目前已在国际知名刊物上发表SCI论文71篇,SCI被引4800余次,第一作者单篇被引最高689次,15篇被引超过100次,H因子32(Web of Science数据)。以第一/通讯作者发表SCI论文33篇,包括Innovation(1篇)、Nat. Commun.(1篇)、Sci. Bull.(1篇)、Interdiscip. Mater.(1篇)、Appl. Phys. Rew.(1篇)、Adv. Funct. Mater.(4篇)、Adv. Energy Mater.(2篇)、Nano Energy(2篇)、Adv. Sci.(2篇)、NPG Asia Mater.(1篇)、Acta Mater.(3篇)、Sci. China-Mater.(1篇)、J. Mater. Sci. Technol.(1篇)、Chem. Eng. J.(1篇)等,其中IF ≥ 10的论文22篇,中科院升级版一区论文22篇,ESI高被引论文4篇。申请发明专利7项,已授权5项。
代表性第一/通讯作者论文如下:
2024年:
[1] Y. H. Zhang,# G. Y. Peng,# S. K. Li,# H. J. Wu,* K. D. Chen, J. D. Wang, Z. H. Zhao, T. Lyu, Y. Yu, C. H. Zhang, Y. Zhang, C. S. Ma, X. D. Ding,* J. Sun, F. S. Liu,* L. P. Hu,* Phase interface engineering enables state-of-the-art half-heusler thermoelectrics. Nature Communications, 2024, 15, 5978. 中科院大类1区,IF = 14.7
[2] J. X. Zhong,# X. Y. Yang,# T. Lyu, G. G. Liang, S. N. Zhang, C. H. Zhang, W. Q. Ao, F. S. Liu, P. F. Nan,* B. H. Ge, L. P. Hu,* Nuanced dilute doping strategy enables high-performance GeTe thermoelectrics. Science Bulletin, 2024, 69, 1037-1049. 中科院大类1区,IF = 18.8
[3] Y. L. Huang,# T. Lyu,#,* M. T. Zeng, M. R. Wang, Y. Yu, C. H. Zhang, F. S. Liu, M. Hong,* L. P. Hu,* Manipulation of metavalent bonding to stabilize metastable phase: a strategy for enhancing zT in GeSe. Interdisciplinary Materials, 2024, 3, 607-620. 中国科技期刊卓越行动计划高起点新刊,IF = 24.5
[4] Y. W. Zhou, J. H. Cheng, M. Hong, T. Lyu, M. R. Wang, X. H. Luo, C. H. Zhang, F. S. Liu, L. P. Hu,* Orchestrating phase transition in GeTe thermoelectrics: an investigation into the role of electronegativity. Nano Energy, 2024, 127, 109723. 中科院大类1区,IF = 16.8
[5] Tu Lyu, Moran Wang, Xiaohuan Luo, Yuwei Zhou, Lei Chen, Min Hong,* and Lipeng Hu,* Advanced GeSe-based thermoelectric materials: Progress and future challenge, Applied Physics Reviews, 2024, 11, 031323. 中科院大类1区,IF = 11.9
[6] M. R. Wang, M. Hong, X. C. Fang, J. H. Cheng, T. Lyu, Y. W. Zhou, X. H. Luo, C. H. Zhang, W. Q. Ao, F. S. Liu, L. P. Hu,* Engineering the p-n switch: mastering intrinsic point defects in Sb2Te3-dominant alloys. Acta Materialia, 2024, 266, 119675. 中科院大类1区,IF = 8.3
[7] Y. G. Li, Y. Q. Liu, M. R. Wang, W. Q. Yao, X. H. Luo, T. Lyu, W. Q. Ao, C. H. Zhang, F. S. Liu, L. P. Hu,* Leveraging crystal symmetry for thermoelectric performance optimization in cubic GeSe. Rare Metals, 2024, 43(10), 5332-5345. 中科院大类1区,IF = 9.6
[8] X. H. Luo, J. H. Cheng, B. C. Duan, M. R. Wang, Y. W. Zhou, T. Lyu, C. H. Zhang, S. N. Zhang,* F. S. Liu,* L. P. Hu,* Realizing n-type GeSe thermoelectrics: boosting the solubility of donor dopants by enhancing the crystal symmetry. Rare Metals, 2024, 43(12), 6583-6595. 中科院大类1区,IF = 9.6
2023年:
[1] Wenqing Yao, Yihua Zhang, Tu Lyu, Weibo Huang, Nuoxian Huang, Xiang Li, Chaohua Zhang, Fusheng Liu, Matthias Wuttig, Yuan Yu,* Min Hong,* and Lipeng Hu,* Two-step phase manipulation by tailoring chemical bonds results in high-performance GeSe thermoelectrics, The Innovation, 2023, 4(6), 100522. 中科院大类1区,IF = 33.2
[2] Lipeng Hu, Bingcai Duan, Tu Lyu,* Nan Lin, Chaohua Zhang, Fusheng Liu,* Junqin Li, Matthias Wuttig, and Yuan Yu,* In Situ Design of High-Performance Dual-Phase GeSe Thermoelectrics by Tailoring Chemical Bonds, Advanced Functional Materials, 2023, 33, 2214854. 中科院大类1区,IF = 18.5
[3] Dongliang Su, Jiahui Cheng, Shan Li, Shengnan Zhang, Tu Lyu, Chaohua Zhang, Junqin Li, Fusheng Liu, and Lipeng Hu,* Inhibiting the bipolar effect via band gap engineering to improve the thermoelectric performance in n-type Bi2-xSbxTe3 for solid-state refrigeration, Journal of Materials Science & Technology, 2023, 138, 50-58. 中科院大类1区,IF = 11.2
[4] Jinxuan Zhong, Gege Liang, Jiahui Cheng, Weiqin Ao, Chaohua Zhang, Junqin Li, Fusheng Liu, Shengnan Zhang,* and Lipeng Hu,* Entropy engineering enhances the thermoelectric performance and microhardness of (GeTe)1-x(AgSb0.5Bi0.5Te2)x, Science China Materials, 2023, 66(2), 696-706. 中科院大类2区,IF = 6.8
[5] Tu Lyu, Quanxin Yang, Zhenming Li, Chaohua Zhang, Fusheng Liu, Junqin Li, Lipeng Hu,* and Guiying Xu,* High pressure drives microstructure modification and zT enhancement in bismuth-telluride-based alloys, ACS Applied Materials & Interfaces, 2023, 15, 19250-19257. 中科院大类2区,IF = 8.3
2022年:
[1] Xiang Li,# Zhiyao Zhang,# Jibiao Li, Feng Cheng, Jian He, Chaohua Zhang, Junqin Li, Fusheng Liu, Tu Lyu,* Binghui Ge,* Lipeng Hu,* Crystal symmetry enables high thermoelectric performance of rhombohedral GeSe(MnCdTe2)x, Nano Energy, 2022, 100, 107434. (IF = 19.069)
[2] Tu Lyu,# Xiang Li,# Quanxin Yang, Jiahui Cheng, Yihua Zhang, Chaohua Zhang, Fusheng Liu, Junqin Li, Weiqin Ao, Heping Xie, and Lipeng Hu,* Stepwise Ge vacancy manipulation enhances the thermoelectric performance of cubic GeSe, Chemical Engineering Journal, 2022, 442, 136332. (IF = 16.744)
[3] Shan Li,# Xingce Fang,# Tu Lyu, Jiahui Cheng, Weiqin Ao, Chaohua Zhang, Fusheng Liu, Junqin Li, and Lipeng Hu,* Antisite defect manipulation enables the high thermoelectric performance of p-type Bi2-xSbxTe3 alloys for solid-state refrigeration, Materials Today Physics, 2022, 27, 100764. (IF = 11.021)
[4] Jiahui Cheng, Tu Lyu,* Gege Liang, Wenqing Yao, Weiqin Ao, Chaohua Zhang, Junqin Li, Fusheng Liu, and Lipeng Hu,* Microstructure design via novel thermodynamic route to enhance the thermoelectric performance of GeTe, Materials Today Physics, 2022, 27, 100820. (IF = 11.021)
[5] Bingcai Duan, Yihua Zhang,* Quanxin Yang, Yugeng Li, Jiahui Cheng, Chaohua Zhang, Junqin Li, Fusheng Liu, and Lipeng Hu,* The Role of Cation Vacancies in GeSe: Stabilizing High-Symmetric Phase Structure and Enhancing Thermoelectric Performance, Advanced Energy and Sustainability Research, 2022, 3, 2200124. (Wiley新刊邀稿)
2021年及以前:
[1] Shizhen Zhi,# Jibiao Li,# Lipeng Hu,* Junqin Li, Ning Li, Haijun Wu,* Fusheng Liu, Chaohua Zhang, Weiqin Ao, Heping Xie, Xinbing Zhao, Stephen John Pennycook, and Tiejun Zhu*, Medium Entropy-enabled High Performance Cubic GeTe Thermoelectrics, Advanced Science, 2021, 8, 2100220. (IF = 17.521)
[2] Lipeng Hu,* Fanchen Meng, Yanjie Zhou, Jibiao Li,* A. Benton, Junqin Li, Fusheng Liu, Chaohua Zhang, Jian He,* Leveraging Deep Levels in Narrow Bandgap Bi0.5Sb1.5Te3 for Record-High zTave Near Room Temperature, Advanced Functional Materials, 2020, 30(45), 2005202. (IF = 19.924)
[3] Gege Liang,# Tu Lyu,# Lipeng Hu,* Wanbo Qu, Shizhen Zhi, Jibiao Li, Yang Zhang, Jian He, Junqin Li, Fusheng Liu, Chaohua Zhang, Weiqin Ao, Heping Xie, and Haijun Wu,* (GeTe)1-x(AgSnSe2)x: Strong Atomic Disorder-Induced High Thermoelectric Performance near the Ioffe-Regel Limit, ACS Applied Materials & Interfaces, 2021, 13, 47081. (IF = 10.383)
[4] Yanjie Zhou,# Fanchen Meng,# Jian He, Allen Benton, Lipeng Hu,* Fusheng Liu, Junqin Li, Chaohua Zhang, Weiqin Ao, and Heping Xie, n-Bi2-xSbxTe3: A Promising Alternative to MainstreamThermoelectric Material n-Bi2Te3-xSex near Room Temperature, ACS Applied Materials & Interfaces, 2020, 12(28), 31619. (IF = 10.383)
[5] Lipeng Hu, Yang Zhang, Haijun Wu, Yamei Liu, Junqin Li,* Jian He, Weiqin Ao, Fusheng Liu, Stephen John Pennycook, Xierong Zeng, Synergistic Compositional-Mechanical-Thermal Effects Leading to a Record High zT in n-Type V2VI3 Alloys Through Progressive Hot Deformation, Advanced Functional Materials, 2018, 28, 1803617. (IF = 19.924)
[6] Lipeng Hu, Yang Zhang, Haijun Wu, Junqin Li,* Yu Li, Myles Mckenna, Jian He,* Fusheng Liu, Stephen John Pennycook, Xierong Zeng, Entropy Engineering of SnTe: Multi-Principal-Element Alloying Leading to Ultralow Lattice Thermal Conductivity and State-of-the-Art Thermoelectric Performance, Advanced Energy Materials, 2018, 8, 1802116. (IF = 29.698)
[7] Lipeng Hu, Yangming Guo, Junqin Li, Weiqin Ao, Fusheng Liu, Chaohua Zhang, Yu Li, Xierong Zeng, Control of donor-like effect in V2VI3 polycrystalline thermoelectric materials, Materials Research Bulletin, 2018, 99, 377–384. (IF = 5.600)
[8] Tiejun Zhu,* Lipeng Hu, Xinbing Zhao, Jian He*, New Insights into Intrinsic Point Defects in V2VI3 Thermoelectric Materials, Advanced Science, 2016, 3(7), 1600004. (IF = 17.521)
[9] Lipeng Hu#, Haijun Wu#, Tiejun Zhu *, Chenguang Fu, Jiaqing He*, Pingjun Ying, Xinbing Zhao*, Tuning Multiscale Microstructures to Enhance Thermoelectric Performance of n-Type Bismuth-Telluride-Based Solid Solutions, Advanced Energy Materials, 2015, 5(17): 1500411. (IF = 29.698)
[10] Lipeng Hu, Tiejun Zhu*, Xianqiang Yue, Xiaohua Liu, Yaguang Wang, Zhaojun Xu, Xinbing Zhao*, Enhanced Figure of Merit in Antimony Telluride Thermoelectric Materials by In-Ag Co-alloying for Mid-temperature Power Generation, Acta Materialia, 2015, 85: 270-278. (IF = 9.209)
[11] Lipeng Hu, Tiejun Zhu*, Xiaohua Liu, Xinbing Zhao*, Point Defect Engineering of High-Performance Bismuth-Telluride-Based Thermoelectric Materials, Advanced Functional Materials, 2014, 24(33): 5211-5218. (IF = 19.924)
[12] Lipeng Hu, Tiejun Zhu*, Yaguang Wang, Hanhui Xie, Zhaojun Xu, Xinbing Zhao*, Shifting up the Optimum Figure of Merit of p-type Bismuth Telluride-based Thermoelectric Materials for Power Generation by Suppressing Intrinsic Conduction, NPG Asia Materials, 2014, 6: e88. (IF = 10.761)
[13] Lipeng Hu, Xiaohua Liu, Hanhui Xie, Junjie Shen, Tiejun Zhu*, Xinbing Zhao*, Improving Thermoelectric Properties of n-type Bismuth-Telluride-Based Alloys by Deformation-Induced Lattice Defects and Texture Enhancement, Acta Materialia, 2012, 60(11): 4431-4437. (IF = 9.209)
[14] Lipeng Hu, Hongli Gao, Xiaohua Liu, Hanhui Xie, Junjie Shen, Tiejun Zhu*, Xinbing Zhao*, Enhancement in Thermoelectric Performance of Bismuth Telluride Based Alloys by Multi-scale Microstructural Effects, Journal of Materials Chemistry, 2012, 22(32): 16484-16490. (IF = 6.626)