基本情况

胡宪伟,东北大学工学博士,现任东北大学冶金学院党委副书记、纪委书记,轻金属冶金研究所所长。发表论文200余篇,其中SCI、EI检索150余篇;以第二作者出版译著一部;授权发明专利20余项。


工作经历

2021.01-至今,东北大学,冶金学院,教授;

2017.11-2018.12,美国犹他大学,冶金工程系,访问学者;

2015.12-2020.12,东北大学,冶金学院,副教授;

2012.01-2015.11,东北大学,材料与冶金学院,副教授;

2009.03-2011.12,东北大学,材料与冶金学院,讲师


研究领域

铝电解;熔盐结构;熔盐电化学


科研项目

作为项目负责人完成或正在承担以下项目:

  1. 国家自然科学基金面上项目:“Raman光谱法快速联测铝电解质分子比和氧化铝浓度的基础研究”,2020-2023.
  2. 国家自然科学基金面上项目:“含锂盐、钾盐铝电解质体系的电化学原位Raman光谱研究”,2015-2018.
  3. 国家自然科学基金青年基金课题:“铝精炼电解质熔盐结构的Raman光谱研究”,2011-2013.
  4. 国家重点研发计划课题子课题:“高温熔融金属泄露流淌快速耐火阻隔技术及装备-2”,2017-2020.
  5. 国家科技支撑计划子课题:“复杂电解质体系Li、K元素浓度的控制与工艺优化”,2013-2015.
  6. 国家科技支持计划课题子课题:“低温新技术在400kA级铝电解系列中的应用”,2009-2010.
  7. 辽宁省自然基金项目:“Raman光谱原位测定铝电解质参数基础研究”,2019-2021.
  8. 教育部中央高校基本科研业务费重点科学研究引导项目:“铝电解废阴极炭块的NaOH亚熔盐资源化、无害化处理研究”,2022-2024.
  9. 教育部中央高校基本科研业务费博士生科研创新项目:“Fe、Zn、Co基MOFs衍生物电极材料的可控合成及在锂、镁离子电池中的应用”,2021-2022.
  10. 教育部中央高校基本科研业务费青年教师科研创新基金:“铝电解体系氧化铝溶解行为和浓度分布的原位光纤Raman光谱研究”,2016-2017.
  11. 教育部中央高校基本科研业务费青年教师科研创新基金:“含锂、钾铝电解质中电极过程机理的电化学原位Raman光谱研究”,2014-2015.
  12. 教育部中央高校基本科研业务费青年教师科研启动课题:“AlF3-NaF-CaF2BaF2)熔盐结构Raman光谱研究”,2010-2011;
  13. 山东魏桥创业集团有限公司 教育部产学合作协同育人项目:“以科研和实践为导向的冶金工程专业课程教学模式的应用”,2021-2022.
  14. 企业项目:“工业铝电解质成分及初晶温度的测定”,2010.
  15. 企业项目:“河南中孚实业股份有限责任公司400kA铝电解槽物理场测试”,2011.

并参与多项国家“973”、“863”、支撑计划,国家自然科学基金,国家工信部项目,以及其他省部级项目和企业横向项目。


论文发表



[1] Xu Can, Hu Xianwei*, et al. Raman spectroscopy and quantum chemical calculation on SmCl3 -KCl-LiCl molten salt system [J]. Journal of Molecular Liquids, 2024, 394: 123693.

[2] 谭雅婕,胡宪伟*等. 氟化氢在氧化铝表面吸附机理的Al8O12团簇模型量子化学计算[J]. 过程工程学报,2024,24(2):218-226.

[3] Meng Qingling, Hu Xianwei*, et al. In-situ surface-enhanced Raman scattering on imidazole-based ionic liquids at variable temperatures[J]. Journal of Molecular Liquids, 2024, 396: 123980.

[4] 张文帝,胡宪伟*等. 熔融NaF-AlF3-Al2O3-MF (M=Ca, Li, K)的微观性质及拉曼光谱的第一性原理分子动力学研究[J]. 轻金属,2024,(12):12-20.

[5] 申翰林,李卓,胡宪伟*等. 金属-有机框架材料在储能领域的应用[J]. 化学进展,2024,36(5):724-740.

[6] Zhang Yifan, Hu Xianwei*, et al. Clean separation of vanadium from NaVO3 in NaF-KF-AlF3 molten salt by electrochemical reduction[J]. Separation and Purification Technology, 2023, 312: 123389.

[7] Xu Can, Hu Xianwei*, et al. Raman spectroscopy and quantum chemical calculation on YCl3-KCl molten salt system[J]. Rare Metals, 2023, 42(11): 3886-3896.

[8] Zhang Yifan, Hu Xianwei*, et al. Experimental and quantum chemical investigations on generation mechanism of Al-V intermediate alloy by aluminothermic reduction of NaVO3[J]. Journal of Alloys and Compounds, 2023, 945: 169252.


[9] Zhang Wendi, Hu Xianwei*, et al. Theoretical investigation on 1-Ethyl-3-Methylimidazolium fluoride: A DFT study[J]. Science of Advanced Materials, 2023, 14 (11): 1732-1740.

[10] Zhang Yifan, Hu Xianwei*, et al. Study on the decomposition mechanism of K3AlF6 by quantum chemical calculations[J]. Russian Journal of Physical Chemistry A, 2023, 97: 997-1006.

[11] 汤帅,胡宪伟*等. 氧化对熔融NaCl-KCl-K2TiF6体系离子结构的影响[J]. 中国有色金属学报,2023,33(2):590-597.

[12] 许粲,胡宪伟*等. 拉曼光谱法在稀土氯化物熔盐体系研究的应用[J]. 冶金分析,2023,43(10):10-18.

[13] 张文帝,胡宪伟*等. 基于Raman光谱表征的NaOH亚熔盐浸出铝电解废旧阴极固体产物中碳材料石墨化度研究[J]. 轻金属,2023,23(11):24-29.

[14] 李代旭,胡宪伟*等. NaOH亚熔盐处理铝电解废阴极炭块[J]. 材料与冶金学报,2023,22(4):321-329.

[15] Li Zhuo, Hu Xianwei*, et al. Multi-scale study on a synergetic multimetal-based selenide anode with nitrogen-doped porous carbon support for high-performance lithium storage[J]. Journal of Alloys and Compounds, 2022, 919: 165841.

[16] Li Zhuo, Hu Xianwei*, et al. Porous ZnO Nanosphere inherently encapsulated in carbon framework as a high-performance anode for Ni–Zn secondary batteries[J]. Frontiers in Chemistry, 2022, 10: 936679.

[17] Tang Shuai, Hu Xianwei*, et al. Dissolution reaction of TiO2 in molten 6.58NaF-AlF3:A Raman spectroscopy and computational simulation study[J]. Journal of Molecular Liquids, 2022, 367(6): 120431.

[18] Zhang Yifan, Hu Xianwei*, et al. Quantum chemical calculation on the decomposition mechanism of Na3AlF6[J]. Russian Journal of Physical Chemistry A, 2022, 96(5): 1035-1043.

[19] 孟庆龄,胡宪伟*等. 温度对银基底表面增强拉曼散射效应的影响[J]. 光子学报,2022,51(2):367-376.

[20] Hu Xianwei*, Deng Wentao, Shi Zhongning, et al. Solubility of CO2 in molten Li2CO3-LiCl[J]. Journal of Mining and Metallurgy Section B-Metallurgy, 2021, 57(2): 279-284.

[21] Chen Peng, Hu Xianwei*, Wu Yuping*, et al. An artificial polyacrylonitrile coating layer confining zinc dendrite growth for highly reversible aqueous zinc - based batteries[J]. Advanced Science, 2021, 8(11): 2100309.

[22] Lin Ming, Hu Xianwei*, Shi Zhongning, et al. Raman spectroscopy and quantum theory calculations on complexes in the KF-AlF3-Al2O3 system[J]. Journal of Molecular Liquids, 2021, 326: 115267.

[23] Li Zhuo, Hu Xianwei*, Shi Zhongning, et al. MOF-derived iron sulfide nanocomposite with sulfur-doped carbon shell as a promising anode material for high-performance lithium-ion batteries[J]. Journal of Alloys and Compounds, 2021, 868: 159110.

[24] Li Zhuo, Hu Xianwei*, Shi Zhongning, et al. MOF-derived Fe3O4 hierarchical nanocomposites encapsulated by carbon shells as high-performance anodes for Li-storage systems[J]. Journal of Alloys and Compounds, 2021, 875: 159906.

[25] Yu Jiangyu, Liu Chengyuan, Hu Xianwei*, et al. A novel AlCl3-[EMIM][TF2N] electrolyte for rechargeable aluminum-ion battery[J]. Journal of Physics: Conference Series, 2021, 2044: 012048.

[26] 胡宪伟*,田义凡,文佳. Fe-MOF衍生的Fe2O3@C锂离子电池负极材料的制备及其电化学性能[J]. 功能材料,2021,6(52):7137-7142.

[27] 李博,胡宪伟*,李卓等. V2C@MoS2复合材料的制备及其储锂性能研究[J]. 功能材料,2021,52(9):9083-9094.

[28] 于江玉,胡宪伟*,刘成员等. MF-ZrF4(M=Li,Na,K)体系离子结构的Raman光谱研究[J]. 材料与冶金学报,2021,80(4).

[29] Lin Ming, Hu Xianwei*, Shi Zhongning, et al. Existence of Al2F7 in molten MF–AlF3 (M = K, Cs) systems as determined by Raman spectroscopy and structural simulation[J]. Journal of Energy Chemistry, 2020, 44: 19-23.

[30] Lin Ming, Hu Xianwei*, Shi Zhongning, et al. Investigation of the ionic structure of molten 1.5–8 KF-AlF3 salts with Raman spectroscopy[J]. JOM, 2020, 72(1): 278-286.

[31] Lin Ming, Hu Xianwei*, Yu Jiangyu, et al. Morphology of alumina in NaF-AlF3 systems determined by Raman spectroscopy and quantum mechanical calculations[J]. Journal of Molecular Liquids, 2020, 315: 113747-113754.

[32] Li Zhuo, Hu Xianwei*, Shi Zhongning, et al. MOFs-derived metal oxides inlayed in carbon nanofibers as anode materials for high-performance lithium-ion batteries[J]. Applied Surface Science, 2020, 531: 147290.

[33] Li Zhuo, Han Lu, Wang Yongfei, Li Xinyan, Lu Jinlin, Hu Xianwei*. Microstructure characteristics of cathode materials for rechargeable magnesium batteries[J]. Small, 2019, 15(32), 1900105.

[34] Hu Xianwei*, Deng Wentao, Shi Zhongning, et al. Solubility of CO2 in Molten Li2O-LiCl System: A Raman Spectroscopy Study[J]. Journal of Chemical and Engineering Data, 2019, 64(1): 202-210.

[35] Hu Xianwei*, Li Bo,Yu Jiangyu,et al. Raman spectroscopy on the KBF4–KF–KCl molten salt system[A]. Characterization of Minerals, Metals, and Materials 2019[C]. San Antonio: Minerals, Metals & Materials Soc, 2019:371-377.

[36] Hu Xianwei*,Li Yue,Yu Zongxin,et al. Thermal stability of sodium nitrate–sodium nitrite melts: a Raman spectra study[J]. Spectroscopy Letters,2018, 51(7): 350-355.

[37] 胡宪伟*,李博,张璇等. KF-KBF4 熔盐结构的Raman 光谱表征[J]. 中国有色金属学报,2018,28(10):2120-2126 .

[38].胡宪伟*,史向凯,张宽等. NaNO3KNO3NaNO2熔盐的Raman光谱测定与计算[J].太阳能学报,2018,39(4):952-956.

[39].Hu Xianwei*Yu Zongxin, Gao Bingliang, et al. Equilibrium between NO3- and NO2- in KNO3-NaNO2 melts: a Raman spectra study[J]. Chinese Optics Letters, 2014, 12(9): 093001-5.

[40].胡宪伟*,盛卓,高炳亮等. 电化学原位拉曼光谱技术在高温熔盐中的应用[J]. 冶金分析,2014,34(8):32-38.

[41].Hu Xianwei*, Li Huan, Gao Bingliang, et al. A light-through-side cell and co-used furnace designed for micro-Raman spectra study on volatile melts[J]. Chinese Chemical Letters, 2012, 23(11): 1291-1294.

[42]. 胡宪伟*,高炳亮,刘敬敬等. A closed sample cell and co-used furnace designed for micro-Raman spectra study on volatile melts[J]. 光散射学报,2012,24(4):397-401.

[43]. Hu Xianwei*, Liu Jingjing, Li Huan, et al. Micro-Raman Spectra research on NaF-AlF3-NaCl melts[A]. Light Metals 2012[C]. Orlando: Minerals, Metals & Materials Soc, 2012:799-802.

[44]. Hu Xianwei*, Li Lin, Gao Bingliang, et al. Thermal decomposition of ammonium hexafluoroaluminate and preparation of aluminum fluorde[J]. Transactions of Nonferrous Metals Society of China, 2011, 21(9): 2087-2092.

[45]. Hu Xianwei*, Qu Junyue, Gao Bingliang, et al. Raman spectroscopy and ionic structure of Na3AlF6-Al2O3 melts[J]. Transactions of Nonferrous Metals Society of China, 2011, 21(2): 402-406.

[46]. Hu Xianwei*, Gao Bingliang, Li Lin, et al. A sample cell and furnace used for micro-Raman spectroscopy of volatile liquid[A]. 9th International Symposium on Molten Salts Chemistry and Technology[C]. Trondheim: MS9 organizing committee, 2011: 401-406.

[47]. Hu Xianwei* Wang Zhaowen, Gao Bingliang, et al. Structural entities in NdF3-LiF[J]. Transactions of Nonferrous Metals Society of China, 2010, 20(12): 2387-2391.

[48]. Hu Xianwei*, Wang Zhaowen, Gao Bingliang, et al. Density and ionic structure of NdF3-LiF melts[J]. Journal of Rare Earths, 2010, 28(4): 587-590.

[49]. Hu Xianwei*, Wang Zhaowen, Yu Yaxin, et al. Dissolution kinetics of Nd2O3 in NdF3-LiF-Nd2O3 melts[J]. Rare Metals, 28(SI), 2009: 719-725.

[50]. Hu Xianwei*, Wang Zhaowen, Gao Bingliang, et al. Equivalent conductivity and its activation energy of NaF-AlF3 melts[J]. Transactions of Nonferrous Metals Society of China, 2009, 19(3): 719-723.

[51]. Hu Xianwei*, Wang Zhaowen, Gao Bingliang, et al. Research on form of Nd-F-O complex ions in NdF3-LiF-Nd2O3 melts[A]. In Proceedings of 2009 World Non-Grid-Connected Wind Power and Energy Conference[C]. Nanjing: Institute of Electrical and Electronics Engineers, Inc.,2009: 462-466.

[52]. 胡宪伟,王兆文,陈广华等. 酸性NaF-AlF3熔盐离子结构的Raman光谱[J]. 中国有色金属学报,18(10),2008:1914-1919.

[53]. 胡宪伟,王兆文,高炳亮等. NdF3-LiF-Nd2O3系熔盐电导率的CVCC法研究[J]. 东北大学学报(自然科学版),29(9),2008:1294-1297.

[54]. 胡宪伟,王兆文,路贵民等. 连续变化电导池常数法测定电导率的等效电路分析及应用[J]. 中国有色金属学报,18(3),2008:551-556.

[55]. 胡宪伟,王兆文,罗旭东等. 氟化物熔盐中含钕及含钕-氧络合离子存在形式的研究[J].稀土,29(5),2008:58-60.

[56]. Hu xianwei, Wang zhaowen, Shi Zhongning et al. Structural entities in NdF3-LiF[A]. 2008 Joint Symposium on Molten Salts[C]. Kobe: Organizing committee of 2008 Joint Symposium on Molten Salts, 2008: 166-171.

[57]. Hu xianwei, Wang zhaowen, Gao bingliang et al. Ionic sructue of cryolite-based melts[A]. 2008 Joint Symposium on Molten Salts[C]. Kobe: Organizing Committee of 2008 Joint Symposium on Molten Salts, 2008: 90-97.

[58]. Hu xianwei, Wang zhaowen, Shi Zhongning et al. Electrical conductivity and Nd solubility of NdF3-LiF-Nd2O3 melts[A]. Characterization of Minerals, Metals and Materials[C]. Orlando: Minerals, Metals & Materials Soc, 2007: 77-80.

[59]. Hu xianwei, Wang zhaowen, Shi Zhongning et al. Study on AC impedance equivalent circuit and experimental condition for solution and melts electrical conductivity measurement by CVCC technique [A]. Proceedings of Non-grid-connected Wind Power Systems[C]. Shanghai: Global Wind Energy Council, 2007: 303-312.
[60]. Hu Xianwei, Wang Zhaowen, Shi Zhongning et al. Nd2O3 solubility in NdF3-LiF-Nd2O3 melts[A]. Proceedings of Non-grid-connected Wind Power Systems[C]. Shanghai: Global Wind Energy Council, 2007: 284-286.

[61]. 胡宪伟,王兆文,高炳亮等. 基于AlF63-二步分解机制的Na3AlF6-AlF3熔盐的电导率模型化研究[J]. 东北大学学报(自然科学版),27(S2),2006:81-84.






学术专著


高炳亮,胡宪伟,石忠宁,王兆文.熔融电解质的物理化学分析(译). 冶金工业出版社,共44万字,个人负责12万字.



授权专利

  1. 胡宪伟,王兆文,高炳亮等.一种工业铝电解质电导率在线测量装置及测量方法. ZL201010263321.2,2010-08-26.
  2. 胡宪伟,高炳亮,李欢等.高温挥发性熔盐Raman光谱测量用显微热台. ZL201111329976.X,2011-10-26.
  3. 胡宪伟,包莫日根高娃,王兆文等.一种铝液-熔盐法生产铝锆合金的方法. ZL201410034232.9,2014-01-24.
  4. 胡宪伟,盛卓,高炳亮等. 熔盐电化学原位Raman光谱测量用显微热台和样品池. ZL201410836981.3,2014-12-29.
  5. 胡宪伟,陈鹏,黄椿森等. 一种电化学原位Raman光谱测量用显微热台和样品池系统. ZL201610263691.3,2016-04-26.
  6. 胡宪伟,邓文涛,王志鑫等. 一种基于Raman光谱法测量高温熔盐体系中气体溶解量的显微热台装置. ZL201710191627.3,2017-03-28.
  7. 胡宪伟,王志鑫,张一帆等. 一种NaOH亚熔盐处理铝电解废旧阴极炭块的方法. ZL201811583104.4,2018-12-24.
  8. 胡宪伟,郭瑞东,张文帝等. 一种高温熔盐动态Raman光谱原位检测炉. ZL 202410218939.9,2024-02-28.
  9. 胡宪伟,郭瑞东,张文帝等. 一种基于Raman光谱的铝电解质分子比检测方法. ZL 202410218869.7,2024-02-28.
  10. 胡宪伟,康红光,张晗阳等. 一种硫化铅的制备方法. ZL 202311027020.3,2023-08-14.