梁 鑫
博士，教授，江苏省特聘教授
江苏省常州市科教城科教会堂 C 座 409 室，邮编：213164电子邮件：liangxin@cczu.edu.cn；
课题组主页：http://liangxin.cczu.edu.cn
每年招收研究生，欢迎优秀学生报考本课题组
拟招收研究生方向：（1）材料物理与化学；（2）材料学
教育背景：
2008.09 – 2013.08，美国哈佛大学，应用物理 博士，导师：David R. Clarke 院士；
2008.09 – 2010.05，美国哈佛大学，应用物理 硕士；
2006.09 – 2008.08，加拿大麦克马斯特大学，材料工程 硕士，导师：J. David Embury 院士和
Hatem S. Zurob 教授；
2002.09 – 2006.07，北京科技大学，材料物理 学士
工作经历：
2014.12 – 至今，常州大学，特聘教授，课题组组长；
2013.12 – 2014.11，美国布朗大学，博士后研究员，导师：Brian W. Sheldon 教授；
2013.09 – 2013.11，美国哈佛大学，博士后，导师：David R. Clarke 院士
研究领域：
? 声子、电子输运机制；
? 可持续性高效热电材料探索与研究；
? 热管理及超低热导材料；
? 金属、陶瓷及复合材料的结构与机械性能
代表荣誉及奖励：
? 江苏省特聘教授，2016
? 江苏省“六大人才高峰”第十二批高层次人才资助，2015
? 江苏省“双创计划”双创博士资助项目，2015
? The Lin Fellowship, Harvard University，2009-2010
? Harvard Graduate Student Fellowship，2008-2009
? McMaster Internal Prestige “Mutual Group Graduate Scholarship”，2007-2008
? 北京市优秀毕业生，2006

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学术成果：
21. X. Liang* and L. Shen, Optimizing interfacial transport properties of InO2 single
atomic layers in In2O3(ZnO)4 natural superlattices for enhanced high temperature
thermoelectrics, Nanoscale, 2018, 10, 4500-4514.
20. X. Liang* and L. Shen, Interfacial thermal and electrical transport properties
of pristine and nanometer-scale ZnS modified grain boundary in ZnO polycrystals, Acta
Materialia, 2018, 148, 100-109.
19. X. Liang*, Mobile copper ions as heat carriers in polymorphous copper sulfide
superionic conductors, Applied Physics Letters, 2017, 111, 133902.
18. X. Liang*, Impact of grain boundary characteristics on lattice thermal
conductivity: A kinetic theory study on ZnO, Physical Review B, 2017, 95, 155313.
17. Y. Yang, X. Liu and X. Liang*, Thermoelectric properties of Bi1-xSnxCuSeO solid
solutions, Dalton Transactions, 2017, 46, 2510-2515.
16. X. Liang, Y. Yang, J. Lou and B. W. Sheldon*, The impact of core-shell
nanotube structures on fracture in ceramic nanocomposites, Acta Materialia, 2017, 122, 82-91.
15. X. Liang* and X. Wang, Modeling of θ → α alumina lateral phase transformation with
applications to oxidation kinetics of NiAl-based alloys, Materials & Design, 2016, 112, 519-529.
14. X. Liu, D. Jin and X. Liang*, Enhanced thermoelectric performance of n-type transformable
AgBiSe2 polymorphs by indium doping, Applied Physics Letters, 2016, 109, 133901.
13. S. Margueron, J. Pokorny, S. Skiadopoulou, S. Kamba, X. Liang and D. R.
Clarke, Optical and vibrational properties of (ZnO)k In2O3 natural superlattice
nanostructures, Journal of Applied Physics, 2016, 119, 195103.
12. X. Liang*, Nanostructure engineering of ZnO based complex oxides for thermoelectric
application,
Invited Review, Current Nanoscience, 2016, 12, 157-168.
11. X. Liang*, Thermoelectric transport properties of naturally nanostructured Ga–ZnO
ceramics: Effect of point defect and interfaces, Journal of the European Ceramic
Society, 2016, 36, 1643-1650.
10. Y. Yang, X. Liang, W. Chen, L. Cao, M. Li, B. W. Sheldon and J. Lou*, Quantification and
promotion of interfacial interactions between carbon nanotubes and polymer derived
ceramics, Carbon, 2015, 95, 964-971.
9. X. Su, T. Zhang, X. Liang, H. J. Gao and B. W. Sheldon*, Employing nanoscale surface
morphologies to improve interfacial adhesion between solid electrolytes and Li ion
battery cathodes, Acta Materialia, 2015, 98, 175-181.
8. X. Liang*, Remarkable enhancement in the Kapitza resistance and electron
potential barrier of chemically modified In2O3(ZnO)9 natural superlattice interfaces,
Physical Chemistry Chemical Physics, 2015, 17, 29655-29660.
7. X. Liang*, Thermoelectric Transport Properties of Fe-Enriched ZnO with
High-Temperature Nanostructure Refinement, ACS Applied Materials & Interfaces, 2015, 7, 7927-7937.
6. X. Liang*, Recasting the Callaway and von Baeyer thermal conductivity model on defective
oxide materials: the ZnO-In2O3 system as an example, Physical Chemistry Chemical Physics,
2015, 17,
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27889-27893.
5. X. Liang* and D. R. Clarke, Relation between thermoelectric properties and phase equilibria
in the ZnO–In2O3 binary system, Acta Materialia, 2014, 63, 191-201.
4. X. Liang*, Scaling of stacking fault energy and deformation temperature on
strain hardening of FCC metals and alloys, Philosophical Magazine Letters, 2014, 94, 556-563.
3. X. Liang, M. Baram and D. R. Clarke*, Thermal (Kapitza) resistance of interfaces in
compositional dependent ZnO-In2O3 superlattices, Applied Physics Letters, 2013, 102, 5.
2. X. Liang, X. Wang and H. S. Zurob, Microstructural characterization of transformable Fe-Mn
alloys at different length scales, Materials Characterization, 2009, 60, 1224-1231.
1. X. Liang, J. R. McDermid, O. Bouaziz, X. Wang, J. D. Embury and H. S. Zurob,
Microstructural evolution and strain hardening of Fe-24Mn and Fe-30Mn alloys during tensile
deformation, Acta Materialia, 2009, 57, 3978-3988.
教学:
讲授本科专业基础课（双语）：“New Energy Materials”讲授本科专业课（双语）：“Electroceramics”








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