教育背景

2006/09-2010/06，北京林业大学，环境科学与工程，学士

2010/09-2013/03，同济大学，环境科学与工程，硕士

2013/09-2019/03，同济大学，环境科学与工程，博士

工作经历

2021/07至今，bat365在线登录入口，bat365中文官方网站，讲师

2019/06-2021/06，同济大学，环境科学与工程学院，博士后

科研项目

l 国家自然科学基金，电容去离子中电极孔隙效应对离子选择性吸附作用的多尺度研究，2022.1年至今，项目负责人

l 中国博士后科学基金，基于尿液资源回收的电容去离子（CDI）过程离子输运及选择性富集机理研究，2020~2021，项目负责人

l 国家重点研发计划项目，农村厕所粪便高效资源化处理关键技术与示范，2018-2022，参与

l 国家自然科学基金委，能源与环境工程中的多尺度、跨尺度问题研究，2012.1~2016.12，参与

l 科技部十二五科技支撑项目，“室内SVOC及其复合污染暴露和控制仿真软件研究”，2012.1~2015.12，参与

代表性论文

[1] Mao, YF*, Gerisch, A, Lang, J, Böhm, MC, Müller-Plathe, F. Uncertainty quantification guided parameter selection in a fully coupled molecular dynamics-finite element model of the mechanical behavior of polymers, Journal of Chemical Theory and Computation, Journal of Chemical Theory and Computation, 2021, 17(6), 3760-3771.

[2] Mao, YF, Ardham VR, Xu, LQ, Cui, PY, Wu, DL*. Insight into electrosorption behavior of monovalent ions and their selectivity in capacitive deionization: an atomic level study by molecular dynamics simulation. Chemical Engineering Journal, 2021, 415, 128920.

[3] Mao, YF, Li, Z, He, YL, Tao, WQ*. Numerical investigation of dust sedimentation effects on wall adsorption of indoor SVOC by the immersed boundary-lattice Boltzmann method, Building and Environment, 2020, 180, 106974.

[4] Mao, YF, Li, Z, Tao, WQ*. Lattice Boltzmann method simulation of SVOC mass transfer with particle suspensions, International Journal of Heat and Mass Transfer, 2019, 135, 685-695.

[5] Mao, YF, Li, Z, Mu, YT, He, YL, Tao, WQ*. Numerical investigation of SVOC mass transport in a tube by an axisymmetric lattice Boltzmann method, Building and Environment, 2018, 128, 180-189.

[6] Mao, YF, Li, Z, He, YL, Tao, WQ*. CFD analysis of SVOC mass transfer in different chambers, International Journal of Heat and Mass Transfer, 2017, 99, 613-621.

[7] Mao, YF, Li, Z, Zhang, YP, He, YL, Tao, WQ*. A review of mass-transfer models and mechanistic studies of semi-volatile organic compounds in indoor environments, Indoor and Built Environment, 2017, 27, 1307-1321.

[8] Xu, LQ, Mao, YF, Zong, Y., Peng, S, Zhang, XM, Wu, DL*. Membrane-Current Collector-Based Flow-Electrode Capacitive Deionization System: A Novel Stack Configuration for Scale-Up Desalination, Environmental Science & Technology, 2021, 55, 19, 13286–13296.

[9] Xu, LQ, Mao, YF, Zong, Y., Wu, DL*. Scale-up desalination: Membrane-current collector assembly in flow-electrode capacitive deionization system. Water Research, 2021, 190, 116782.

[10] Xu, LQ, Xie, Y, Zong, Y, Mao, YF, Zhang, B, Chu, HQ, Wu, DL*. Formic acid recovery from EDTA wastewater using coupled ozonation and flow-electrode capacitive deionization (Ozo/FCDI): Performance assessment at high cell voltage. Separation and Purification Technology, 2020, 254, 117613.

[11] Xu, LQ, Yu, C, Mao YF, Zong, Y., Zhang, B., Chu, HQ, Wu, DL*. Can flow-electrode capacitive deionization become a new in-situ soil remediation technology for heavy metal removal?. Journal of Hazardous Materials, 2020, 402,123568.

[12] Xu, LQ, Yu, C, Tian, SY, Mao, YF, Zong, Y, Zhang, XM, Zhang, B, Zhang, CY, Wu, DL*. Selective Recovery of Phosphorus from Synthetic Urine Using Flow- Electrode Capacitive Deionization (FCDI)-Based Technology. ACS EST Water, 2021, 1, 1, 175-184.

专利

[1] 一种新型聚合酶链反应微流体芯片控制系统及其制备方法, 2016-11-16, 中国, ZL 201410828918.5.     

[2] 一种新型微加热器及其制备方法, 2016-03-02, 中国, ZL 201310676245.1.