崔立峰 教授(博士)
发布时间: 2018-09-27 文章作者: 发布人: 韩冰 访问次数: 13175

崔立峰

 

教授、博导

环境与低碳科学研究中心主任

 

上海市杨浦区军工路516

上海理工大学环境与建筑学院201

Email: lifeng.cui@gmail.com

 

 

 

研究领域

 

1.环境催化、新型环保材料

2.CO2捕获及资源化利用

3.生物质垃圾的热化学催化分解及资源化利用

4.环保二次电池、微生物燃料电池等绿色能源科技

 

教育与工作经历

 

2013.06至今:上海理工大学环境与建筑学院,教授

2011.06-2013.05Amazon,资深电池系统工程师

2010.06-2011.05Clean Cell International, Inc.,资深研究员

2007.08-2010.05:斯坦福大学材料科学与工程系,博士后研究员

2001.09-2007.05:华盛顿州立大学材料科学系/ 美国太平洋西北国家实验室-环境分子科学实验室,硕博连读研究生


 

获得荣誉

 

所做的纳米碳管集流极研究被《纽约时报》和《科学美国》报道,2010

所做同轴纳米硅线锂电池负极材料的研究被《麻省理工技术回顾》报道, 2009

所做纳米硅线锂电池负极材料的研究被《科学》报道, 2009

铅原子团簇的论文被选为《物理化学杂志》的封面,2005

研究生院知名学者奖,华盛顿州立大学,2003

研究生院知名学者奖,华盛顿州立大学,2002

 

 

SCI论文

1.“General synthesis ofmagnetic mesoporous FeNi/graphitic carbon nanocomposites and their applicationfor dye adsorption”, Y. Wang, M. Yao, Y. Chen, Y. Zuo, X. Zhang, and L. Cui*, J. Alloy. Compd., 627, 7-12(2015)

2.“Synthesis of Ti-dopedgraphitic carbon nitride with improved photocatalytic activity under visiblelight”Y.Wang, Y. Wang, Y. Chen, C. Yin, Y. Zuo, and L. Cui*, Materials Letters, 139, 70-72, (2015).  

3.“Preferential carbonmonoxide oxidation on Ag/Al-SBA-15 catalysts: Effect of the Si/Al ratio” X.Zhang, H. Dong, Z. Gu, G. Wang, Y. Zuo, Y. Wang, and L. Cui*, Chemical Engineering Journal, 269, 94-104, (2015).  

4.“Simple synthesis ofordered cubic mesoporous graphitic carbon nitride by chemical vapor depositionmethod using melamine”, Y. Wang, F. Wang; Y. Zuo, X. Zhang, and L. Cui*, Materials Letters, 136,271-273, (2014).  

5.Enhanced photocatalytic performance ofordered mesoporous Fe-doped CeO2 catalysts for the reduction of CO2with H2O under simulated solar irradiationY.Wang, F. Wang, Y. Chen, D. Zhang, B. Li, S. Kang, X. Li, and L. F. Cui*, Appl.Catal. B: Environ., 147, 6022014

6.Hierarchicallymesostructured TiO2/graphitic carbon composite as a new efficientphotocatalyst for the reduction of CO2 under simulated solarirradiation Y. Wang, F. Wang, Y. Chen, J. Yao, B. Li, S.Kang, X. Li and L.F. Cui*, Catal. Sci. Technol., 3, 3286 (2013)

  1. Ordered mesoporous CeO2-TiO2 composites:   Highly efficient photocatalysts for the reduction of CO2 with H2O   under simulated solar irradiationY. Wang, B.   Li, C. Zhang, L.F. Cui, S. Kang, X. Li, L. Zhou, Appl. Catal. B: Environ. 130, 277-284 (2013)

  2. “InorganicGlue Enabling High Performance of Silicon Particles as Lithium IonBattery Anode”, L.F. Cui,   L. Hu, F. L. Mantia, and Yi Cui, J.   of the Electrochem. Soc., 158,   A592 (2011)

  3. LiMn1-xFexPO4    Nanorods Grown on Graphene Sheets for Ultrahigh-Rate-Performance Lithium   Ion Batteries” H. Wang, Y.   Yang, Y. Liang, L. F. Cui, H.   S. Casalongue, Y. Li, G. Hong, Y. Cui, and H. Dai, Angew. Chem. Int.Ed., 50, 7364-7368 (2011)

  4. A microfluidic positioning   chamber for long-term live-cell imaging”,L. Hanson,   L. F. Cui, C.   Xie,   and B. Cui, Microscopy   Research and Technique, 74, 4962011

  5. Si nanoparticle-decorated Si nanowire networks for   Li-ion battery anodes”, Chemical   Communications, L. Hu, L.F. Cui,   H. Wu, and Y. Cui 47, 367 (2011)

  6. Light-Weight   Free-Standing Carbon Nanotube-Silicon Films for Anodes of Lithium Ion   BatteriesL. F. Cui, L. Hu, J. W. Choi and Y. Cui,ACS   Nano 4, 3671 (2010)

  7. Mn3O4Graphene Hybrid as a High-Capacity   Anode Material for Lithium Ion Batteries”, L.F. Cui, H. Wang, S. Casalongue, Y. Cui, and H. Dai, J. Am.   Chem. Soc.,132, 13978 (2010)

  8. Metal current collector-free freestanding   silicon-carbon 1D nanocomposites for ultralight anodes in lithium ion   batteries”, J. Choi, L. Hu., L.F. Cui, and Y. Cui, J.   of Power Sources, 195,8311 (2010)

  9. “Stretchable, Porous, and Conductive Energy   Textiles”, L. Hu, M. Pasta, F.L. Mantia, L.F. Cui, S. Jeong, H. Dawn   Deshazer, and Y. Cui, Nano Lett.    10, 708 (2010)

  10. “Crystalline-Amorphous   Core-Shell Silicon Nanowires for High Capacity and High Current Battery   Electrodes”, L. F. Cui, C. K.   Chan, R. Ruffo, H. Peng, and Y. Cui Nano Lett., 9, 491-495 (2009)

  11. “Carbon-Silicon   Core-Shell Nanowires as High Capacity Electrode for Lithium ion   Batteries ”, L. F. Cui, Y. Yang, C. M. Hsu, and Y. Cui,  Nano Lett. 9, 3370   (2009) (Reported by ScienceNOW and MIT Technology Review)

  12. “Highly   Conductive Paperfor   Energy Storage Devices” L. Hu, J.   W. Choi, Y. Yang, L. F. Cui, S.   Jeong, F. L. Mantia, and Yi Cui, Proc.   Natl. Acad. Sci. USA, 106, 21490 (2009) (Reportedby New York Times and Scientific America)

  13. “Stable Icosahedral Hollow Cage Clusters:   Stannaspherene (Sn122–) and Plumbaspherene (Pb122–)”,   L. F. Cui and L. S. Wang, Int.   Rev. Phys. Chem. 27, 139-166 (2008)

  14. “Probing   the Electronic and Structural Properties of Doped Aluminum Clusters: MAl12-    (M = Li, Cu, and Au)” R. Pal, L. F. Cui, S. Bulusu, H. J. Zhai, L. S. Wang, and X. C. Zeng J.   Chem. Phys. 128,   024305-1-8 (2008)

  15. “Endohedral   Stannaspherenes (M@Sn12-): A Rich Class of Stable   Molecular Cage Clusters”, L. F. Cui,   X. Huang, L. M. Wang, J. Li, and L. S. Wang, Angew. Chem. Int.Ed., 46, 742-745 (2007)

  16. “Photoelectron   Spectroscopic and Computational Studies of Sodium Auride Clusters NanAun-    (n = 1–3)”, L. F. Cui, X. Li,   L. S. Wang, Y. C. Lin, and D. Sundholm, J. Phys. Chem. A, 111, 7555-7561 (2007)

  17. “Evolution of electronic properties of Snn-    (n = 4 – 45) clusters by photoelectron spectroscopy”, L. F. Cui, L.   M. Wang, and L. S. Wang, J. Chem.   Phys., 126, 064505 (2007)

  18. “Sn122-:   Stannaspherene”, L. F. Cui, X. Huang, L. M. Wang,   D. Y. Zubarev, A. I. Boldyrev, J. Li, and L. S. Wang, J. Am. Chem. Soc. , 128, 8390-8391 (2006)

  19. “Pb122-:   Plumbaspherene”, L. F. Cui, X.   Huang, L. M. Wang, J. Li, and L.   S. Wang, J.Phys. Chem. A,110, 10169-10172 (2006)    (Featured on cover)

  20. “Photoelectron Spectroscopy of AlnD2-    (n = 3-15): Observation of Chemisorption and Physisorption of Di-Deuterium   on Aluminum Cluster Anions”, L. F. Cui, X. Li, and L. S. Wang, J. Chem. Phys.,   124, 054308-1-5 (2006)

  21. “On the Structure and Chemical Bonding of   Si62- and Si62- in NaSi6-    upon Na+ Coordination”,   D. Y. Zubarev, A. N. Alexandrova, A. I. Boldyrev, L. F. Cui, X. Li, and L. S. Wang, J. Chem. Phys., 124, 124305-1-13 (2006)

  22. “Experimental   and Computational Studies of Alkali-Metal Coinage-Metal Clusters”, Y. C.   Lin, D. Sundholm, J, Juselius, L.   F. Cui, X. Li, H. J. Zhai and L.   S. Wang, J. Phys. Chem. A, 110, 4244-4250 (2006)

  23. “Structural   Evolution of Anionic Silicon Clusters Sin (20 ≤ n ≤ 45)”, J. Bai, L. F. Cui, J. Wang, S. Yoo, X. Li,   J. Jellinek, C. Koehler, T. Frauenheim, L. S. Wang and X. C. Zeng, J. Phys. Chem. A, 110, 908-912 (2006)

  24. “Magnetic   Properties in Transition-Metal-Doped Gold Clusters: M@Au6 (M =   Ti , V , Cr)”, X. Li, B.   Kiran, L. F. Cui, and L. S. Wang, Phys. Rev. Lett. 95, 253401, 1-4 (2005)

  25. “Chemical   Bonding in Si52- and NaSi5-    via Photoelectron Spectroscopy and ab Initio Calculations”, D. Yu.   Zubarev, A. I. Boldyrev, X. Li, L.   F. Cui and L. S. Wang, J.   Phys. Chem. A, 109,   11385-11394 (2005)

  26. “Electronic   and Structural Evolution and Chemical Bonding in Ditungsten Oxide   Clusters:W2On- and W2On    (n= 1-6)”, H. J. Zhai, X. Huang, L.   F. Cui, X. Li, J. Li, and L.   S. Wang, J. Phys. Chem. A, 109, 6019-6030 (2005)

  27. “Electronic   Structure and Chemical Bonding in MOn- and MOn    Clusters (M = Mo, W; n = 3-5): A Photoelectron Spectroscopy and Ab   Initio Study”, H. J. Zhai, B. Kiran, L. F. Cui, X Li, D. A. Dixon, and L. S. Wang, J. Am. Chem. Soc.,126, 16134-16141 (2004)

  28. "SiAu4: Aurosilane", B. Kiran, X. Li, H. J. Zhai,   L. F. Cui, and L. S. Wang, Angew. Chem. Int. Ed. 43, 2125-2129 (2004)

 

专利

  1. L.F   Cui, C.K.   Chan, R.   Ruffo, H.   Peng, and Y.   Cui, “Crystalline-Amorphous Nanowires for Battery Electrodes” US   2011/0151290 A1 (2011)

  2. L.F. Cui,   L. Hu, and Y. Cui, “Nanotube-Based Nanomaterial Membrane” US 2011/0256451   A1 (2011)

  3. L.F. Cui,   “High Capacity Electrode Materials Enhanced by Amorphous Silicon”, WO   2011/068911 A2 (2011)

 

学术讲座

  1. “Carbon Nanotube-Silicon Composite Films as   High Capacity Anode for Lithium Ion Batteries ”, Materials Research   Society Spring Meetings, San Francisco, 2010

  2. “Silicon based high capacity anode materials for   lithium ion batteries”, Stanford Institute for Materials & Energy   Science (SIMES) Annual Meeting, 2010

  3. “Core-shell designed silicon nanowires for high   capacity and high current battery electrodes”, Electrochemical Society 215th    Meeting, San Francisco, 2009

  4. “Crystalline-amorphous core-shell silicon   nanowires for high capacity and high current battery electrodes”,   Materials Research Society Spring Meetings, San Francisco, 2009

  5. “Sn122–:   Stannaspherene”, American Chemical Society National   Meetings, San Francisco,   2006

  6. “Sn122–:   Stannaspherene”, Chemical Structure   & Dynamics Seminar Series, Pacific Northwest National Laboratory,   2006

  7. “Photoelectron Spectroscopic studies of silicon   clusters and aluminum hydride clusters”, Gordon Research Conferences: Clusters, Nanocrystals &   Nanostructures, Connecticut College, 2005

  8. “Structural Evolution of Silicon   Nanoclusters Sin (20   ≤ n ≤45)”, Chemical Structure & Dynamics   Seminar Series, Pacific Northwest National Laboratory, 2005

  9. “Study of   Atomic Clusters using Photoelectron Spectroscopy”, Materials Science Program Seminar, Washington State   University, 2003