近期团队发表：
23. R. Sun, et. al., High anisotropy in electrical and thermal conductivity through the design of aerogel-like superlattice (NaOH)0.5NbSe2, Nature Communications (2023) 14:6689
22. Y. Jing, et. al, Scalable manufacturing of a durable, tailorable, and recyclable multifunctional woven thermoelectric textile system, Energy Environ. Sci., 2023, 16, 4334
21. N. Chen, Hangtian Zhu,* Guodong Li, Zhen Fan, Xiaofan Zhang, Jiawei Yang, Tianbo Lu, Qiulin Liu, Xiaowei Wu, Yuan Yao, Youguo Shi, Huaizhou Zhao,* Improved figure of merit (z) at low temperatures for superior thermoelectric cooling in Mg3(Bi,Sb)2, Nature Communications (2023) 14:4932
20. Q. Dong, et. al., A quasi-one-dimensional bulk thermoelectrics with high performance near room temperature, Science Bulletin 68 (2023) 920–927
19. T. Lu, et. al., Synergistically enhanced thermoelectric and mechanical performance of Bi2Te3 via industrial scalable hot extrusion method for cooling and power generation applications, Materials Today Physics 32 (2023) 101035
18. Y. Zheng, et. al., Durable, stretchable and washable inorganic-based woven thermoelectric textiles for power generation and solid-state cooling, Energy Environ. Sci., (2022).
17. A. Dutt, et. al., Geometric Study of Polymer Embedded Micro Thermoelectric Cooler with Optimized Contact Resistance, Adv. Electron. Mater. 2022, 2101042.
16. K. Jia, et. al., Emergence of 1/3 magnetization plateau and successive magnetic transitions in Zintl phase Eu3InAs3.  Physical Review Research, 2021, PHYSICAL REVIEW RESEARCH 3, 043178 (2021).
15. J. Guo, et. al., “Doping high-mobility donor–acceptor copolymer semiconductors with an organic salt for high-performance thermoelectric materials”，Adv. Electron. Mater. 2020, 1900945 (2020).
14. F. Yang, et. al., Effect of additives and optimized Cyclic voltammetry parameters on the morphology of electrodeposited Tellurium thin film, Journal of Electroanalytical Chemistry 925 (2022) 116872
13. Q. Liu, et. al., Highly efficient thermoelectric air conditioner with kilo-Watt capacity realized by ground source heat exchanging system, iScience, 5, 104296, 2022.
12. R. Pan, et. al., Diversified Plasmonic Metallic Nanostructures with High Aspect Ratio based on Templated Electrochemical Deposition, J. Micromech. Microeng. 32 (2022) 054002.
11. Y. Zheng, et. al., Durable, stretchable and washable inorganic-based woven thermoelectric textiles for power generation and solid-state cooling, Energy Environ. Sci., 2022 15, 2374.
10. Q. Liu, et. al., Micro thermoelectric devices: from principles to innovative applications, Chinese Physics B, 2022, 21(4): 047204.
9. A. Dutt, et. al., Geometric Study of Polymer Embedded Micro Thermoelectric Cooler with Optimized Contact Resistance, Adv. Electron. Mater. 2022, 2101042.
8. J.Yang, et. al., Next-Generation Thermoelectric Cooling Modules Based on High-Performance Mg3(Bi,Sb)2 Material，Joule, 2021, 6, 1-12.
7. K. Jia, et. al., Emergence of 1/3 magnetization plateau and successive magnetic transitions in Zintl phase Eu3InAs3. Physical Review Research, 2021, 3, 043178 (2021).
6. S. Moradi, et. al., Highly Symmetric and Extremely Compact Multiple Winding Microtubes by a Dry Rolling Mechanism, Adv. Mater. Interfaces, 2020, 1902048 (2020)
5. L. Gao, et. al., High-Pressure Synthesis and Thermal Transport Properties of Polycrystalline BAsx, CHIN. PHYS. LETT. Vol. 37, No. 6, 066202 (2020)
4. V. Barati, et. al., “Thermoelectric characterization platform for electrochemically deposited materials”, Adv. Electron. Mater. 2020, 1901288 (2020)
3. J. Guo, et. al., “Doping high-mobility donor–acceptor copolymer semiconductors with an organic salt for high-performance thermoelectric materials”, Adv. Electron. Mater. 2020, 1900945 (2020)
2. E. Song, et. al., “Thickness-Dependent Electronic Transport in Ultrathin, Single Crystalline Silicon Nanomembranes”, Adv. Electron. Mater. 2019, 1900232 (2019)
1. D. A. Lara Ramos, et. al., “Design Guidelines for Micro-Thermoelectric Devices by Finite Element Analysis”, Adv. Sustainable Syst. 2019, 1800093 (2019)
代表性工作：
1. G. Li,* J. Garcia Fernandez, D. Lara Ramos, V. Barati, N. Perez, I. Soldatov, H. Reith, G. Schierning, and K. Nielsch, “Integrated micro-thermoelectric coolers with rapid response time and high device reliability”, Nat. Electronics 1, 555, (2018, Cover page) （citation >100次）.
2. G. Li,* M. Yarali, A. Cocemasov, S. Baunack, D. Nika, V. M. Fomin, S. Singh, F. Zhu, A. Mavrokefalos and O. G. Schmidt, “In-Plane Thermal Conductivity of Radial and Planar Si/SiOx Hybrid Nanomembrane Superlattices”, ACS Nano 11, 8215−8222 (2017).
3. Q. Liu, F. Wei, G. Li,* Z. Kan, J. Yang, H. Zhu, B. Wang,* H. Zhao,* Highly efficient thermoelectric air conditioner with kilo-Watt capacity realized by ground source heat exchanging system, iScience, 5, 104296 (2022).
4. G. Li, D. Liang, Richard L. Qiu and Xuan P. A. Gao, “Measurement of thermal conductivity of individual Bi2Se3 nano-ribbon by self-heating three-omega method”, Appl. Phys. Lett. 102, 043104 (2013).
5. G. Li, D. Liang, Richard L. Qiu and Xuan P. A. Gao, “Measurement of thermal conductivity of individual Bi2Se3 nano-ribbon by self-heating three-omega method”, Appl. Phys. Lett. 102, 043104 (2013)