Prof. Lihong Liang,
Female,
Ph. D, Professor,
College of Mechanical and Electrical Engineering, Beijing University of Chemical Technology, Beijing 100029, China
Chaoyang District, Beijing City
Research field:
She is interested in mechanical and related physical properties of micro/nanomaterials, and studied systematically the melting thermodynamics of nanocrystals, the size-dependent lattice strain of nanocrystals, the elastic modulus of thin films, the size effect of interface energy, and the thermal conductivity of nanosolids.
She published more than 50 SCI papers in some international journals in material physics field, such as Physical Review B, Applied Physics Letter, Nanotechnology, etc., these papers were SCI cited about 800 times by other groups. She was invited to review some papers in Philosophical Magazine, Journal of Crystal Growth, Journal of Nanomaterials, etc.
Education Experience (time reverse order):
2000.03-2003.03, Jilin University, Materials Science, Ph. D.
1997.09-2000.03, Jilin University of Technology, Materials Science, Master
1993.09-1997.07, Jilin Institute of Technology, Materials Science, Bachelor
Work Experience:
2019.07- , College of Mechanical and Electrical Engineering, Beijing University of Chemical Technology
2007.07-2019.07, Institute of Mechanics, Chinese Academy of Sciences, Assistant Professor, Associate Professor(2007.12-)
2005.03-2007.07, Department of Physics, National University of Singapore, Research Fellow
2003.03-2005.03, Institute of Physics, Chinese Academy of Sciences, Postdoctor
SCI paper list (one part):
1. X. You, L. H. Liang, Y. Wei, “The atomistic simulation study of Ag/MgO interface tension fracture”, Computational Materials Science, 142 (2017) 277.
2. H. Liu, Y. Wei, L. H. Liang, et al., “Damage characterization model of ceramic coating systems based on energy ****ysis and bending tests”, Ceramics International, 44(2018) 4807.
3. J. Song, C. Fan, H. Ma, L. H. Liang, Y. Wei, “Crack deflection occurs by constrained microcracking in nacre”, Acta Mechanica Sinica, 34 (2018) 143.
4. L. H. Liang, X. N. Li, H. Y. Liu, Y. B. Wang, Y. G. Wei, “Power-law characteristics of damage and failure of ceramic coating systems under three-point bending”, Surface & Coatings Technology, 285 (2016) 113. (SCI. EI) cite 2, 1
5. H.Y. Liu, L.H. Liang, Y.B. Wang, Y.G. Wei, Fracture characteristics and damage evolution of coating systems under four-point bending, International Journal of Applied Ceramic Technology, 13(6) (2016) 1043-1052.
6. L. H. Liang, X. N. Li, Y. G. Wei, H. Wei, “The Mechani** of High Thermal Shock Resistance of Nanostructured Ceramic Coatings”, International Journal of Applied Ceramic Technology, 12 (2015) 1096-1102.
7. X. N. Li, L. H. Liang, J. J. Xie, L. Chen, Y. G. Wei, “Thickness-dependent fracture characteristics of ceramic coatings bonded on the alloy substrates”, Surface & Coatings Technology, 258 (2014) 1039.
8. L. H. Liang, H. Wei, X. C. Chang, W. Xu, X. N. Li, Y. G. Wei, “Enhanced insulation temperature and the reduced thermal conductivity of nanostructured ceramic coating systems”, International Journal of Heat and Mass Transfer65 (2013) 219.
9. L. H. Liang, H. Wei, X. N. Li, Y. G. Wei, “Size-dependent interface adhesive energy and enhanced interface strength of nanostructured systems”, Surface & Coatings Technology236 (2013) 525.
10. L. H. Liang, M. Z. Li, F. Q. Qin, Y. G. Wei, “Temperature effect on elastic modulus of thin films and nanocrystals”, Philosophical Magazine9 (2013) 574.
11. L. H. Liang, H. S. Ma, Y. G. Wei, “Size-Dependent Elastic Modulus and Vibration Frequency of Nanocrystals”, Journal of Nanomaterials2011 (2011) 670857.
12. L. H. Liang, X. M. You, H. S. Ma, Y. G. Wei, “Interface energy and its influence on interface fracture between metal and ceramic thin films in nanoscale”,Journal of Applied Physics 108 (2010) 084317.
13. S. Yang, W. Xu, L. H. Liang, T. C. Wang, Y. G. Wei, “An experimental study on the dependence of the strength of adhesively bonded joints with thickness and mechanical properties of the adhesives”, Journal of Adhesion Science and Technology, 28 (2014) 1055.
14. J. R. Song, J. Y. Liu, H. S. Ma, L. H. Liang, Y. G. Wei, “Determinations of both length scales and surface elastic parameters for fcc metals”, Comptes Rendus Mecanique, 342 (2014) 315.
15. L. H. Liang, Y. G. Wei, B. W. Li, “Size-dependent interface phonon tran**ission and thermal conductivity of nanolaminates”, Journal of Applied Physics 103 (2008) 084314.
16. L. H. Liang and B. W. Li, “Size-dependent thermal conductivity of nanoscale semiconducting systems”, Physical Review B 73 (2006) 153303.
17. L. H. Liang, F. Liu, D. X. Shi, W. M. Liu, X. C. Xie, H. J. Gao, “Nucleation and reshaping thermodynamics of Ni as catalyst of carbon nanotubes”, Physical Review B 72 (2005) 035453.
18. B. Wu, L. H. Liang, H. S. Ma, Y. G. Wei, “A trans-scale model for size effects and intergranular fracture in nanocrystalline and ultra-fine polycrystalline metals”, Computational Materials Science 57 (2012) 2.
19. X. L. Chen, H. S. Ma, L. H. Liang, Y. G. Wei, “A surface energy model and application to mechanical behavior ****ysis of single crystals at sub-micron scale”, Computational Materials Science 46 (2009) 723.
20. L. H. Liang, Y. G. Wei, B. W. Li, “Thermal conductivity of composites with nanoscale inclusions and size-dependent percolation”, Journal of Physics: Condensed Matter 20 (2008) 365201.
21. L. H. Liang and B. W. Li, “Size-dependent melting temperature and thermal conductivity of nanoscale semiconductors”, International Journal of Modern Physics B 21 (2007) 4026.
22. G. Ouyang, L. H. Liang, C. X. Wang, and G. W. Yang, “Size-dependent interface energy”, Applied Physics Letter 88 (2006) 091914.
23. L. H. Liang, G. W. Yang, B. W. Li, “Size-dependent formation enthalpy of nanocompounds”, Journal of Physical Chemistry B 109 (2005) 16081.
24. L. H. Liang, C. M. Shen, S. X. Du, W. M. Liu, X. C. Xie, H. J. Gao, “Increase in thermal stability induced by organic coatings on nanoparticles”, Physical Review B 70 (2004) 205419.
25. L. H. Liang, C. M. Shen, X. P. Chen, W. M. Liu, H. J. Gao, “The size-dependent phonon frequency of semiconductors nanocrystals”, Journal of Physics: Condensed Matter 16 (2004) 267.
26. Q. Jiang, L. H. Liang, J. C. Li, “Thermodynamic superheating of low-dimensional metals embedded in a matrix”, Vacuum 72 (2004) 249.
27. L. H. Liang, D. Liu, Q. Jiang, “Size-dependent continuous solution phase diagram of binary system”, Nanotechnology 14 (2003) 438.
28. L. H. Liang, J. C. Li, Q. Jiang, “Size-dependent melting depression and lattice contraction of Bi nanocrystals”, Physica B 334 (2003) 49.
29. L. H. Liang, J. C. Li, Q. Jiang, “Modeling of melting enthalpy of organic nanowires”, Physics Status Solidi B 236 (2003) 583.
30. L. H. Liang, J. C. Li, Q. Jiang, “Size-dependent elastic modulus of Cu and Au thin films”, Solid State Communications 121 (2002) 453.
31. L. H. Liang, M. Zhao, Q. Jiang, “Melting enthalpy depression of nanoparticles based on surface effect”, Journal of Materials Science Letter 21 (2002) 1843.
32. L. H. Liang, J. C. Li, Q. Jiang, “Superheating thermodynamics of nanocrystals based on the interface effect”, Physica B 322 (2002) 188.
33. Q. Jiang, L. H. Liang, D. S. Zhao, “Lattice contraction and surface stress of fcc nanocrystals”, Journal of Physical Chemistry B 105 (2001) 6275. (SCI他引39次)。
34. Q. Jiang, L. H. Liang, J. C. Li, “Thermodynamic superheating and relevant interface stability of low-dimensional metallic crystals”, Journal of Physics: Condensed Matter 13 (2001) 565.
35. Q. Jiang, L. H. Liang, M. Zhao, “Modeling of the melting temperature of nano-ice in MCM-41 pores”, Journal of Physics: Condensed Matter 13 (2001) L397.