正规的买球平台

正规的买球平台:管晓飞

时间:2018-03-01浏览:14443设置

管晓飞课题组介绍


Principal Investigator


管晓飞 Xiaofei Guan (ORCID: 0000-0002-7100-2949)

助理教授、研究员、博士生导师

Assistant Professor, School of Physical Science and Technology, ShanghaiTech University

Address:393 Huaxia Middle Road, SPST 5-403.I, Shanghai, China 201210
E-mail:guanxf@shanghaitech.edu.cn


Appointments and Education:

Assistant Professor, ShanghaiTech University, 2017.11-Present 

Postdoctoral Fellow, Harvard University, 2014.09-2017.09

Postdoctoral Research Associate, Boston University, 2013.09-2014.09

Ph.D. in Materials Science and Engineering, Boston University, 2010.09-2013.09

Graduate Student in Physics, The University of Arizona, 2009.08-2010.08

B.S. in Applied Physics, Nankai University, 2005.09-2009.06


Honors and Awards:

Young Leaders Professional Development Award, The Minerals, Metals and Materials Society (TMS), United States, 2015.

Outstanding PhD Dissertation Award in Materials Science and Engineering, Boston University, 2014.


Research


Our modern society is faced with challenges in energy, environment, and resources. The chemical industry for hydrogen production, for example, is highly energy intensive and also emits a large amount of greenhouse gases. There is an urgent need of technological transformations in the chemical industries for building a sustainable energy future. At ShanghaiTech, our research group is exploring unconventional electrochemical materials and sustainable processes to enable energy, environmental and electronic technologies. Our current projects include:

1. Catalytic synthesis of fuels: designing, preparing and characterizing catalysts & reactors for producing fuels.

2. Critical metals extraction and recycling: developing environmentally friendly electrochemical processes for materials extraction and recycling. 

3. Carbon capture: design and investigate new methods for capturing carbon dioxide from air or flue gas.

4. Complex oxides for energy and electronic applications: materials synthesis, control and characterization of electronic and ionic properties, and nanofabrication of field-effect devices. 

有关能源、环境和资源利用中的关键问题,课题组以电化学为中心提出新思路并且探索解决方案,研究目标是促进碳中和的实现以及可持续能源未来的建设。课题组的主要研究方向包括电化学工程、高温热催化和电催化、金属元素回收、和功能氧化物薄膜材料。欢迎对这些方向感兴趣的助理研究员、博士后、研究生和本科生加入,有意者请直接邮件联系。


课题组正在开展的项目包括:

(1) 催化合成燃料:制备和表征新型催化材料,设计和搭建催化反应器。

(2) 关键金属元素的提取和回收:开发节能并且对环境友好的新型电化学工艺。

(3) 碳捕集:设计和研究直接从空气或从工业废气中捕集二氧化碳的新方法。

(4) 复杂氧化物在能源和电子器件中的应用:加工和表征纳米薄膜器件,并且调控材料的电学性质。


目前,课题组诚聘 "助理研究员" 和 "博士后",研究经历与 "催化" 或者 "电化学" 相关有意向者请直接邮件联系。 




Publications



Papers: (# co-first authors; * corresponding author)

6.  Z. Tang, X. Meng, Y. Shi, and X. Guan*, "Lithium-Based Loop for Ambient-Pressure Ammonia Synthesis in a Liquid Alloy-Salt System", ChemSusChemdoi: 10.1002/cssc.202101571, (2021).

5. C. Zhou#, J. Ni#, H. Chen#, and X. Guan*, "Harnessing Electrochemical pH Gradient for Direct Air Capture with Hydrogen and Oxygen By-Products in a Calcium-Based Loop", Sustainable Energy & Fuels, 5, 4355-4367, (2021).

4. J. Ni, J. Zhou, J. Bing, and X. Guan*, "Recycling the Cathode Materials of Spent Lithium-ion Batteries in a H-Shaped Neutral Water Electrolysis Cell", Separation and Purification Technology, doi: 10.1016/j.seppur.2021.119485, (2021).

3. Z. Tang and X. Guan*, "Lithium Extraction from Molten LiOH by Using a Liquid Tin Cathode", Journal of Sustainable Metallurgy, 7, 203-214, (2021).

2. Q. Yang#, C. Zhou#, J. Ni, and X. Guan*, "Methane Dry Reforming in a Coking- and Sintering-Free Liquid Alloy-Salt Catalytic System", Sustainable Energy & Fuels, 4, 2768-2774, (2020). (Selected a Sustainable Energy and Fuels HOT Article)

1. C. Fleuriault*, X. Guan, and J. Grogan, "Extraction and Recycling of Battery Materials", JOM, 71, 4445-4446, (2019). 


Work prior to joining ShanghaiTech:

1. X. Guan, B.C. Enalls, D.R. Clarke, and P. Girguis, "Iron Sulfide Formation on Iron Substrates by Electrochemical Reaction in Anoxic Conditions", Crystal Growth & Design, 17, 6332-6340, (2017).

2. X. Guan, J. Jiang, J. Lattimer, M. Tsuchiya, C. Friend, and S. Ramanathan, "Hydride-Based Solid Oxide Fuel Cell-Battery Hybrid Electrochemical System", Energy Technology, 5, 616-622, (2017).

3. S. Lee and X. Guan, "Cerium Silicate-Based Thin Film Apatites: High Conductivity and Solid Oxide Fuel Cell Application", MRS Communications, 7, 199-205, (2017).

4. S. Su, U. Pal, and X. Guan, "Solid Oxide Membrane Electrolysis Process for Aluminum Production: Experiment and Modeling", Journal of the Electrochemical Society, 164, F248-255 (2017).

5. Z. Zhang, F. Zuo, C. Wan, A. Datta, J. Kim, J. Rensberg, R. Nawrodt, H.H. Park, T. Larrabee, X. Guan, Y. Zhou, S.M. Prokes, C. Ronning, V.M. Shalaev, A. Boltasseva, M.A. Kats, and S. Ramanathan, "Evolution of Metallicity in Vanadium Dioxide by Creation of Oxygen Vacancies", Physical Review Applied, 7, 034008 (2017).

6. M. Zhang, X. Guan, and J. Howarter, "Recent Developments in Deriving Values from Resource Recovery at Multiple Scales", JOM, 69, 1537-1538 (2017).

7. J. Jiang, X. Guan, J. Lattimer, C. Friend, A. Verma, M. Tsuchiya, and S. Ramanathan, "Experimental Investigation into Tungsten Carbide Thin Films as Solid Oxide Fuel Cell Anodes", Journal of Materials Research, 31, 3050-3059 (2016).

8. Y. Zhou, X. Guan, H. Zhou, K. Ramadoss, S. Adam, H. Liu, S. Lee, J. Shi, M. Tsuchiya, D.D. Fong, and S. Ramanathan, "Strongly Correlated Perovskite Fuel Cells", Nature, 534, 231-234 (2016).

9. X. Guan, U.B. Pal, Y. Jiang, and S. Su, "Clean Metals Production by Solid Oxide Membrane Electrolysis Process", Journal of Sustainable Metallurgy, 2 (2), 152-166 (2016). (Feathered as Cover Article)

10. S. Lee, X. Guan, and S. Ramanathan, "Thin Film Oxy-Apatite Anodes for Solid Oxide Fuel Cells", Journal of Electrochemical Society, 163 (7), F719-727 (2016).

11. X. Guan, U.B. Pal, "Design of Optimum Solid Oxide Membrane Electrolysis Cells for Metals Production", Progress in Natural Science: Materials International, 25 (6), 591-594 (2015).

12. X. Guan, S. Su, U.B. Pal, and A.C. Powell, "Periodic Shorting of SOM Cell to Remove Soluble Magnesium in Flux and Improve Faradaic Efficiency", Metallurgical and Materials Transactions B, 45 (6), 2138-2144 (2014).

13. X. Guan, U.B. Pal, and A.C. Powell, "Environmentally Friendly Solid Oxide Membrane Electrolysis Process for Magnesium Oxide Reduction: Experiment and Modeling", Metallurgical and Materials Transactions E, 1 (2), 132-144 (2014).

14. E.S. Gratz, X. Guan, J. Milshtein, U.B. Pal, and A.C. Powell, "Mitigating the Electronic Current in Solid Oxide Membrane Electrolysis for Magnesium Production", Metallurgical and Materials Transaction B, 45 (4), 1325-1336 (2014).

15. Y. Jiang, J. Xu, X. Guan, U.B. Pal and S.N. Basu (2013), "Production of Silicon by Solid Oxide Membrane-Based Electrolysis Process", MRS Proceedings, 1493, 231-235 (2013).

16. X. Guan, U.B. Pal, S. Gopalan, and A.C. Powell, "LSM (La0.8Sr0.2MnO3-δ)–Inconel Inert Anode Current Collector for Solid Oxide Membrane Electrolysis", Journal of the Electrochemical Society, 160 (11), F1179-F1186 (2013).

17. X. Guan, U.B. Pal and A.C. Powell, "An Environmentally Friendly Process Involving Refining and Membrane Based Electrolysis for Magnesium Recovery from Partially Oxidized Scrap Alloy", JOM, 65 (10), 1285-1292 (2013).

18. X. Guan, U.B. Pal, P.A. Zink and A.C. Powell, "Recycling of Magnesium Alloy Employing Refining and Solid-Oxide-Membrane (SOM) Electrolysis", Metallurgical and Materials Transactions B, 44 (2), 261-271 (2013).



Group Members


   Graduate Students Wang, Xingyuan | Tang, Zujian | Tang, Qijuan | Ni, Jihong | Zhou, Jiayin | Meng, Xian.

   Undergraduate Students Chen, Huiqi | Bing, Jinhong.

   Group Alumni (positions) Xue, Qingjun (Daicel) | Yang, Qinghai (GalaxyCore) | Shi, Yue (Cornell) | Zhou, Congquan (SIMIT).

      (Group photo taken on 2021/01/18. From left to right: Congquan, Zujian, Jihong, Jinhong, Yue, Huiqi, Qijuan, Jiayin, Xian, Qinghai, Xingyuan and Xiaofei.)


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