澳门游戏网站大全

      周恒辉 

博士,研究员,博士生导师

分析化学,新能源材料

办公室:澳门游戏网站大全B106

电话:+86-10-62757908

电子信箱:hhzhou@pku.edu.cn

课题组网页:/zhangxx/

学术简历:

1999/12-至今,公司先行科技产业有限公司,首席科学家

1998/07-至今,公司,澳门游戏网站大全,教师

1995/09–1998/07,公司,澳门游戏网站大全,博士研究生,导师:慈云祥教授;

1986/09–1989/07,湘潭大学,化学系,硕士研究生,导师:王应玮教授。

 

研究领域与兴趣:

1. 能量储存与转换材料的设计、合成及表征;

2. 化学能源中的电极/电解质界面研究;

3. 可移动能源器件的设计及其在3C电子产品、电动汽车中的应用。

近5年代表性论文:

  1. Wang Q., Wan J., Cao X., Wen R., Guo Y.G., Liu W.*, Zhou H.H.*Organophosphorus Hybrid Solid Electrolyte Interphase Layer Based on LixPO4 Enables Uniform Lithium Deposition for High-Performance Lithium Metal BatteriesAdv. Func. Mater.,2021,doi.org/10.1002/adfm.2021079235.
  2. Yang, C., Shao, R., Wang, Q., Zhou, T., Lu, J., Jiang, N., Gao, P., Liu, W., Yu, Y.*, Zhou, H.H.*, Bulk and surface degradation in layered Ni-rich cathode for Li ions batteries: Defect proliferation via chain reaction mechanism. Energy Storage Materials, 2021,35:62-69.
  3. Wang, Q., Wu, K., Wang, H., Liu, W.*, Zhou, H.H.*, Lithiophilic 3D SnS2@Carbon Fiber Cloth for Stable Li Metal Anode. Acta Physico-Chimica Sinica,2021,37(1):1-9.
  4. Wang, Q., Wang, H., Wu, J., Zhou, M., Liu, W*. Zhou, H.H.*, Advanced electrolyte design for stable lithium metal anode: From liquid to solid. Nano Energy , 2021,80:105516.
  5. Wang Q., Wang H.C., Liu Y., Wu K., Liu W.*, Zhou H.H.*, Asymmetric quasi-solid electrolyte enables high-performance Li metal batteriesChem. Commun. ,2020, 56, 7195–7198.
  6. Liu Y., Wang Q., Bi S. C., Zhang W., Zhou H.H.*, Jiang X Y*, Water Processable Liquid Metal Nanoparticles by Single Step Polymer EncapsulationNanoscale. 2020, 12, 13731–13741.
  7. Zhu M., Wang Q., Zhou H.H.*, Qi L.M.*, Binder-Free TiO2-Coated Polypropylene Separators for Advanced Lithium-Ion Batteries Energy Technology. 2020, 2000228.
  8. Wu K.,Zhao B.L.,Yang C.K., Wang Q.,Liu W.*, Zhou H.H.*, ZnCo2O4/ZnO induced lithium deposition in multi-scaled carbon/nickel frameworks for dendrite-free lithium metal anodeJ. Energy Chem., 2020, 43: 16–23.
  9. Zhao B.T., Lu X., Wang Q., Yang J., Zhao J.*, Zhou H.H.*Enhancing the ionic conductivity in a composite polymer electrolyte with ceramic nanoparticles anchored to charged polymer brushesChinese Chemical Letters2020,31,831–835.
  10. Qi L.Y., Shang L.R.,Wu K.,Qu L.L., Pei H.,Li W., Zhang L.X., Wu Z.W., Zhou H.H. *, McKeown N.B. *, Zhang W.X. *, Yang Z.J. *, An Interfacial Layer Based on Polymers of Intrinsic Microporosity to Suppress Dendrite Growth on Li Metal Anodes,Chemistry-A European J., 2019,25(52): 12052–12057.
  11. Wang Q., Yang C.K.,yang J.J.,Wu K.,Hu C.J.,Lu J., Liu W.*, Sun X.M.,Qiu J.Y. *,Zhou H.H.*, Dendrite-Free Lithium Deposition via a Superfilling Mechanism for High-Performance Li-Metal BatteriesAdv. Mater.,2019,31(41)1903248
  12. Wang Q., Yang C.K., Zhang Y.F., Yang J.J., Wu K., Hu C.J., Lu J., Liu W. *, Zhou H.H. *Surface-Based Li+ Complex Enables Uniform Lithium Deposition for Stable Lithium Metal AnodesACS Appl. Energy Mater., 2019,2(7): 4602–4608.
  13. Hu Y.R., Wu K., Zhang F., Zhou H.H. *, Qi L.M. *Hierarchical MnO@C Hollow Nanospheres for Advanced Lithium-Ion Battery AnodesACS Appl. Nano Mater. 2019, 2429−439.
  14. He L., Chen C., Kotobuki M., Zheng F., Zhou H.H.*, Lu L.*A new approach for synthesizing bulk-type all-solid-state lithium-ion batteriesJ. Mater. Chem. A, 20197 (16)97489760.
  15. Qian D., Gu Y., * Chen Y., Liu H., Wang J., Zhou H.H. *Ultra-high specific capacity of Cr3+-doped Li4Ti5O12 at 1.55 V as anode material for lithium-ion batteriesMaterials Letters2019, 238102106.
  16.  Zhang F., Yang C.K., Guan H.Q., Hu Y.R., Jin C., Zhou H.H.,* Qi L.M. * 3D Copper Foam@FeOx Nanoarrays as A High Areal Capacity and Stable Electrode for Lithium-Ion Batteries, ACS Applied Energy Materials, 2018,110):54175427.
  17. Wu K., Shi B.W., Qi L.Y., Mi Y.Y., Zhao B.L., Yang C.K., Wang Q., Tang H., Lu J., Liu W.,* Zhou H.H., * SnO2 quantum dots @ 3D sulfur-doped reduced graphene oxides as active and durable anode for lithium ion batteries, Electrochimica Acta, 2018, 2912430.
  18. Wang Q., Yang C.K., Tang H., Wu K., Zhou H.H., Graphene oxide-polypyrrole composite as sulfur hosts for high-performance Lithium-Sulfur batteries, Functional Materials Letters, 2018,11(06): 1840007.
  19. Wang S., Liu X., Wang A.L., Wang Z., Chen J., Zeng Q., Jiang X., Zhou H.H., Zhang L.Y., High-Performance All-Solid-State Polymer Electrolyte with Controllable Conductivity Pathway Formed by Self-Assembly of Reactive Discogen and Immobilized via a Facile Photopolymerization for a Lithium-Ion BatteryACS Applied Materials and Interfaces2018, 1030: 25273–25284
  20. Wang S., WangA.L., Yang C.K., Gao R., Liu X., Chen J., Wang Z.N., Zeng Q.H., Liu X.H., Zhou H.H., Zhang L.Y., Six-arm star polymer based on discotic liquid crystal as high performance all-solid-state polymer electrolyte for lithium-ion batteriesJ. Power Sources, 2018, 395:137–147.
  21. Wang Q. , Yang C.K., Yang J.J., Wu K., Qi L.Y., Tang H., Zhang Z.Y., Liu W. *, Zhou H.H. *, Stable Li metal anode with protected interface for high-performance Li metal batteries, Energy Storage Materials , 2018,15: 249–256
  22. Fu Y., Gu Y.J.*, Chen Y.B., Liu H.Q., Zhou H.H.*,Changes in Mn3+/Mn4+ ratio, resistance values in electrochemical impedance spectra, and rate capability with increased lithium content in spinel LixMn2O4Solid State Ionics, 2018,320:16–23
  23. Yang C.K., Shao R.W., Mia Y.Y., Shen L.Y., Zhao B.L., Wang Q., Wu K., Liu W.*, Gao P.,* Zhou H.H. *, Stable interstitial layer to alleviate fatigue fracture of high nickel cathodeJ. Power Sources, 2018, 376:200–206.
  24. Zheng X.Y. , Yang C.K.,Zheng J. *, Zhou H.H.,* Li X.G.*, Synergism of rare earth trihydrides and graphite in lithium storage: evidence of hydrogen enhanced lithiationAdv. Mater.2017303):1704353
  25. Li Y., Gu Y.J.*, Chen Y.B., Liu H.Q., Han Y.Q., Wang H.F., Zhou H.H. *,Mixed Mn3+/Mn4+ in high-voltage nano-structured lithium nickel manganese oxide cathode with a P4332 structure, Funct.Mater.Lett., 2017, 10 (6) :1750074
  26. Gu Y.J.,* Li Y.,* Chen Y.B., Liu H.Q., Zhou H.H.,* Wang H.F., Han Y.Q.Zhang J., Enhanced Oxygen Vacancies in Nanostructured LiNi0.5Mn1.5O4-δ with a P4332 Space Group, Int. J. Electrochem. Sci., 2017, 12 , 9523 – 9532
  27. Tu J.G., Wu K., Tang H.Zhou H.H.,*, Jiao S.Q.,* Mg-Ti co-doping behavior of porous LiFePO4 microspheres for high-rate lithium-ion batteriesJ. Mater. Chem. A, 2017, 5:17021–17028
  28. Zhang F., Yang C.K., GaoX. , Chen S., Hu Y.R., Guan H.Q., Ma Y.R., Zhang J., Zhou H.H.*, Qi L.M.*SnO2@PANI Core-Shell Nanorod Arrays on 3D Graphite Foam: A High-Performance Integrated Electrode for Lithium-Ion BatteriesACS Appl. Mater. Interfaces, 20179(11): 9620–9629
  29. Li G.Y., Zhang Z.J. *, Huang Z.L., Yang C.K., Zuo Z.C.Zhou H.H.*, Understanding the accumulated cycle capacity fade caused by secondary particles fracture of LiNi1-x-yCoxMnyO2 cathode for lithium ion batteries, J.Solid State Electrochem., 2017, 21(3): 673–682
  30. Mi Y.Y., Liu W., Yang K. R., Jiang J.B., Fan Q., Weng Z., Zhong Y.R., Wu Z.S., Brudvig G.W., Batista V. S. *, Zhou H.H.*, Wang H.L. *, Ferrocene Promoted Long Cycle Lithium-Sulfur Batteries, Angew. Chem. Int. Ed., 201655(47) 1481814822
  31. Yang C.K., Qi L.Y., Zuo Z.C., Wang R.N., Ye M., Lu J., Zhou H.H. *, Insights into the Inner Structure of High-Nickel Agglomerate as High-Performance Lithium-Ion Cathodes, J. Power Sources, 2016, 331: 487–494
  32. Li G.Y., Zhang Z.J. *, Wang R.N. *, Huang Z.L., Zuo Z.C.Zhou H.H.*, Effect of Trace Al Surface Doping on the Structure, Surface Chemistry and Low Temperature Performance of LiNi0.5Co0.2Mn0.3O2 Cathode, Electrochimica Acta, 2016, 212:399407
  33. Qi L.Y., Xin Y.L., Zuo Z.C., Yang C.K., Wu K.,Wu B., Zhou H.H.*Grape-Like Fe3O4 Agglomerates Grown on Graphene Nanosheets for Ultrafast and Stable Lithium StorageACS Appl. Mater. Interfaces, 20168(27)1724517252
  34. Qi L.Y., Zhang Y.W., Zuo Z.C., Xin Y.L., Yang C.K., Wu B., Zhang X.X.Zhou H.H.*,In-situ Quantization of Ferroferric Oxide Embedded in Micro 3D Carbon for Ultrahigh Performance Sodium-Ion BatteryJ. Mater. Chem. A,2016, 4:88228829
  35. Yang X.H., J.G. Tu , M. Lei, Zuo Z.C., Wu B.R.,* Zhou H.H.* , Selection of Carbon Sources for Enhancing 3D Conductivity in the Secondary Structure of LiFePO4/C Cathode, Electrochimica Acta, 2016, 193206215
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