师资队伍

刘浪

2016年澳大利亚昆士兰大学(The University of Queensland)毕业,师从Suresh  Bhatia教授(澳大利亚科学院与工程院院士)获工学博士学位。博士期间主要致力于采用多孔碳纳米材料进行CO2捕集的研究。2016年10月至2018年10月在澳大利亚昆士兰大学Bhatia教授课题组从事博士后研究员的工作。该期间主要研究流体分子-多孔纳米材料的界面效应对传质系数的影响。 2015年1月-2015年6月获澳大利亚昆士兰大学国际交流奖学金;赴美国佐治亚理工学院David  Sholl 教授(佐治亚理工、化工生物学院院长)的课题组深入学习了有机和无机分子在不同纳米材料如有机金属框架(MOF),沸石和类沸石有机金属框架(ZMOF)内的吸附、输运特性。

      2018年10月,以重庆市高层次人才、“百人计划学者”引进加入能源与动力工程学院。现致力于面向太阳能、工业余热等低品位能高效利用的先进纳米技术研究。近五年在Carbon、 ACS Applied  Materials & Interfaces, Langmuir, JPCC, Chemical Engineering Science等国内外权威刊物及学术会议上发表相关研究论文30余篇。 担任SCI期刊,Open Chemistry编委,Molecules 客座编辑;国际期刊《International Journal of Heat and Mass Transfer》、《Molecular Physics》、《Journal of Chemical of Physics》等多个国际期刊审稿人。

 

教育经历:

2006.9-2010.6, 重庆大学动力工程学院,本科 
2010.6-2012.9, 重庆大学动力工程学院,硕士
2012.10-2016.4,  The University of Queensland,博士
2016.5-2018.10   The University of Queensland,博士后

2018.10 至今  重庆大学能源与动力工程学院,研究员/博导

研究方向:

1)太阳能高效利用的纳米仿生技术研究;

2)碳基多孔介质碳捕集与封存技术研究;

3)基于先进纳米技术的低品能位高效利用系统研发;

4)先进纳米膜材料的设计制备;

学生培养:

研究生代表:

1)王勤:博士毕业现为常州大学讲师

2)林志忠:硕士毕业在香港城市大学攻读博士学位;曾获研究生国家奖学金;

3)宋家胜在读博士:获得国际CSC资助,新加坡国立大学博士联合培养;

本科生:

指导2019级本科生,获全国节能减排大赛一等奖;

指导2019级本科生,完成SRTP、重庆市市创研究。

在研科研项目:

(1)主持,重庆大学“百人计划”中央高校项目;2018.10-2024.10 ;项目经费100 万元;

(2)主持,原子能研究所横向项目,“气溶胶分布的多尺度模拟研究”,2022年8月—2023年4月,项目经费89万元;

(3)主持,国家自然科学基金项目“氧化石墨烯放生体海水淡化的能质流匹配机制研究”,2021年1月—2023年12月,项目经费24万元;

(4)主持,博士后基金委特别资助:“光热蒸发与分质结晶耦合的精准调控调控机制”,2022.10-2024.10月,项目经费18万元;

(5)主持,2021-2023博士后基金委一等资助项目:“光热海水淡化仿生系统能质转化的界面调控机制”,项目经费12万元;

(7)主持,2021-2023 重庆市面上全额资助 “超低温余热深度利用的膜渗透热压转化能级提升机制”,项目经费10万元;

(7)主持,2021-2022 中央高校前沿基础交叉专项“膜渗透热压转化的低温余热能级提升机制”;项目经费17万元;

(8)主持,国家重点实验室开放基金“基于混合基质膜设计制备的膜蒸馏页岩气废水处理研究”,2020年1月—2021年12月;项目经费5万元

(9)主持,教育部固定人员基金“基于混合基质膜设计制备的膜蒸馏页岩气废水处理研究”,2020年1月—2021年12月,项目经费5万元

代表性期刊论文

[1] Y. Su, L. Liu*, X. Gao et al. A High-Efficient and Salt-Rejecting 2D Film for Photothermal Evaporation, iScience (Available online 13 July 2023, 107347)

[2] J. Song, L. Liu* and S. Cai, Water desalination through FAU zeolite studied by using molecular dynamics simulations, Journal of Molecular Liquids, 2023, 380, 121683. 

[3] T. Xiao, L. Liu*, C. Liu et al. Integration of desalination and energy conversion in a thermo-osmotic system using low-grade heat: Performance analysis and techno-economic evaluation, Applied Thermal Engineering, 2023, 223, 120039.

[4] L. Xin, W Yu, C. Liu, L. Liu*, S. Wang, X. Li, Y. Liu, Thermal stability of a mixed working fluid (R513A) for organic Rankine cycle, Energy, 2023, 263, 126131

[5] J.S Song, Z. Zhu and L. Liu*, Mechanism of Hexane Displaced by Supercritical Carbon Dioxide: Insights from Molecular Simulations, Molecules, 27, 8340

[6] Q. Wang, J. Song, X. Gao, L. Liu*, C. Liu Carbon nanotube membranes for the separation of Li+ and Mg2+ ions: Effect of functional groups with charges, Desalination, 2022, 540, 115996. 

[7] J. Song, L. Liu* and Y. Hong, High Interfacial Resistances of CH4 and CO2 Transport Through Metal-Organic Framework 5 (MOF-5), Separation and Purification Technology, 2022, 301, 121895. 

[8] J. Cao, L. Liu*, C. Liu and C. He, Phase transition mechanisms of paraffin in waxy crude oil in the absence and presence of pour point depressant, Journal of Molecular Liquids, 345, 2022, 116989.

[9] J. Song, C. Liu and Lang Liu*, Interfacial resistance of gas transport through rigid and flexible zeolites, Separation and Purification Technology, 278, 2021, 119529

[10] X. Gao, Zhi Li, Cheng Chen, Chao Da, Lang Liu*, Sen Tian, Guozhao Ji, The Determination of Pore Shape and Interfacial Barrier of Entry for Light Gases Transport in Amorphous TEOS-Derived Silica: A Finite Element Method, ACS Applied Materials & Interfaces, 13, 2021,4804-4812.

[11] Zhizhong Lin, Lang Liu*, Chao Liu and Yang Liu, Optimal Performance of Nanoporous Carbons on Adsorptive Separation of CO2 from Flue Gas, Energy & Fuels,35, 2021 ,8086-8080

[12] Zhizhong Lin, Lang Liu*, Chao Liu and Xuechao Gao, Adsorptive separation of Xe/Kr using nanoporous carbons in the presence of I2 and CH3I, Separation and Purification Technology, 275, 2021, 119161

[13] Jiasheng Song, Lang Liu*, Qibin Li, ChaoLiu and Fenhong Song, Entrance resistance of water transport into carbon nanotubes: Insights from molecular dynamics simulations, Journal of Molecular Liquids, 331,2021,115739

[14] Qin Wang, Lang Liu*, Chao Liu and Xuechao Gao, Size Effect in Determining the Water Diffusion Rate in Carbon Nanotubes, Journal of Molecular Liquids, 334, 2021,116034

[15] Qin Wang, Lang Liu*, Chao Liu and Yang Liu, Exchange Dynamics of Molecules at the Fluid-Solid Interface Determining the Diffusion Rate in Nanopores, Journal of Molecular Liquids, 335,2021 ,116030

[16] Lin Z.Z., Liu C., Liu L.*, He D. L. and Zhang Y*, Unprecedentedly High Selective Adsorption of Xe/Kr Mixtures in Carbon Nanotubes: A Molecular Simulation Study. Chemical Engineering Journal, 2020, 393, 124744.

[17] Song, F.; Niu, H.; Fan, J.; Chen, Q.; Wang, G.; Liu, L.*, Molecular dynamics study on the coalescence and break-up behaviors of ionic droplets under DC electric field. Journal of Molecular Liquids 2020, 312, 113195.

[18] Duan D., Lei. H., Wang Y., Ruan R., Liu Y., Ding L., Zhang. Y* and Liu L.*, Renewable phenol production from lignin with acid pretreatment and ex-situ catalytic pyrolysis. Journal of Cleaner Production, 2019, 231,331-340

[19] Liu L.* and Bhatia S. K.* Influence of Morphology on Transport Properties and Interfacial Resistance in Nanoporous Carbons, J. Phys. Chem. C. 2019, 123, 21050-21058

[20] Liu L., Nicholson, D., Bhatia, S.K. Effects of Adsorption Affinity and Porosity on Interfacial Resistance in Carbon Nanotube Membranes. ACS Applied Material and Interfaces. 2018,10, 34706-34717. 

[21] Liu L., Nicholson, D., Bhatia, S.K. Exceptionally high performance of charged carbon nanotube arrays for CO2 separation from flue gas. Carbon. 2017, 125, 245-257. 

[22] Liu L., Nicholson, D., Bhatia, S.K. Inhibitory Effect of Adsorbed Water on the Transport of Methane in Carbon Nanotubes. Langmuir. 2017, 35, 6280-6291.

[23] Liu L., Nicholson, D., Bhatia, S.K. Interfacial Resistance and Length-Dependent Transport Coefficients in Carbon Nanotubes. J. Phys. Chem. C. 2016, 120, 26363-26373. 

[24] Liu L., Nicholson, D., Bhatia, S.K. Impact of H2O on CO2 Separation from Natural Gas: Comparison of Carbon Nanotubes and Disordered Carbon. J. Phys. Chem. C. 2015, 119,407-419.

[25] Liu L., Nicholson, D., Bhatia, S.K. Adsorption of CH4 and CH4/CO2 Mixtures in Carbon Nanotubes and Disordered Carbons: A Molecular Simulation Study. Chem. Eng. Sci. 2015, 121, 268-278.

[26] Liu L. and Bhatia, S. K. Molecular Simulation of CO2 Adsorption in the Presence of Water in Single-Walled Carbon  Nanotubes. J. Phys. Chem. C. 2013, 117, 13479-13491.

[27] Lin Zhizhong, Liu Lang *, Liu Chao, molecular simulation study on adsorption separation of CO2/N2 mixture by carbon nanotubes, 工程热物理学报, 42(6), 2021

[28] Song Jiasheng, Liu Lang *, Liu Chao, study on the hydrodynamic characteristics of the entrance interface of carbon nanotubes.工程热物理学报. 42(7), 2021

发明专利

【1】发明专利:一种疏水膜抽液蓄能系统,ZL2022 10251551.X,授权时间:2023-03-15,刘浪,刘龙燚等

【2】发明专利:石墨烯球负载过渡金属量子点复合材料及其制备方法,ZL2020 11563615.7,授权时间2023-04-18, 刘浪,何冬林

上一位:徐肖肖

下一位:李逍霄