 2009-今 兰州大学物理学院副教授。
近期论文
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1. P. Ding, J. Ma, H. Cao, Y. Liu, L.W. Wang*, J. Li, Melting of iron nanoparticles embedded in silica prepared by mechanical milling, Materials Science and Engineering B 178 (2013) 930. 2. P. Ding, H.F. Hou, S.X. Pu, H. Cao, L.W. Wang*, J. Li, Mechanochemical synthesis for studying the melting of metallic nanoparticles: a case study of copper, Philosophical Magazine Letters 95 (2015) 14. 3. L.M. Shen, H.F. Hou, C.Y. Yao, L.W. Wang*, Insignificant influence of the matrix on the melting of incoherently embedded tin and zinc nanoparticles, Journal of Physics: Condensed Matter 29 (2017) 035004. 4. Y.L. Lu, Y. Liu, Y.B. Xu, L.W. Wang, J. Li, Size-dependent melting of ice in mesoporous silica, Philosophical Magazine 93 (2013) 1827. 5. Y.B. Xu, Z.Y. Zhao, L.W. Wang, Insignificant influence of the matrix on the melting of ice confined in decorated mesoporous silica, Philosophical Magazine 98 (2018) 237. 1. L.W. Wang, L. Zhang, K. Lu, Vacancy-decomposition-induced lattice instability and its correlation with the kinetic stability limit of crystals, Philosophical Magazine Letters 85 (2005) 213. 2. L.W. Wang, Q. Wang, K.Q. Lu, Melting of superheated crystals initiated on vacancies, Philosophical Magazine Letters 87 (2007) 19. 3. L.W. Wang, Comment on "Melting dynamics of superheated argon: Nucleation and growth" [J. Chem. Phys. 126, 034505 (2007)], Journal of Chemical Physics 126 (2007) 187101. 4. L.W. Wang, Vacancy formation and squashing during surface melting and the size effect on surface-induced melting of metals, Philosophical Magazine 93 (2013) 3648. 5. L.W. Wang, H.-J. Fecht, A kinetic model for liquids: Relaxation in liquids, origin of the Vogel-Tammann-Fulcher equation, and the essence of fragility, Journal of Applied Physics 104 (2008) 113538. 6. L.W. Wang, J. Li, H.-J. Fecht, Single-exponential activation behavior behind the super-Arrhenius relaxations in glass-forming liquids, Journal of Physics: Condensed Matter 22 (2010) 455104. 7. L.W. Wang, J. Li, H.-J. Fecht, Correlating the stretched-exponential and super-Arrhenius behaviors in the structural relaxation of glass-forming liquids, Journal of Physics: Condensed Matter 23 (2011) 155102. 8. L.W. Wang, Extracting energy and structure properties of glass-forming liquids from structural relaxation time, Journal of Physics: Condensed Matter 24 (2012) 155103. 9. L.W. Wang, Thermodynamic cooperativity in glass-forming liquids: Indications and consequences, Journal of Non-Crystalline Solids 383 (2014) 59. 10. L.W. Wang, Probabilistic interpretation of liquid fragility, Journal of Non- Crystalline Solids 407 (2015) 161. 11. L.W. Wang, Atomistics of self-diffusion in liquid metals, EPJ Web of Conferences 151 (2017) 02004. 12. L.W. Wang, Estimating the Energy State of Liquids Metals, Metals 4 (2014) 570. 13. L.W. Wang, Melting point depression method for determining the solid–liquid interfacial energy of metal elements: theoretical validation and updated compilation of data, Philosophical Magazine Letters 97 (2017) 328.