亚 - 博取款快速到账

  

  姓 名：杨辉

  职 称：教授、博士生导师，华中卓越学者

  电子邮箱：huiyang2017@hust.edu.cn; hui.yang.m@outlook.com

教育背景：

2002- 2006亚 - 博取款快速到账，工程力学，学士

2009- 2010美国宾夕法尼亚州立大学，工程力学，硕士

2009- 2014美国宾夕法尼亚州立大学，工程科学与力学，博士

工作经历：

2015.01– 2015. 09美国宾夕法尼亚州立大学，博士后 （导师：Sulin Zhang）

2015.10– 2017. 09美国塔夫茨大学，博士后 （导师：Jianmin Qu）

2016.06– 2017. 03美国西北大学，博士后 （导师：Jianmin Qu）

2017.10– 现今 亚 - 博取款快速到账，海外高层次人才，教授，博士生导师

主要研究方向：

新能源系统的电化学-力学耦合问题，例如锂离子、钠离子电池、电催化剂等，以及电极结构、电池系统的设计；

极端、复杂环境下材料的损伤与失效研究；

跨尺度、多场耦合模拟仿真：密度泛函理论（DFT），分子动力学，反应力。≧eaxFF），相场法（Phase-field method），应变梯度、晶体塑性有限元；

原位材料观测与表征：纳米压痕，高倍原位透射电子显微镜；

增材制造的跨尺度、多场耦合模拟。

主要学术成就：

主要从事新能源（电池、催化剂、核能）相关材料的力学跨学科研究。先后参加了多项美国国家自然科学基金、美国能源部等机构资助的科研项目，主持了中国海外高层次青年人才计划、中国国家自然科学基金支持项目。在新兴高性能二次电池材料与结构充/放电过程中的电化学动力学、材料变形与破坏、以及电极材料结构的优化设计等方面取得了一系列突出研究成果，其中既包括实时、原位的高倍透射电子显微镜实验观测方法，又包括跨尺度、多场耦合数值计算方法及相关的理论建模。从2012年到目前，在固体力学及工程科学领域的顶级期刊上发表论文50多篇；其中，以第一或同等贡献第一作者、通讯作者发表在国际著名期刊有Nature Communications、Nano Letters、ACS Nano、Energy Storage Materials、Applied Catalysis B: Environmental、Journal of the Mechanics and Physics of Solids（固体力学顶级期刊）、Extreme Mechanics Letters等。所发表论文被引用2500多次，H指数为22。

已发表论文：

(**: Equal contribution; ^@@: Corresponding author; ____: Students supervised; IF: Impact factor;)

1. Zhang, W.; Gui, S.; Li, W.; Sun, Y.^@@; Zhou, H.; Yang, H.^@@, Scalable and Controllable Fabrication of Micro-Si-Graphene Composites with 3D Conducting Network as a High-Stable Anode Material for LIBs. ACS Applied Materials & Interfaces, 2022, Submitted.

2. Zhang, C.; Deng, D.; Ai, X.; Gui, S.; Xie, Q.^@@; Guo, W.; Zheng, H.; Wang, L.; Yang, H.^@@; Peng, D.^@@, Kilogram-scale synthesis of ultra-long-life Li-rich layered cathode for superior Li-ion batteries. Energy Storage Materials, 2022, Submitted.

3. Zhang, W.**; Gui, S.**; Li, W.; Tu, S.; Li, G.; Zhang, Y.; Sun, Y.^@@; Xie, J.; Zhou, H.; Yang, H.^@@, Functionally Gradient Silicon/Graphite Composite Electrodes Enabling Stable Cycling and High Capacity for Lithium-Ion Batteries. ACS Applied Materials & Interfaces, 2022, Submitted.

4. Gao, D.; Deng, S.; Li, X.; Zhang, Y.; Lv, T.; He, Y.; Mao, W.; Yang, H.; Chu, P. K.; Huo, K., Lithiophilic and Conductive Framework of 2D MoN Nanosheets Enabling Planar Lithium Plating for Dendrite-Free and Minimum-Volume-Change Lithium Metal Anodes. Small, 2022, Submitted.

5. Wang, X.; Li, C.; Chen, Z.; Tu, S.; Hu, Y.; Yang, H.; Sun, Y., Heterogeneous Li-alloy interface enabling stable battery foil anode. Energy Storage Materials, 2022, Submitted.

6. Xiong, R.; Yu, Y.; Chen, S.; Li, M.; Li, L.; Zhou, M.; Zhang, W.; Yan, B.; Li, D.; Yang, H.^@@; Zhang, Y.^@@; Zhou, H.^@@, Overpotential decomposition enabled decoupling of complex kinetic processes in battery electrodes. Journal of Power Sources, 2022, Submitted.

7. Li, Z.; Fu, J.; Zhou, X.; Wei, L.; Yang, H.; Guo, X.^@@, Ionic conduction in lithium-ion conducting solid polymer electrolytes. Advanced Materials, 2022, Submitted.

8. Cui, C.; Yang, H.; Zeng, C.; Gui, S.; Liang, J.; Xiao, P.; Wang, S.; Huang, G.; Hu, M.; Zhai, T.; Li, H., Unlocking the in-situ Li plating dynamics and evolution mediated by diverse metallic substrates in all solid-state batteries. Science Advances, 2022, Accepted. (IF = 14.972)

9. Zeng, C.; Chen, J.; Yang, H.; Yang, A.; Cui, C.; Zhang, Y.; Li, X.; Gui, S.; Wei, Y.; Feng, X.; Xu, X.; Xiao, P.; Liang, J.; Zhai, T.; Cui, Y.; Li, H., Visualizing fast interlayer anisotropic lithium diffusion via single crystal microbattery. Matter, 2022, https://doi.org/10.1016/j.matt.2022.08.003. (IF = 19.967)

10. Li, C.; Tu, S.; Ai, X.; Gui, S.; Chen, Z.; Wang, W.; Liu, X.; Tan, Y.; Yang, H.^@@; Sun, Y.^@@, Stress-regulation design of lithium alloy electrode towards stable battery cycling. Energy & Environmental Materials, 2022, https://doi.org/10.1002/eem2.12267. (IF = 15.122)

11. Gao, H.; Ai, X.; Wang, H.; Li, W.; Wei, P.; Cheng, Y.; Gui, S.; Luo, L.; Yang, H.^@@; Yang, Y.; Wang, M.^@@, Visualizing the failure of solid electrolyte under GPa-level interface stress induced by lithium eruption. Nature Communications, 2022, 13: p.5050. (IF = 17.694)

12. Li, Z.; Yu, R.; Gui, S.; Yang, H.^@@; Guo, X.^@@, A pressure responsive artificial interphase layer of BaTiO₃ against dendrite growth for stable lithium metal anodes. Batteries & Supercaps, 2022, 5: p. e202200142. (IF = 7.093)

13. Wang, J.; Guo, X.; Du, X.; Liang, J.; Wu, J.; Zhao, G.; Li, X.; Gui, S.; Zheng, F.; Zhao, J.; Xu, C.; Wang, D.^@@; Yang, H.^@@; Zhang, B.^@@; Zhu, Y.^@@, Revealing the complex lithiation pathways and kinetics of core-shell NiO@CuO electrode. Energy Storage Materials, 2022, 51: p. 11-18. (IF = 20.831).

14. Zhou, X.**; Li, X.**; Li, Z.; Fu, J.; Xu, S.; Zhou, W.; Gui, S.; Wei, L.; Yang, H.^@@; Wu, J.^@@; Guo, X.^@@, Ten micrometer thick polyethylene separator modified by α-LiAlO₂@γ-Al₂O₃ nanosheets for simultaneous suppression of Li dendrite growth and polysulfide shuttling in Li-S batteries. Materials Today Energy, 2022, 26: p. 100990. (IF = 9.257)

15. Li, Q.; Liu, K.; Gui, S.; Wu, J.; Li, X.; Liu, Z. ^@@; Jin, H.; Yang, H.^@@; Hu, Z.; Liang, W. ^@@; Huang, L.^@@, Cobalt doping boosted electrocatalytic activity of CaMn₃O₆ for hydrogen evolution reaction. Nano Research, 2022, 15 (4): p. 2870-2876. (IF = 10.269)

16. Wei, P.; Sun, X.^@@; Wang, M.; Xu, J.; He, Z.; Li, X.; Cheng, F.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Construction of an N-decorated carbon encapsulated W₂C/WP heterostructure as an efficient electrocatalyst for hydrogen evolution in both alkaline and acidic media. ACS Applied Materials & Interfaces, 2021, 13 (45): p. 53955-53964. (IF = 10.383)

17. Ye, H.**; Gui, S.**; Wang, Z.; Chen, J.; Liu, Q.; Zhang, X.; Jia, P.; Tang, Y.; Yang, T.; Du, C.; Geng, L.; Li, H.; Dai, Q.; Tang, Y.^@@; Zhang, L.^@@; Yang, H.^@@; Huang, J.^@@, In situ measurements of the mechanical properties of electrochemically deposited Li₂CO₃ and Li₂O nanorods. ACS Applied Materials & Interfaces, 2021, 13 (37): p. 44479-44487. (IF = 10.383)

18. Wei, P.; Li, X.; He, Z.; Li, Z.; Sun, X.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Electron density modulation of MoP by rare earth metal as highly efficient electrocatalysts for pH-universal hydrogen evolution reaction. Applied Catalysis B: Environmental, 2021. 299: p. 120657. (IF = 19.503)

19. Zhou, X.; Li, X.; Li, Z.; Xie, H.; Fu, J.; Wei, L.; Yang, H.^@@; Guo, X.^@@, Hybrid Electrolytes with Ultrahigh Li-Ion Transference Number for Lithium-Metal Batteries with Fast and Stable Charge/Discharge Capability. Journal of Materials Chemistry A, 2021. 9: p. 18239-18246. (IF = 12.732)

20. Xiong, R.; Zhang, Y.; Wang, Y.; Song, L.; Li, M.; Yang, H.; Huang, Z.; Li, D.; Zhou, H., Scalable manufacture of high-performance battery electrodes enabled by a template-free method. Small Methods, 2021. 5 (6): p. 2100280. (IF = 14.188)

21. Wei, P.**; Li, X.**; He, Z.; Sun, X.; Liang, Q.; Wang, Z.; Fang, C.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Porous N, B co-doped carbon nanotubes as efficient metal-free electrocatalysts for ORR and Zn-air batteries. Chemical Engineering Journal, 2021. 422: p. 130134. (IF = 13.273)

22. Tu, S.; Ai, X.; Wang, X.; Gui, S.; Cai, Z.; Zhan, R.; Tan, Y.; Liu, W.; Yang, H.^@@, Li, C.^@@; Sun, Y.^@@, Circumventing chemo-mechanical failure of Sn foil battery anode by grain refinement and elaborate porosity design. Journal of Energy Chemistry, 2021. 62: p. 477-484. (IF = 9.676)

23. Ding, X.^@@; Liang, D.; Ai, X.; Zhao, H.; Zhang, N.; Chen, X.; Xu, J.; Yang, H.^@@, Synergistic lithium storage in silica-tin composites enables a cycle-stable and high-capacity anode for lithium-ion batteries. ACS Applied Energy Materials, 2021. 4 (3): p. 2741-2750. (IF = 6.024)

24. Li, G.; Yang, Q.; Chao, J.; Zhang, B.; Wan, M.; Liu, X.; Mao, E.; Wang, L.; Yang, H.; Seh, Z.; Jiang, J.; Sun, Y., Enhanced processability and electrochemical cyclability of metallic sodium at elevated temperature using sodium alloy composite. Energy Storage Materials, 2021. 35: p. 310-316. (IF = 17.789)

25. Cao, S.; Zhang, X.; Mao, L.; Wang, Y.; Qu, A.; Zhang, Y.; Yang, H.; Zhu, L.; Wang, Y.; Lu, J., Numerical and experimental comparison of two nano-structuring processing techniques on making stronger stainless steels. Materials Today Communications, 2020. 24: p. 100419. (IF = 3.383)

26. Zhang, C.; Chen, Q.; Ai, X.; Li, X.; Xie, Q.^@@; Cheng, Y.; Kong, H.; Xu, W.; Wang, L.; Wang, M.; Yang, H.^@@; Peng, D.^@@, Conductive polyaniline doped with phytic acid as a binder and conductive additive for a commercial silicon anode with enhanced lithium storage properties. Journal of Materials Chemistry A, 2020. 8: p. 16323-16331. (IF = 12.732)

27. Wei, P.**; Sun, X.**; Liang, Q.; Li, X.; He, Z.; Hu, X.; Zhang, J.; Wang, M.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Enhanced oxygen evolution reaction activity by encapsulating NiFe alloy nanoparticles in nitrogen-doped carbon nanofibers. ACS Applied Materials & Interfaces, 2020. 12 (28): p. 31503-31513. (IF = 9.229)

28. Xiong, L.; Jin, H.; Lu, Y.; Li, X.; Ai, X.; Yang, H.^@@; Huang, L.^@@, A solvent molecule driven pure PEDOT:PSS actuator. Macromolecular Materials and Engineering, 2020. 305: p. 2000327. (IF = 4.367)

29. Cao, L.; Yang, H.; Fan, F., Stress generation during anisotropic lithiation in silicon nanopillar electrodes: a reactive force field study. Physics Letters A, 2019. 383 (33): p. 125955. (IF = 2.654)

30. Yang, H.^@@; Qu, J.^@@, Fracture toughness of Li_xSi alloys in lithium ion battery. Extreme Mechanics Letters, 2019. 32: p. 100555. (IF = 4.806)

31. Zhu, J.**; Shen, H.**; Shi, X.**; Yang, F.; Hu, X.; Zhou, W.; Yang, H.^@@; Gu, M.^@@, Revealing the chemical and structural evolution of V₂O₅ nanoribbons in lithium-ion battery using in-situ transmission electron microscopy. Analytical Chemistry, 2019. 91: p. 11055-11062. (IF = 6.986)

32. Zhu, J.**; Guo, M.**; Liu, Y.; Shi, X.; Fan, F.; Gu, M.^@@; Yang, H.^@@, In situ TEM of phosphorus dopant-induced nanopore formation in delithiated silicon nanowires. ACS Applied Materials & Interfaces, 2019. 11 (19): p. 17313-17320. (IF = 9.229)

33. Han, S.; Zhu, Y.; Cai, C.; Zhu, J.; Han, W.; Chen, L.; Zu, X.^@@; Yang, H.^@@; Gu, M.^@@, Failure mechanism of Au@Co9S8 yolk-shell anode in Li-ion batteries unveiled by in-situ transmission electron microscopy. Applied Physics Letters, 2019. 114 (11): p. 113901-5. (IF = 3.791)

34. Dai, F.; Yi, R.; Yang, H.; Zhao, Y.; Luo, L.; Gordin, M.; Sohn, H.; Chen, S.; Wang, C.-M.; Zhang, S.; Wang, D., Minimized volume expansion in hierarchical porous silicon upon lithiation. ACS Applied Materials & Interfaces, 2019. 11 (14): p. 13257-13263. (IF = 9.229)

35. Song, J.; Yang, H.; Bermejo, R.; Qu, J.; Hu, L.; Zhang, Y., Enhanced thermal shock response of Al₂O₃–graphite composites through a layered architectural design. Journal of the American Ceramic Society, 2019. 102: p. 3673-3684. (IF = 3.784)

36. Li, Z.; Huang, H.; Zhu, J.; Wu, J.; Yang, H.^@@; Wei, L.^@@; Guo, X.^@@, Ionic conduction in composite polymer electrolytes: case of PEO: Ga-LLZO composites. ACS Applied Materials & Interfaces, 2019. 11 (1): p. 784-791. (IF = 9.229)

37. Shi, X.**; Zhu, J.**; Xia, Y.; Fan, F.; Zhang, F.; Gu, M.^@@; Yang, H.^@@, Ultra-high malleability of the lithiation-induced LixSi phase. ACS Applied Energy Materials, 2018. 1: p. 4211-4220. (IF = 6.024)

38. Fan, F.; Yang, H.; Zeng, Z., An atomistic perspective on lithiation-induced stress in silicon nanopillars. Scripta Materialia, 2018. 152: p. 74-78. (IF = 5.611)

39. Chen, T.; Yang, H.; Li, J.; Zhang, S., Mechanics of electrochemically driven mechanical energy harvesting. Extreme Mechanics Letters, 2017. 15: p. 78-82. (IF = 4.806)

40. Xiao, X.; Chen, Q.; Yang, H.; Duan, H.; Qu, J., A mechanistic model for depth-dependent hardness of ion irradiated metals. Journal of Nuclear Materials, 2017. 485: p. 80-89. (IF = 2.936)

41. Yang, H.; Qu, J., Advance in lithiation mechanics of anode materials in lithium ion battery. Science & Technology Review, 2016. 34 (23): p. 88-98.

42. Kim, S.; Choi, S. J.; Zhao, K.; Yang, H.; Gobbi, G.; Zhang, S.; Li, J.; Electrochemically driven mechanical energy harvesting. Nature Communications, 2016. 7: p.10146. (IF = 14.919)

43. Xiao, Q.**; Gu, M.**; Yang, H.**; Li, B.; Zhang, C.; Liu, Y.; Liu, F.; Dai, F.; Yang, L.; Liu, Z.; Xiao, X.; Liu, G.; Zhao, P.; Zhang, S.; Wang, C.-M.; Lu, Y.; Cai, M., Inward lithium-ion breathing of hierarchically porous silicon anodes. Nature Communications, 2015. 6: p. 8844. (IF = 14.919)

44. Luo, L.; Zhao, P.; Yang, H.; Liu, B.; Zhang, J.-G.; Cui, Y.; Yu, G.; Zhang, S.; Wang, C.-M., Surface coating constraint induced self-discharging of silicon nanoparticles as anodes for lithium ion batteries. Nano Letters, 2015. 15 (10): p. 7016-7022. (IF = 13.779)

45. Luo, L.**; Yang, H.**; Yan, P.; Travis, J. J.; Liu, N.; Piper, D. M.; Lee, S.-H.; George, S. M.; Zhang, J.-G.; Cui, Y.; Zhang, S.; Ban, C.; Wang, C.-M., Surface-coating regulated lithiation kinetics and degradation in silicon nanowires for lithium ion battery. ACS Nano, 2015. 9 (5): p. 5559-5566. (IF = 15.881)

46. Yang, H.; Liang, W.; Guo, X.; Wang, C.-M.; Zhang, S., Strong kinetics-stress coupling in lithiation of Si and Ge anodes. Extreme Mechanics Letters, 2015. 2: p. 1-6. (IF = 4.806)

47. Yang, H.; Fan, F.; Liang, W.; Guo, X.; Zhu, T.; Zhang, S., A chemo-mechanical model of lithiation in silicon. Journal of the Mechanics and Physics of Solids, 2014. 70: p. 349-361. (IF = 5.471)

48. Wang, C.-M.; Gu, M.; Yang, H.; Perea, D.E.; Zhang, S., In-situ TEM study of internal and external stress on lithiation behavior of high capacity anode materials with a large volume change. Microscopy and Microanalysis, 2014. 20 (SupplementS3): p. 1536-1537. (IF = 4.127)

49. Gu, M.**; Yang, H.**; Perea, D.E.; Zhang, J.-G.; Zhang, S.; Wang, C.-M., Bending-induced symmetry breaking of lithiation in germanium nanowires. Nano Letters, 2014. 14 (8): p. 4622-4627. (IF = 13.779)

50. Liang, W.; Hong, L.; Yang, H.; Fan, F.; Liu, Y.; Li, H.; Li, J.; Huang, J.Y.; Chen, L.-Q.; Zhu, T.; Zhang, S., Nanovoid formation and annihilation in gallium nanodroplets under lithiation-delithiation cycling. Nano Letters, 2013. 13 (11): p. 5212-5217. (IF = 13.779)

51. Huang, X.; Yang, H.; Liang, W.; Raju, M.; Terrones, M.; Crespi, V.H.; van Duin, A.C.T.; Zhang, S., Lithiation induced corrosive fracture in defective carbon nanotubes. Applied Physics Letters, 2013. 103 (15): p. 153901-4. (IF = 3.791)

52. Fan, F.; Huang, S.; Yang, H.; Raju, M.; Datta, D.; Shenoy, V.B.; van Duin, A.C.T.; Zhang, S.L.; Zhu, T., Mechanical properties of amorphous LixSi alloys: a reactive force field study. Modelling and Simulation in Materials Science and Engineering, 2013. 21 (7): p. 074002. (IF = 2.248)

53. Liang, W.; Yang, H.; Fan, F.; Liu, Y.; Liu, X.H.; Huang, J.Y.; Zhu, T.; Zhang, S., Tough germanium nanoparticles under electrochemical cycling. ACS Nano, 2013. 7 (4): p. 3427-3433. (IF = 15.881)

54. Yang, H.; Huang, X.; Liang, W.; van Duin, A.C.T.; Raju, M.; Zhang, S., Self-weakening in lithiated graphene electrodes. Chemical Physics Letters, 2013. 563: p. 58-62. (IF = 2.328)

55. Liu, X.H.; Fan, F.; Yang, H.; Zhang, S.; Huang, J.Y.; Zhu, T., Self-limiting lithiation in silicon nanowires. ACS Nano, 2013. 7 (2): p. 1495-1503. (IF = 15.881)

56. Segall, A.E.; Drapaca, C.; Engels, D.; Zhu, T.; Yang, H., Direct and inverse solutions for thermal- and stress-transients and the analytical determination of boundary conditions using remote temperature or strain data. Journal of Pressure Vessel Technology, 2012. 134 (4): p. 041011. (IF = 1.142)

57. Huang, X.; Yang, H.; van Duin, A.C.T.; Hsia, K.J.; Zhang, S., Chemomechanics control of tearing paths in graphene. Physical Review B, 2012. 85 (19): p. 195453. (IF = 4.036)

Yang, H.; Huang, S.; Huang, X.; Fan, F.; Liang, W.; Liu, X.H.; Chen, L.-Q.; Huang, J.Y.; Li, J.; Zhu, T.; Zhang, S., Orientation-dependent interfacial mobility governs the anisotropic swelling in lithiated silicon nanowires. Nano Letters, 2012. 12 (4): p. 1953-1958. (IF = 13.779)

招贤纳士：

课题组长期招收相关研究方向的博士后，年薪税前24-40万元，欢迎加盟！

欢迎有力学、机械、材料、电化学、数学知识背景且有志于从事科学研究的学生报考硕士/博士研究生

Hui Yang, Ph.D.

Department of Mechanics

School of Aerospace Engineering &

State Key Laboratory of Material Processing and Die & Mould Technology

Huazhong University of Science and Technology

Wuhan, Hubei 430074, China

Mobile: (+86) 136-3864-5498

Email: huiyang2017@hust.edu.cn; hui.yang.m@outlook.com

Ph.D.  Engineering Science and Mechanics, 2014

The Pennsylvania State University, University Park, PA, USA

Advisor: Prof. Sulin Zhang

M.S.          Engineering Mechanics, 2010

The Pennsylvania State University, University Park, PA, USA

Advisor: Prof. Albert E. Segall

B.S.           Engineering Mechanics, 2006

Huazhong University of Science and Technology, Wuhan, Hubei, China

Advisor: Prof. Jianqiao Chen

· Electro-chemo-mechanics of energy-storage technologies, i.e., lithium/sodium-ion batteries, electrocatalysts

· Damage and failure of materials under extreme and complex Environments

· Molecular dynamics, reactive force field (ReaxFF), and finite element modeling

· In-situ experimentation, i.e., TEM, nano-indentation

· Phase field modeling, strain gradient plasticity, crystal plasticity

· Multi-physical finite-element methods for additive manufacturing

· Professor, 10/2017 - Present

Department of Mechanics, School of Aerospace Engineering &

State Key Laboratory of Material Processing and Die & Mould Technology

Huazhong University of Science and Technology

Wuhan, Hubei, China

· Postdoctoral Fellow, 10/2015 – 09/2017

Department of Mechanical Engineering

Tufts University, Medford, MA, USA

Supervisor: Prof. Jianmin Qu

· Postdoctoral Fellow, 06/2016 - 03/2017

Department of Civil and Environmental Engineering

Northwestern University, Evanston, IL, USA

Supervisor: Prof. Jianmin Qu

· Postdoctoral Researcher, 01/2015 - 10/2015

Department of Engineering Science and Mechanics

The Pennsylvania State University, University Park, PA, USA

Supervisor: Prof. Sulin Zhang

· Graduate Research Assistant, 2009 - 2014

Department of Engineering Science and Mechanics

The Pennsylvania State University, University Park, PA, USA

· Graduate Research Assistant, 2005 - 2006

Department of Mechanics

Huazhong University of Science and Technology, Wuhan, Hubei, China

Summary: 2515 times of total citations (Google Scholar), H-index=22.

(**: Equal contribution; ^@@: Corresponding author; ____: Students supervised; IF: Impact factor;)

1. Zhang, W.; Gui, S.; Li, W.; Sun, Y.^@@; Zhou, H.; Yang, H.^@@, Scalable and Controllable Fabrication of Micro-Si-Graphene Composites with 3D Conducting Network as a High-Stable Anode Material for LIBs. ACS Applied Materials & Interfaces, 2022, Submitted.

2. Zhang, C.; Deng, D.; Ai, X.; Gui, S.; Xie, Q.^@@; Guo, W.; Zheng, H.; Wang, L.; Yang, H.^@@; Peng, D.^@@, Kilogram-scale synthesis of ultra-long-life Li-rich layered cathode for superior Li-ion batteries. Energy Storage Materials, 2022, Submitted.

3. Zhang, W.**; Gui, S.**; Li, W.; Tu, S.; Li, G.; Zhang, Y.; Sun, Y.^@@; Xie, J.; Zhou, H.; Yang, H.^@@, Functionally Gradient Silicon/Graphite Composite Electrodes Enabling Stable Cycling and High Capacity for Lithium-Ion Batteries. ACS Applied Materials & Interfaces, 2022, Submitted.

4. Gao, D.; Deng, S.; Li, X.; Zhang, Y.; Lv, T.; He, Y.; Mao, W.; Yang, H.; Chu, P. K.; Huo, K., Lithiophilic and Conductive Framework of 2D MoN Nanosheets Enabling Planar Lithium Plating for Dendrite-Free and Minimum-Volume-Change Lithium Metal Anodes. Small, 2022, Submitted.

5. Wang, X.; Li, C.; Chen, Z.; Tu, S.; Hu, Y.; Yang, H.; Sun, Y., Heterogeneous Li-alloy interface enabling stable battery foil anode. Energy Storage Materials, 2022, Submitted.

6. Xiong, R.; Yu, Y.; Chen, S.; Li, M.; Li, L.; Zhou, M.; Zhang, W.; Yan, B.; Li, D.; Yang, H.^@@; Zhang, Y.^@@; Zhou, H.^@@, Overpotential decomposition enabled decoupling of complex kinetic processes in battery electrodes. Journal of Power Sources, 2022, Submitted.

7. Li, Z.; Fu, J.; Zhou, X.; Wei, L.; Yang, H.; Guo, X.^@@, Ionic conduction in lithium-ion conducting solid polymer electrolytes. Advanced Materials, 2022, Submitted.

8. Cui, C.; Yang, H.; Zeng, C.; Gui, S.; Liang, J.; Xiao, P.; Wang, S.; Huang, G.; Hu, M.; Zhai, T.; Li, H., Unlocking the in-situ Li plating dynamics and evolution mediated by diverse metallic substrates in all solid-state batteries. Science Advances, 2022, Accepted. (IF = 14.972)

9. Zeng, C.; Chen, J.; Yang, H.; Yang, A.; Cui, C.; Zhang, Y.; Li, X.; Gui, S.; Wei, Y.; Feng, X.; Xu, X.; Xiao, P.; Liang, J.; Zhai, T.; Cui, Y.; Li, H., Visualizing fast interlayer anisotropic lithium diffusion via single crystal microbattery. Matter, 2022, https://doi.org/10.1016/j.matt.2022.08.003. (IF = 19.967)

10. Li, C.; Tu, S.; Ai, X.; Gui, S.; Chen, Z.; Wang, W.; Liu, X.; Tan, Y.; Yang, H.^@@; Sun, Y.^@@, Stress-regulation design of lithium alloy electrode towards stable battery cycling. Energy & Environmental Materials, 2022, https://doi.org/10.1002/eem2.12267. (IF = 15.122)

11. Gao, H.; Ai, X.; Wang, H.; Li, W.; Wei, P.; Cheng, Y.; Gui, S.; Luo, L.; Yang, H.^@@; Yang, Y.; Wang, M.^@@, Visualizing the failure of solid electrolyte under GPa-level interface stress induced by lithium eruption. Nature Communications, 2022, 13: p.5050. (IF = 17.694)

12. Li, Z.; Yu, R.; Gui, S.; Yang, H.^@@; Guo, X.^@@, A pressure responsive artificial interphase layer of BaTiO₃ against dendrite growth for stable lithium metal anodes. Batteries & Supercaps, 2022, 5: p. e202200142. (IF = 7.093)

13. Wang, J.; Guo, X.; Du, X.; Liang, J.; Wu, J.; Zhao, G.; Li, X.; Gui, S.; Zheng, F.; Zhao, J.; Xu, C.; Wang, D.^@@; Yang, H.^@@; Zhang, B.^@@; Zhu, Y.^@@, Revealing the complex lithiation pathways and kinetics of core-shell NiO@CuO electrode. Energy Storage Materials, 2022, 51: p. 11-18. (IF = 20.831).

14. Zhou, X.**; Li, X.**; Li, Z.; Fu, J.; Xu, S.; Zhou, W.; Gui, S.; Wei, L.; Yang, H.^@@; Wu, J.^@@; Guo, X.^@@, Ten micrometer thick polyethylene separator modified by α-LiAlO₂@γ-Al₂O₃ nanosheets for simultaneous suppression of Li dendrite growth and polysulfide shuttling in Li-S batteries. Materials Today Energy, 2022, 26: p. 100990. (IF = 9.257)

15. Li, Q.; Liu, K.; Gui, S.; Wu, J.; Li, X.; Liu, Z. ^@@; Jin, H.; Yang, H.^@@; Hu, Z.; Liang, W. ^@@; Huang, L.^@@, Cobalt doping boosted electrocatalytic activity of CaMn₃O₆ for hydrogen evolution reaction. Nano Research, 2022, 15 (4): p. 2870-2876. (IF = 10.269)

16. Wei, P.; Sun, X.^@@; Wang, M.; Xu, J.; He, Z.; Li, X.; Cheng, F.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Construction of an N-decorated carbon encapsulated W₂C/WP heterostructure as an efficient electrocatalyst for hydrogen evolution in both alkaline and acidic media. ACS Applied Materials & Interfaces, 2021, 13 (45): p. 53955-53964. (IF = 10.383)

17. Ye, H.**; Gui, S.**; Wang, Z.; Chen, J.; Liu, Q.; Zhang, X.; Jia, P.; Tang, Y.; Yang, T.; Du, C.; Geng, L.; Li, H.; Dai, Q.; Tang, Y.^@@; Zhang, L.^@@; Yang, H.^@@; Huang, J.^@@, In situ measurements of the mechanical properties of electrochemically deposited Li₂CO₃ and Li₂O nanorods. ACS Applied Materials & Interfaces, 2021, 13 (37): p. 44479-44487. (IF = 10.383)

18. Wei, P.; Li, X.; He, Z.; Li, Z.; Sun, X.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Electron density modulation of MoP by rare earth metal as highly efficient electrocatalysts for pH-universal hydrogen evolution reaction. Applied Catalysis B: Environmental, 2021. 299: p. 120657. (IF = 19.503)

19. Zhou, X.; Li, X.; Li, Z.; Xie, H.; Fu, J.; Wei, L.; Yang, H.^@@; Guo, X.^@@, Hybrid Electrolytes with Ultrahigh Li-Ion Transference Number for Lithium-Metal Batteries with Fast and Stable Charge/Discharge Capability. Journal of Materials Chemistry A, 2021. 9: p. 18239-18246. (IF = 12.732)

20. Xiong, R.; Zhang, Y.; Wang, Y.; Song, L.; Li, M.; Yang, H.; Huang, Z.; Li, D.; Zhou, H., Scalable manufacture of high-performance battery electrodes enabled by a template-free method. Small Methods, 2021. 5 (6): p. 2100280. (IF = 14.188)

21. Wei, P.**; Li, X.**; He, Z.; Sun, X.; Liang, Q.; Wang, Z.; Fang, C.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Porous N, B co-doped carbon nanotubes as efficient metal-free electrocatalysts for ORR and Zn-air batteries. Chemical Engineering Journal, 2021. 422: p. 130134. (IF = 13.273)

22. Tu, S.; Ai, X.; Wang, X.; Gui, S.; Cai, Z.; Zhan, R.; Tan, Y.; Liu, W.; Yang, H.^@@, Li, C.^@@; Sun, Y.^@@, Circumventing chemo-mechanical failure of Sn foil battery anode by grain refinement and elaborate porosity design. Journal of Energy Chemistry, 2021. 62: p. 477-484. (IF = 9.676)

23. Ding, X.^@@; Liang, D.; Ai, X.; Zhao, H.; Zhang, N.; Chen, X.; Xu, J.; Yang, H.^@@, Synergistic lithium storage in silica-tin composites enables a cycle-stable and high-capacity anode for lithium-ion batteries. ACS Applied Energy Materials, 2021. 4 (3): p. 2741-2750. (IF = 6.024)

24. Li, G.; Yang, Q.; Chao, J.; Zhang, B.; Wan, M.; Liu, X.; Mao, E.; Wang, L.; Yang, H.; Seh, Z.; Jiang, J.; Sun, Y., Enhanced processability and electrochemical cyclability of metallic sodium at elevated temperature using sodium alloy composite. Energy Storage Materials, 2021. 35: p. 310-316. (IF = 17.789)

25. Cao, S.; Zhang, X.; Mao, L.; Wang, Y.; Qu, A.; Zhang, Y.; Yang, H.; Zhu, L.; Wang, Y.; Lu, J., Numerical and experimental comparison of two nano-structuring processing techniques on making stronger stainless steels. Materials Today Communications, 2020. 24: p. 100419. (IF = 3.383)

26. Zhang, C.; Chen, Q.; Ai, X.; Li, X.; Xie, Q.^@@; Cheng, Y.; Kong, H.; Xu, W.; Wang, L.; Wang, M.; Yang, H.^@@; Peng, D.^@@, Conductive polyaniline doped with phytic acid as a binder and conductive additive for a commercial silicon anode with enhanced lithium storage properties. Journal of Materials Chemistry A, 2020. 8: p. 16323-16331. (IF = 12.732)

27. Wei, P.**; Sun, X.**; Liang, Q.; Li, X.; He, Z.; Hu, X.; Zhang, J.; Wang, M.; Li, Q.; Yang, H.^@@; Han, J.^@@; Huang, Y., Enhanced oxygen evolution reaction activity by encapsulating NiFe alloy nanoparticles in nitrogen-doped carbon nanofibers. ACS Applied Materials & Interfaces, 2020. 12 (28): p. 31503-31513. (IF = 9.229)

28. Xiong, L.; Jin, H.; Lu, Y.; Li, X.; Ai, X.; Yang, H.^@@; Huang, L.^@@, A solvent molecule driven pure PEDOT:PSS actuator. Macromolecular Materials and Engineering, 2020. 305: p. 2000327. (IF = 4.367)

29. Cao, L.; Yang, H.; Fan, F., Stress generation during anisotropic lithiation in silicon nanopillar electrodes: a reactive force field study. Physics Letters A, 2019. 383 (33): p. 125955. (IF = 2.654)

30. Yang, H.^@@; Qu, J.^@@, Fracture toughness of Li_xSi alloys in lithium ion battery. Extreme Mechanics Letters, 2019. 32: p. 100555. (IF = 4.806)

31. Zhu, J.**; Shen, H.**; Shi, X.**; Yang, F.; Hu, X.; Zhou, W.; Yang, H.^@@; Gu, M.^@@, Revealing the chemical and structural evolution of V₂O₅ nanoribbons in lithium-ion battery using in-situ transmission electron microscopy. Analytical Chemistry, 2019. 91: p. 11055-11062. (IF = 6.986)

32. Zhu, J.**; Guo, M.**; Liu, Y.; Shi, X.; Fan, F.; Gu, M.^@@; Yang, H.^@@, In situ TEM of phosphorus dopant-induced nanopore formation in delithiated silicon nanowires. ACS Applied Materials & Interfaces, 2019. 11 (19): p. 17313-17320. (IF = 9.229)

33. Han, S.; Zhu, Y.; Cai, C.; Zhu, J.; Han, W.; Chen, L.; Zu, X.^@@; Yang, H.^@@; Gu, M.^@@, Failure mechanism of Au@Co9S8 yolk-shell anode in Li-ion batteries unveiled by in-situ transmission electron microscopy. Applied Physics Letters, 2019. 114 (11): p. 113901-5. (IF = 3.791)

34. Dai, F.; Yi, R.; Yang, H.; Zhao, Y.; Luo, L.; Gordin, M.; Sohn, H.; Chen, S.; Wang, C.-M.; Zhang, S.; Wang, D., Minimized volume expansion in hierarchical porous silicon upon lithiation. ACS Applied Materials & Interfaces, 2019. 11 (14): p. 13257-13263. (IF = 9.229)

35. Song, J.; Yang, H.; Bermejo, R.; Qu, J.; Hu, L.; Zhang, Y., Enhanced thermal shock response of Al₂O₃–graphite composites through a layered architectural design. Journal of the American Ceramic Society, 2019. 102: p. 3673-3684. (IF = 3.784)

36. Li, Z.; Huang, H.; Zhu, J.; Wu, J.; Yang, H.^@@; Wei, L.^@@; Guo, X.^@@, Ionic conduction in composite polymer electrolytes: case of PEO: Ga-LLZO composites. ACS Applied Materials & Interfaces, 2019. 11 (1): p. 784-791. (IF = 9.229)

37. Shi, X.**; Zhu, J.**; Xia, Y.; Fan, F.; Zhang, F.; Gu, M.^@@; Yang, H.^@@, Ultra-high malleability of the lithiation-induced LixSi phase. ACS Applied Energy Materials, 2018. 1: p. 4211-4220. (IF = 6.024)

38. Fan, F.; Yang, H.; Zeng, Z., An atomistic perspective on lithiation-induced stress in silicon nanopillars. Scripta Materialia, 2018. 152: p. 74-78. (IF = 5.611)

39. Chen, T.; Yang, H.; Li, J.; Zhang, S., Mechanics of electrochemically driven mechanical energy harvesting. Extreme Mechanics Letters, 2017. 15: p. 78-82. (IF = 4.806)

40. Xiao, X.; Chen, Q.; Yang, H.; Duan, H.; Qu, J., A mechanistic model for depth-dependent hardness of ion irradiated metals. Journal of Nuclear Materials, 2017. 485: p. 80-89. (IF = 2.936)

41. Yang, H.; Qu, J., Advance in lithiation mechanics of anode materials in lithium ion battery. Science & Technology Review, 2016. 34 (23): p. 88-98.

42. Kim, S.; Choi, S. J.; Zhao, K.; Yang, H.; Gobbi, G.; Zhang, S.; Li, J.; Electrochemically driven mechanical energy harvesting. Nature Communications, 2016. 7: p.10146. (IF = 14.919)

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1. Yang, H.; Qu, J., A chemo-mechanical model for lithiation/delithiation cycling behaviors of high-capacity anode materials, 2017 SES Annual Technical Meeting, Boston, MA, USA.

2. Yang, H.; Qu, J., Fracture toughness of LixSi alloys in lithium ion battery, 2016 ASME's International Mechanical Engineering Congress and Exposition (IMECE), Phoenix, AZ, USA.

3. Xiao, X.; Yang, H.; Duan, H.; Qu, J., The hardness prediction of ion-irradiated metals by nanoindentation: a theoretical model and finite element simulation, 2016 ASME's International Mechanical Engineering Congress and Exposition (IMECE), Phoenix, AZ, USA.

4. Yang, H.; Qu, J., Chemo-Mechanical Modeling of Nanoindentation of LixSi Alloys in Lithium Ion Battery, 2016 ASME's International Mechanical Engineering Congress and Exposition (IMECE), Phoenix, AZ, USA.

5. Yang, H.; Qu, J., Fracture toughness of LixSi alloys in lithium ion battery, 24th International Congress of Theoretical and Applied Mechanics (ICTAM 2016), Montreal, Canada.

6. Kim, S.; Choi, S. J.; Zhao, K.; Yang, H.; Gobbi, G.; Zhang, S.; Li, J., Electrochemically driven mechanical energy harvesting, 2015 MRS Fall Meeting & Exhibit, Boston, MA, USA.

7. Yang, H.; Zhang, S., A chemo-mechanical model of delithiation in high-capacity anode materials, 2014 SES Annual Technical Meeting, West Lafayette, IN, USA.

8. Yang, H.; Zhang, S., Lithiation mechanics of high-capacity anode materials, ESM Today 2014, Department of Engineering Science and Mechanics, The Pennsylvania State University, University Park, PA, USA.

9. Zhang, S.; Yang, H., Degradation mechanics of high-capacity nanostructured electrode materials, Plasticity, Damage & Fracture 2014, Freeport, Bahamas.

10. Zhang, S.; Yang, H.; Zhu, T., In-situ lithiation mechanics of silicon and beyond, ASME International Mechanical Engineering Congress & Exposition 2013, San Diego, CA, USA.

11. Liang, W.; Hong, L.; Yang, H.; Chen, L.-Q.; Huang, J.Y.; Zhu, T.; Zhang, S., In situ TEM study of self-healing gallium nanodroplets under electrochemical cycling, 2013 SES Annual Technical Meeting, Providence, RI, USA.

12. Yang, H.; Zhang, S., In situ lithiation mechanics of silicon nanoelectrodes, ESM Today 2013, Department of Engineering Science and Mechanics, The Pennsylvania State University, University Park, PA, USA.

13. Yang, H.; Zhang, S., Mechanics of lithiation in silicon, TMS 2013 142^nd Annual Meeting and Exhibition, San Antonio, TX, USA.

14. Zhang, S.; Yang, H.; Liang, W.; Zhu, T.; Huang, J. Y., Anisotropy swelling in lithiated silicon, ASME International Mechanical Engineering Congress & Exposition 2012, Houston, TX, USA.

15. Zhang, S.; Yang, H.; Huang, X.; Huang, S.; Zhu, T., Multiscale Modeling of Anisotropic Growth in Lithiated Silicon Nanowires, TMS 2012 141^st Annual Meeting and Exhibition, Orlando, FL, USA.

16. Zhang, S.; Yang, H.; Huang, X., Multiscale modeling of anisotropic swelling in lithiated silicon nanowires, 2011 SES Annual Technical Meeting, Evanston, IL, USA.

Travel fellowship of the U.S. National Committee for Theoretical and Applied Mechanics (USNC/TAM), USA, 2016.