中国科学院北京纳米能源与系统研究所梁鑫

moyang

梁鑫，男，研究员，博士生导师。在美国哈佛大学获得应用物理硕士、博士学位后，先后在美国哈佛大学和美国布朗大学从事博士后研究工作。曾在江苏省常州大学任教授、研究生导师、课题组组长（PI），入选江苏省特聘教授（2016）。主要从事的研究方向包括材料热输运科学、半导体材料物理、固态热能管理与转换、及材料的结构与机械性能等。迄今，研究成果以第一或通讯作者发表在Nano Energy、Acta Materialia、The Journal of Physical Chemistry Letters、Nanoscale、Advanced Electronic Materials、ACS Applied Materials & Interfaces、Physical Review B、Applied Physics Letters等SCI国际学术期刊上20余篇。


姓名：        梁鑫        性别：        男
职称：        研究员        学历：        博士
电话：        010-82854791        传真：        无
Email：        liangxin@binn.cas.cn        邮编：        100083


研究方向：
围绕纳米能源材料及器件的基础科学问题和工程应用问题开展研究，主要研究方向包括：
1、半导体能源材料新物理机制探索
2、纳米尺度热输运科学与工程
3、固态热能管理、转换及应用纳米能源材料和器件
4、纳米能源材料的结构与机械性能


专家类别：
研究员
职务：
研究员
获奖及荣誉：
江苏省特聘教授，2016
江苏省“六大人才高峰”高层次人才资助，2015
江苏省“双创计划”双创博士，2015
The Lin Fellowship, Harvard University，2009
Harvard Graduate Student Fellowship，2008
McMaster Internal Prestige “Mutual Group Graduate Scholarship”，2007
北京市优秀毕业生，2006  
代表论著：
1. X. Liang*, D. Jin, and F. Dai, Phase transition engineering of Cu2S to widen the temperature window of improved thermoelectric performance, Advanced Electronic Materials, 2019 In press
2. X. Liang*, L. Shen, and C. Wang, Origin of anisotropy and compositional dependence of phonon and electron transport in ZnO based natural superlattices and role of atomic layer interfaces, Nano Energy, 2019, 59, 651-666.  
3. X. Liang*, Y. Yang, F. Dai and C. Wang, Orientation dependent physical transport behavior and the micro-mechanical response of ZnO nanocomposites induced by SWCNTs and graphene: importance of intrinsic anisotropy and interfaces, Journal of Materials Chemistry C, 2019. 7(5), 1208-1221.
4. X. Liang* and F. Dai, Reduction of the Lorenz number in copper at room temperature due to strong inelastic electron scattering brought about by high-density dislocations, The Journal of Physical Chemistry Letters, 2019, 10, 507-512.  
5. 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.  
6. 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.  
7. X. Liang*, Mobile copper ions as heat carriers in polymorphous copper sulfide superionic conductors, Applied Physics Letters, 2017, 111, 133902.
8.X. Liang*, Impact of grain boundary characteristics on lattice thermal conductivity: A kinetic theory study on ZnO, Physical Review B, 2017, 95, 155313.  
9. 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.  
10. 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.
11. X. Liang*, Thermoelectric transport properties of Fe-enriched ZnO with high-temperature nanostructure refinement, ACS Applied Materials & Interfaces, 2015, 7, 7927-7937.  
12. 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.  
13. 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.