个人简介:
1968年生,四川省射洪县人;
1991年昆明理工大学有色金属冶金专业本科毕业在四川省会东铅锌矿参加工作;
2000年获中南工业大学有色金属冶金硕士学位;
2007年获北京科技大学材料学博士学位;
1997年获中级职称;
2001−2003年,担任四川省会东铅锌矿副总工程师;
2009年6月晋升为四川大学副教授;
2007年至今,四川大学化学工程学院工作,现任副教授,硕士研究生导师,四川大学低碳循环经济技术研究中心研究成员。
教学及研究成果
[1] Z. Q. Liu*, Y. C. Wang, W. Chu, Z. H. Li, C.C.Ge. Characteristics of doped TiO2 photocatalysts for the degradation of methylene blue waste water under visible light. J.Alloy. Compd., 2010, 501: 54–59.
[2] Z .Q. Liu*, X Yan, W Chu, D D Li. Effects of impurities containing phosphorus on the surface properties and catalytic activity of TiO2 nanotube arrays. Appl. Surf. Sci., 2010, 257: 1295–1299.
[3] Z.Q.Liu*, G. Li, W. Chen. Preparation of ZnFe2O4 nanopowders via sol-gel autoignition method. Powder Metall., 2011, 54(1): 13–18
[4] J.Zheng, Z. Q. Liu*, X. Liu, X. Yan, D. D. Li, W. Chu. Facile hydrothermal synthesis and characteristics of B-doped TiO2 hybrid hollow microspheres with higher photocatalytic activity. J. Alloy. Compd., 2011, 509: 3771–3776.
[5] G. Li, Z. Q. Liu*, J. Lu, L. Wang, Z. Zhang. Effect of calcination temperature on the morphology and surface properties ofTiO2 nanotube arrays. Appl.Surf. Sci, 2009, 255: 7323–7328
[6] G. Li, Z. Q. Liu*, J.Lu, L.Wang, Z.Zhang. Fabrication of TiO2 nanotube arrays via electrochemical anodization in NH4F/H3PO4 electrolyte solution system. Chin. J. Inorg Chem, 2009, 25(6): 1031–1037.
[7] G. Li, Z. Q. Liu*, Z. Zhang, X Yan. Preparation of titania nanotube arrays by the hydrothermal method. Chin J. Catal, 2009, 30(1): 37–42.
[8] G. Li, Z.Q.Liu*, X Yan. Z. Zhang. Preparation of titania nanotube arrays by hydrothermal reaction in combination with anodic aluminum oxide template attached to aluminum substrate. Chin. J. Catal, 2008, 29(8): 680–682.
[9] Z.Q. Liu, Y.P. Zhou, Z.H. Li, Y.C.Wang, C.C. Ge. Enhanced photocatalytic activity of (La, N) co-doped TiO2 by novel TiCl4 sol-gel auto-igniting synthesis. J.Univ.Sci.Technol.B, 2007, 14 (6): 552–557.
[10] Z.Q. Liu, Y.P. Zhou, Z.H. Li, Y.C. Wang, C.C. Ge. Preparation and characterization of (Metal, Nitrogen)-codoped TiO2 by Novel TiCl4 Sol-gel auto-igniting synthesis. RARE METALS, 2007, 26(3): 263–270.
[11] Z.Q.Liu, Z.H. Li, Y.P. Zhou, C.C. Ge. Preparation and characterization of Ag/TiO2-xNx nanoparticles. Materials Science Forum, 2007, 534-536: 105–108.
[12] Z.Q.Liu, C. C. Ge Photocatalysis of Nonmetal Modified TiO2 Induced by Visible Light. Progress in Chemistry, 2006, 18(2/3):168–175.
[13] Z.Q.Liu, Y.P.Zhou, C. C. Ge Investigation of light absorption and photocatalytic performance of doped titania by low temperature combustion syathesis. Rare metal materials and engineering, 2006,35(supplement 2): 104–108.
[14] Z.Q.Liu, C C Ge, Y. P.Zhou. Phase transformation of doped titania nanoparticles preared by sol-gel combustion synthesis. J. Univ. Sci. Tech. B, 2006, 28(2):153–156.
[15] Z.H.Li, Z.Q. Liu, Q.Z.Yan, Y.C.Wang, C.C. Ge. Preparation and performance of titanate nanotube by hydrothermal treatment. RARE METALS, 2008, 27(2): 187–191.
[16] Y.C. Wang, Z.Q. Liu, Z.H.Li, C. C. Ge. Preparation and properties of visible l ight responding N-doped TiO2 nanopowder by hydrothermal synthesis. J. Univ. Sci. Tech. B., 2008, 30(5): 540–543.
[17] Z.H.Li, Z.Q. Liu, Q.Z.Yan, Y.C.Wang, C.C. Ge. The influence of synthesis temperature on the titania nanotube. Function materials, 2007, 38(3): 485–491.
[18] G. D. Lu, Q.Z.Yan, X.T. Su, Z.Q. Liu, C.C. Ge. Progress of porous hydrogels. Progress in Chemistry, 2007, 19(4): 485–493
[19] J. He, M. T. Tan, J.L. Lu, Z.Q. Liu, S.H. Yan, W.Y. Yao. Concentrating Ge in zinc Hydrometallurgical process with hot acid leaching halotrichite method. J. Cent. South Univ. Technol., 2003, 10(4): 307–312.
[20] Z.Q. Liu, F.J. Pan. Treatment of oxidizing calcine of Ag concentrate by oxidizing leaching with hydrochloric acid and leaching with sodium sulfite. Chin. J. Rare Metals, 2004, 28(6): 1029–1033.
[21] Z.Q. Liu, F.J. Pan. Study on germanium recovery from ZnS concentrate leached slag. Nonferrous metals (metallurgy section), 2004, 4: 20–25.
[22] Z.Q. Liu. Problems on clarif ica tion of solution in Zinc hydrometallurgy. Hydrometallurgy of China, 2002, 21(2): 66–69.
[20] Z.Q. Liu, M.T.Tang, Q.M. Fan.Concentration of germanium during Zinc smelting by hot sulphuric acid leaching iron vitriol precipitation. Mining and Metallurgy Engineering, 2000, 20(1): 44–46.
[23] Z.Q. Liu, M.T.Tang, J.L. Lu, J. He, S.H. Yang. Study on behav ior of germanium during neutral leaching of Zinc hydrometallurgy Process. Hydrometallurgy of China, 2000, 19(2), 43–47.
[24] Z.Q. Liu, M.T.Tang. A removal study of cobalt in Zinc sulfate solution with antimony salt method at low temperature. Hydrometallurgy of China, 1999, 4, 22–27.
[25] F.J. Pan, Z.Q. Liu. Industrial practices of concentration of germanium in process flowsheet of wet Zinc smelting. Mining and Metallurgy Engineering, 2004, 24(4): 47–49.
[24] X.F.Zou, Z.Q. Liu, K.Zhen. X.Z.Zhang. Utilization of post-cadm ium-leached-out residue forproducing copper sulphate. Mine reseach and development, 1999, 19 (supplement): 60–62.
[26] J. He, J.L. Lu, Z.Q. Liu, M.T.Tang, S.H. Yang, W.Y. Yao, H.G. Chen. study on enrichment of germanium in hot acid leaching and zinc smelting with iron vitriol method. Journal of Guandong nonferrous metals, 2002,12 (special in rare and scattered metals ): 21–28.
[27] X.T. Su, Q.Z. Yan, Z.Q. Liu, W.F. Zhang, et al. Sol-gel auto-ignition synthesis: overview of some recent results. Int. J Self-Propag High-Temp Sy., 2005, 14(4): 273–281.
[28] X.Yan, Z.Q. Liu*, D.D.Li, G. Li. Preparation and photocatalytic reductive performance of Cu-doped TiO2 nanotube arrays. Function materials,,2010, 41(7): 1278–1281.
[29] Y. T. Zhang, Z.Zhang, X.Z.Yuan, X.G.You, Z.Q. Liu. Microwave drying process and mineral phase analysis of low-grade complex laterite ores. J.Univ.Sci.Technol.B, 2010, 32 (9): 1119–1123.
[30] D. D. Li, Z.Q. Liu*, X.Yan, J.Zheng, X.Liu. Photo-electro catalytic oxidation of ammonia nitrogen wastewater on TiO2 nanotube arrays. Chin. J. Inorg Chem, 2011, in press.
授权专利专利
1、刘中清,唐谟堂,何静,等. 热酸浸出-铁矾法炼锌工艺中锗和银的富集方法. 中国发明专利,公开号CN1345981A,公开日2002-04- 24;
2、葛昌纯,刘中清. 一种溶胶−凝胶低温燃烧合成掺杂二氧化钛光催化剂的方法。中国发明专利,公开号CN1712129 A,公开日2005-12- 28;
3、刘中清, 李丹丹, 颜欣. 一种光电催化处理工业废水的方法. 中华人民共和国国家知识产权局, CN201010157248.0, 中国, 2010/4/23(中国知识产权网)。刘中清 副教授 -- 研究工作主要研究方向:
1、纳米材料包括纳米粉体、纳米结构材料的制备、性能及其在催化合成与催化降解环境中有毒有害污染物中的应用研究;
2、复杂有色金属矿物及二次资源中稀散金属、贵金属等的绿色综合回收技术;
3、有色金属功能材料,合金及单一及复合氧化物和金属超细粉体的制备与应用;
4、冶金生产过程优化与智能控制。
科研工作:
1、二氧化碳高压光电催化还原及其机理研究,国家自然科学基金项目(2008~2010),项目编号:50774053,项目负责人;
2、光电催化处理高氨氮污水关键技术研究与工程示范,四川省科技支撑项目(2009~2011),计划编号:2009GZ0224,项目负责人;
3、复杂红土镍矿流态化选择性还原技术研究,国家高技术研究发展计划(863计划)(2008~2010),项目编号:2008AA06Z110,排名第三;
4、超大规模集成电路铜互连扩散阻挡层性能评价,四川省科技攻关项目(2008~ 2010),项目编号:07FG001-017,排名第三;
5、云南6300KV•A精炼炉工程设计,企业横向,排名第二, 已结题。
6、深部煤炭开发中煤与瓦斯共采理论2011CB201200,课题二:深部采动多尺度破断煤岩体瓦斯吸附、解吸规律(2011CB201202),国家973计划,项目参与人。
教学工作
主讲《钢铁冶金学》、《火法冶金设备》、《湿法冶金设备》等课程。主要从事湿法冶金专业实验研究,本科毕业论文。已培养硕士研究生并毕业一名,在读两名。刘中清 副教授 -- 获奖及其他曾获1997年度四川省科技成果奖励一项,第八完成人;2004年度四川省科技进步三等奖,第三完成人;“Materials Science and Engineering B”, “Surface and Interface Analysis ”, “Corrosion Science”, “ Chem Phys Chem”等刊物审稿人。