个人简介
教授,博士生导师,教育部新世纪人才计划入选者(2008 年),国土资源部天然气水合物重点实验室学术委员会委员,中国可再生能源学会天然气水合物专业委员会委员,美国地球物理学会终身会员,中国矿物岩石地球化学学会终身会员。主要从事海洋天然气水合物成矿机理与地球化学勘查技术等研究。担任《Geochimica et Cosmochimica Acta》、《Chemical Geology》、《Journal of Geochemical Exploration》、《European Journal of Mineralogy》、《International Journal of Greenhouse Gas Control》、《Journal of Natural Gas Chemistry》、《Review of Scientific Instruments》、《Applied Spectroscopy》、《Journal of Raman Spectroscopy》、《Fluid Phase Equilibria》、《Journal of Chemical & Engineering Data》、《Journal of Molecular Structure》、《Chemical Papers》在内的地球化学、光谱学、科研仪器、天然气化学化工领域十多种国际期刊的审稿人。
☆主要国际合作伙伴
△ 美国地质调查局I-Ming Chou教授,海外华人地球科学协会主席,著名实验地球化学家;
△ 美国地质调查局Robert C. Burruss教授,油气地球化学、流体包裹体界知名专家 ;
△ 法国洛林大学Jean Dubessy教授,前GeoRaman 主席、法国国家研发中心(CNRS)主任;
△ 那不勒斯“费德里科二世”大学Benedetto De Vivo教授,国际期刊“Journal of Geochemical Exploration ”杂志主编;
△ 加拿大魁北克大学里穆斯基分校海洋研究所Huixiang Xie教授,海洋化学家。
☆ 科研项目
♦ 国家重点研发计划课题“近海底原位多参量地球化学测量技术与装置研究”(2016YFC0303902),2016.07-2020.12;
♦ 国家自然科学基金项目 “海底未固结沉积物中天然气水合物动态聚散与孔隙流体地球化学时空响应动力学研究” (41176047),2012.01-2015.12;
♦ 国家水合物专项协作课题(GZH201100305-07-01)“天然气水合物微观成矿过程和动态聚散规律研究” ,2011.05-2018.12;
♦ 国家水合物专项协作课题(HD-JJHT-2011-5-1)“天然气水合物成藏数值模拟方法研究” ,2012.05-2015.12;
♦ 国家高技术研究发展计划(863计划)子课题“天然气水合物成矿过程数值模拟技术研究”(2009AA09A202-3),2009.01-2011.12;
♦ 国家重点基础研究发展计划(973计划)“南海北部陆坡天然气水合物成藏机理与资源分布规律”子课题“南海北部天然气水合物成藏的动力学机制” ,2009.01-2012.12;
♦ 教育部科学技术研究重点项目“拉曼光谱法测定H2O-CO2-CH4- NaCl体系包裹体的组成与密度”(N0.109108),2009.04-2010.12;
♦ 国家自然科学基金项目“海水-水合物体系甲烷扩散-水合动力学的拉曼光谱研究”(40603016),2007.01-2009.12;
♦ 中国科学院知识创新工程重要方向项目“深部地质流体的物理化学性质和演化机制:热力学、分子动力学和实验综合研究” 中课题“深部地质流体的物理化学性质实验研究”(kzcx2-yw-124-02), 2007.01-2009.12;
♦ 国家高技术研究发展计划(863计划)“天然气水合物探测技术”课题中三级课题“稳定带模拟与水合物定位预测技术”(2003AA611020/03-02),2004.01-2005.10;
♦ 国家高技术研究发展计划(863计划)“天然气水合物探测技术”课题中“生物成因天然气水合物成藏动力学模拟及稳定带预测” 三级课题(2001AA611020/03-04),2002.01-2003.12;
♦ 国家水合物专项课题“我国海域天然气水合物资源评估及资源前景研究”,参加天然气水合物资源评价研究,2001.8-2008.12;
☆ 学术成果
科研奖励
⌂ 吕万军,2007,“东海陆坡天然气水合物资源调查评价”,国土资源部科学技术奖二等奖(KJ2007-2-24-R3).
☆ 主讲课程
★ 《海洋矿产资源》(本科生)
★ 《海洋地球化学》(本科生)
★ 《海洋地质与资源》(本科生)
★ 《海洋调查技术与方法》(本科生)
★ 《海洋资源》(研究生)
★ 《海洋地质新进展》(研究生)
★ 《海洋科学前沿》(研究生)
★ 《研究生专业英语》(研究生)
联系方式
湖北省武汉市洪山区鲁磨路388号中国地质大学海洋学院(邮编:430074)
研究领域
目前主要从事深海资源探测技术与装备研究、海洋水合物地质地球化学、成矿成藏过程实验模拟、数值模拟技术与软件开发、实验地球化学技术、包裹体地球化学等方面的研究:u 海洋天然气水合物成矿动力学、水合物资源勘查与开发
深海探测技术与装备研究、激光谱学观测技术研发
地质流体热动力学、流体包裹体地球化学、实验地球化学
近期论文
查看导师新发文章
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Wu Xiangen, Lu Wanjun, Ou Wenjia, Marie-Camille Caumon, Jean Dubessy. 2016. Temperature and salinity effects on the Raman scattering cross section of the water OH stretching vibration band in NaCl aqueous solutions from 0 to 300 °C. Journal of Raman Spectroscopy,DOI: 10.1002/jrs.5039.
Ou Wenjia, Lu Wanjun, Qu Kang, Geng Lantao, I-Ming Chou. 2016. In situ Raman spectroscopic investigation of flux-controlled crystal growth under high pressure: A case study of carbon dioxide hydrate growth in aqueous solution. International Journal of Heat and Mass Transfer, 101: 834-843.
Hu Qingcheng, Guo Huirong, Lu Xinbiao, Lu Wanjun, Chen Ying, Zhu Yan, Geng Lantao. 2016. Determination of P–V–T–x properties of the CO2–H2O system up to 573.15 K and 120MPa—Experiments and model. Chemical Geology, 424: 60-72.
Zhang Jianli, Qiao Shaohua, Lu Wanjun, Hu Qingcheng, Chen Shuguang, Liu Yuan. 2015. An equation for determining methane densities in fluid inclusions with Raman shifts. Journal of Geochemical Exploration, in press.
Ou Wenjia, Guo Huirong, Lu Wanjun, Wu Xiangen, I-Ming Chou. 2015. A re-evaluation of the effects of temperature and NaCl concentration on quantitative Raman spectroscopic measurements of dissolved CH4 in NaCl aqueous solutions: Application to fluid inclusion analysis. Chemical Geology, 417: 1-10.
Ou Wenjia, Geng Lantao, Lu Wanjun, Guo Huirong, Qu Kang, Mao Peixiao. 2015. Quantitative Raman spectroscopic investigation of geo-fluids high-pressure phase equilibria: Part II. Accurate determination of CH4 solubility in water from 273 to 603K and from 5 to 140MPa and refining the parameters of the thermodynamic model. Fluid Phase Equilibria, 391: 18-30.
Wang Menhan, I-Ming Chou, Lu Wanjun, De Vivo Benedetto. 2015. Effects of CH4 and CO2 on the sulfidization of goethite and magnetite: an in situ Raman spectroscopic study in high-pressure capillary optical cells at room temperature[J]. European Journal of Mineralogy, 27(2): 193-201.
Wang Menghan, Lu Wanjun, Li Lanlan, Qiao Shaohua. 2014. Pressure and temperature dependence of the Raman peak intensity ratio of asymmetric stretching vibration (ν3) and asymmetric bending overtone (2ν2) of methane. Applied spectroscopy, 68(5): 536-540.
Hu Qingcheng, Guo Huirong, Chen Ying, Lu Wanjun.2014. Raman spectroscopic investigation on aqueous NaCl solutions at temperatures from 273 to 573 K: Effect of NaCl on water structure. Journal of Molecular Liquids,199: 83-87.
Guo Huirong, Chen Ying, Lu Wanjun, Hu Qingcheng, Ou Wenjia, Geng Lantao. 2014. Quantitative Raman spectroscopic investigation of geo-fluids high-pressure phase equilibria: Part I. Accurate calibration and determination of CO2 solubility in water from 273.15 to 573.15 K and from 10 to 120 MPa. Fluid Phase Equilibria, 382: 70-79.
Wang Menghan, De Vivo Benedetto, Lu Wanjun, Muniz-Miranda Maurizio. 2014. Surface-Enhanced Raman Scattering (SERS) Detection of Nitroaromatic Pollutants in Water. Applied Spectroscopy, 68(7): 784-788.
Lu Wanjun, Guo Huirong, Chou I.M., Burruss R.C., Li Lanlan. 2013. Determination of diffusion coefficients of carbon dioxide in water between 268 and 473 K in a high-pressure capillary optical cell with in situ Raman spectroscopic measurements. Geochimica et Cosmochimica Acta, 115:183-204.
Lu Wanjun, Wang Feifei, Wang Menghan. 2013. Experimental Simulation of Hydrate Accumulation and Dispersion in Pore Fluids. Natural Gas Hydrates. Springer Geophysics, pp 217-237.
Guo Huirong, Chen Ying, Lu Wanjun, Li Lanlan, Wang Menghan. 2013. In situ Raman spectroscopic study of diffusion coefficients of methane in liquid water under high pressure and wide temperatures. Fluid Phase Equilibria, 360:274-278.
Hu Qingcheng, Lü Xinbiao, Lu Wanjun, Chen Ying, Liu Hong. 2013. An extensive study on Raman spectra of water from 253 to 753 K at 30 MPa.Journal of Molecular Spectroscopy, 292:23-27.
Liu Chang-ling, Ye Yu-guang, Meng Qing-guo, Lu Wanjun ,Wang Feifei. 2011. In situ Raman Spectroscopic Observation of Micro-Processes of Methane Hydrate Formation and Dissociation. Spectroscopy and Spectral Analysis, 31(6),1524-1528
Shang Linbo, Chou I-Ming, Lu Wanjun, Burruss, R.C., and Zhang Youxue, 2009. Determination of diffusion coefficients of hydrogen in fused silica between 296 and 523 K by Raman spectroscopy and application of fused silica capillaries in studying redox reactions. Geochim. Cosmochim. Acta, 73(18), 5435-5443
Song Yucai, Chou I-Ming, Hu Wenxuan, Burruss R. C, Lu Wanjun. 2009. CO2 Density-Raman Shift Relation Derived from Synthetic Inclusions in Fused Silica Capillaries. Acta Geologica Sinica , 83(5),932-938
Lu Wanjun, I-Ming Chou, and R.C. Burruss. 2008. Determination of methane concentrations in water in equilibrium with sI methane hydrate in the absence of a vapor phase by in-situ Raman spectroscopy. Geochimica et Cosmochimica Acta, 72(2): 412-422.9
Lu Wanjun, I-Ming Chou, R.C. Burruss and Yucai Song. 2007. A unified equation for calculating methane vapor pressures in the CH4–H2O system with measured Raman shifts. Geochimica et Cosmochimica Acta, 71(16): 3969-3978
Lu Wanjun, Chou I-Ming, Burruss R. C. 2007.Temperature effect on the quantitative analysis of CO2 concentration in water by in situ laser Raman spectroscopy: A preliminary study at temperatures between 20 and 150 °C and pressures up to 30 MPa In: Water-Rock Interaction (Proceeding of the 12th International Symposium on Water-Rock Interaction), T. Bullen and Y. Wang, Eds. (Taylor &Francis Group, London), p519-522Lu Wanjun, Chou, I.M., Burruss, R.C., and Yang, M.Z., 2006. In-situ study of mass transfer in aqueous solutions under high pressures via Raman spectroscopy: A new method for the determination of diffusion coefficients of methane in water near hydrate formation conditions.Applied Spectroscopy,60(2):122-129
Chou I-Ming, Burruss R.C., and Lu Wanjun. 2005. A new optical cell for spectroscopic studies of geologic fluids at pressures up to 100 MPa, In: Advances in High-Pressure Technology for Geophysical Applications, J. Chen, Y. Wang, T.S. Duffy, G. Shen, L.F. Dobrzhinetskaya, Eds. (Elsevier, Amsterdam,), Chap. 24: 475-483.