个人简历

Dr. Hui (Claire) Xiong joined the faculty of the Department of Materials Science and Engineering at Boise State University in 2012. Her current research interests focus on the synthesis, characterization and development of advanced functional nanomaterials for sustainable energy systems.r
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She came to Boise after a postdoctoral fellowship at the Center for Nanoscale Materials at Argonne National Laboratory, where she worked on the development of novel nano-architectured electrode materials for energy storage and conversion. Dr. Xiong also spent a year as a postdoctoral fellow at the School of Engineering and Applied Sciences (SEAS) in Harvard University where her research involved electrochemical characterization of micro-fabricated cathode materials for micro-solid oxide fuel cells. Her education includes a Ph.D. in Analytical Chemistry and Electrochemistry from the University of Pittsburgh, and a B.E. in Applied Chemistry and an M.S. in Inorganic Chemistry, both from East China University of Science and Technology in Shanghai.r
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Educationr
Postdoc in Materials Science and Engineering, Argonne National Lab, 2009-2012r
Postdoc in Materials Science and Engineering, Harvard University, 2008r
Ph.D. in Analytical Chemistry/ Electrochemistry, University of Pittsburgh, 2007r
M.S. in Inorganic Chemistry, East China University of Science and Technology, 2000r
B.E. in Applied Chemistry, East China University of Science and Technology, 1998

研究领域

"""Synthesis and characterization of nanostructured electrode materialsr
Fundamental understanding of the electronic and ionic transport properties of nanomaterials for applications in energy storage and conversionr
Interfacial and surface chemistryr
Advanced functional materials for rechargeable batteries (e.g., Li-ion, Na-ion)r
Radiation effect in ceramic materials"""

近期论文

P. Barnes, K. Smith, R. Parrish, † C. Jones, † P. Skinner, † E. Storch, ║ Q. White, ║ C. J. Deng, D. Karsann, † M. L. Lau, † J. J. Dumais, E. Dufek, and H. Xiong* “A non-aqueous sodium hexafluorophosphate-based electrolyte degradation study: formation and mitigation of hydrofluoric acid”, Journal of Power Sources, 447 (2020), 227363.r
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C. J. Deng, C. R. Ma, M. L. Lau, † P. Skinner, † Y. Z. Liu, W. Xu, H. Zhou, Y. Ren, Y. D. Yin, B. Williford, † M. Dahl, and H. Xiong* “Amorphous and crystalline TiO2 nanoparticle negative electrodes for sodium-ion batteries”, Electrochimica Acta, 321 (2019) 134723.r
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K. A. Smith, A. I. Savva, K. Y. S. Mao, Y. Q. Wang, D. A. Tenne, D. Chen, Y. Z. Liu, P. Barnes, C. J. Deng, D. P. Butt, J. P. Wharry, and H. Xiong* “Effect of proton irradiation on anatase TiO2 nanotube anodes for lithium-ion batteries”, Journal of Materials Science, 54 (2019) 13221-13235.r
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C. R. Ma, X. Li, C. J. Deng, Y. Y. Hu, S. Lee, X. Z. Liao, Y. S. He, Z. F. Ma, and H. Xiong* “Coaxial Carbon Nanotube Supported TiO2@MoO2@Carbon Core-Shell Anode for Ultrafast and High-Capacity Sodium Ion Storage”, ACS Nano, 13 (2019) 671-680.r
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K. A. Smith, A. I. Savva, Y. Q. Wu, D. A. Tenne, D. P. Butt, H. Xiong*, and J. P. Wharry “Effects of intermediate energy heavy-ion irradiation on the microstructure of rutile TiO2 single crystal”, Journal of the American Ceramic Society, 101 (2018) 4357-4366.r
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I. Savva, K. A. Smith, M. Lawson, S. R. Croft, † A. E. Weltner,† C. D. Jones,† H. Bull, ‡ P. J. Simmonds, L. Li, and H. Xiong* “Defect generation in TiO2 nanotube anodes via heat treatment in various atmospheres for lithium- ion batteries”, Physical Chemistry Chemical Physics, 20 (2018) 22537-22546.r
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R. Ma, Z. G. Fu, C. J. Deng, X. Z. Liao, Y. S. He, Z. F. Ma, and H. Xiong* “Carbon-coated FeP nanoparticles anchored on carbon nanotube networks as an anode for long-life sodium-ion storage”, Chemical Communications, 54 (2018) 11348-11351.r
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R. Ma, C. J. Deng, X. Z. Liao, Y. S. He, Z. F. Ma, and H. Xiong* “Nitrogen and Phosphorus Codoped Porous Carbon Framework as Anode Material for High Rate Lithium-Ion Batteries”, ACS Applied Materials & Interfaces, 10 (2018) 36969-36975.r
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R. Ma, C. J. Deng, X. Z. Liao, Y. S. He, Z. F. Ma, and H. Xiong* “Urchin-like MoP Nanocrystals Embedded in N-Doped Carbon as High Rate Lithium Ion Battery Anode”, ACS Applied Energy Materials, 1 (2018) 7140-7145.r
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C. J. Deng, P. Skinner, † Y. Z. Liu, M. L. Sun, W. Tong, C. R. Ma, M. L. Lau, † R. Hunt, † P. Barnes, J. Xu, and H. Xiong* “Li-Substituted Layered Spinel Cathode Material for Sodium Ion Batteries”, Chemistry of Materials, 30 (2018) 8145-8154.r
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P. Barnes, A. Savva, K. Dixon, † H. Bull, ‡ L. Rill, † D. Karsann, † S. Croft, † J. Schimpf, † and H. Xiong* “Electropolishing valve metals with a sulfuric acid-methanol electrolyte at low temperature”, Surface & Coatings Technology, 347 (2018) 150-156.r
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K. A. Smith, A. I. Savva, C. J. Deng, J. P. Wharry, S. Hwang, D. Su, Y. Q. Wang, J. Gong, T. Xu, D. P. Butt, and H. Xiong* “Effects of proton irradiation on structural and electrochemical charge storage properties of TiO2 nanotube electrodes for lithium-ion batteries”, Journal of Materials Chemistry A, 5 (2017) 11815-11824.r
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C. J. Deng, M. L. Lau, † H. M. Barkholtz, H. P. Xu, R. Parrish, † M. Xu, T. Xu, Y. Z. Liu, H. Wang, J. G. Connell, K. A. Smith, and H. Xiong* “Amorphous boron nanorod as an anode material for lithium-ion batteries at room temperature”, Nanoscale, 9 (2017) 10757-10763.r
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K. Smith, R. Parrish, † W. Wei, Y. Z. Liu, T. Li, Y. H. Hu, and H. Xiong* “Disordered 3D Multi-layer Graphene Anode Material from CO2 for Sodium-Ion Batteries”, Chemsuschem, 9 (2016) 1397-1402.r
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H. Xiong, H. Yildirim, P. Podsiadlo, J. Zhang, V. B. Prakapenka, J. P. Greeley, E. V. Shevchenko, K. K. Zhuravlev, S. Tkachev, S. K. R. S. Sankaranarayanan, and T. Rajh “Compositional Tuning of Structural Stability of Lithiated Cubic Titania via a Vacancy-Filling Mechanism under High Pressure”, Physical Review Letters, 110 (2013) 078304-078308.