Liang Xin

Name

姓名

Xin Liang

Gender

性别

Male

College

学院

College of Materials Science and Engineering

Highest degree

最高学历

Ph.D.

Professional Title

职称

Professor

(PhD Advisor)

Discipline/Major

专业

Materials Science/Applied Physics

Research Area/Direction

招生研究方向

• Thermal transport physics;

• Thermal Engineering Materials (Ceramics/ Semiconductors, Metals, and Composites)

• Nanoscale measurement techniques for physical transport properties

Email

邮箱

liangxin-mse@buct.edu.cn

Research Topics（no more than 100 words）研究方向

1. Thermal transport physics of low-dimensional materials

2. Advanced techniques for measuring physical transport properties at nanoscale

3. Harvesting and conversion of thermal energy

Education Background 教育背景

Ph.D. in Applied Physics, Harvard University;

Master of Science in Applied Physics, Harvard University;

Master of Applied Science in Materials Engineering, McMaster University;

Bachelor’s degree in Material Physics, University of Science and Technology Beijing

Work Experience 工作经历

2023.05 to present, Professor, Beijing University of Chemical Technology;

2019-2023, Professor, University of Chinese Academy of Sciences;

2014-2019, Professor, Changzhou University;

2013-2014, Postdoctoral Researcher, Brown University;

2013, Postdoctoral Fellow, Harvard University

Publications(no more than 10 representative publications) 发表文章

1.X. Liang* and C. Wang, Anomalous behavior of strain modulated lattice thermal transport in piezoelectric crystals and the effect of polarization, Acta Materialia 2022, 241, 118406.

2. X. Liang* and C. Wang, Insights into strain dependent lattice thermal conductivity of tin oxide, Acta Materialia, 2022, 239, 118289.

3. X. Liang* and C. Chen, Ductile inorganic amorphous compounds with phonon-glass electron-crystal transport behavior and excellent stability of high thermoelectric performance on plastic deformation, Acta Materialia, 2021, 218, 117231.

4. X. Liang*, H. Wang, and C. Wang, Lattice thermal conductivity of transition metal carbides: evidence of a strong electron-phonon interaction above room temperature, Acta Materialia, 2021, 216, 117160.

5. X. Liang*, and F. Dai, Epoxy nanocomposites with reduced graphene oxide constructed 3D networks of single wall carbon nanotube for enhanced thermal management capability with low filler loading, ACS Applied Materials & Interfaces, 2020, 12(2), 3051-3058.

6. 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.

7. 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.

8. 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.

9. X. Liang*, Impact of grain boundary characteristics on lattice thermal conductivity: A kinetic theory study on ZnO, Physical Review B, 2017, 95, 155313.

10. 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.