Chapter

[2] Chengzhen Sun*; Mei Liu; Hassan; Bofeng Bai; Porous Graphene Membranes for Solute Separation via Reverse Osmosis and Electrodialysis. Springer Series on Polymer and Composite Materials, Book title: Two-Dimensional (2D) Nanomaterials in Separation Science, Edited by Rasel Das, 2021.

[1] Chengzhen Sun; Bofeng Bai*; Chemically Derived Graphene for Water Purification and Gas Separation. RSC Nanoscience and Nanotechnology Series, Book title: Chemically Derived Graphene:Functionalization methods, Properties, and Applications, Edited by Jintao Zhang, 2018.

Paper

[65] Ma Xinyi; Mehdi Neek-Amal; Chengzhen Sun*; Advances in Two-Dimensional Ion-Selective Membranes: Bridging Nanoscale Insights to Industrial-Scale Salinity Gradient Energy Harvesting, Acs Nano, 2024,18: 12610-12638.

[64] Runfeng Zhou; Mehdi Neek-Amal; Francois M. Peeters; Bofeng Bai; Chengzhen Sun*; Interlink between Abnormal Water Imbibition in Hydrophilic and Rapid Flow in Hydrophobic Nanochannels, Physical Review Letters, 2024, 132: 184001

[63] Runfeng Zhou; Mathew M. Swisher; Akshay Deshmukh; Chengzhen Sun; John H. Lienhard; Nicolas G. Hadjiconstantinou*. Dense fluid transport through nanoporous graphene membranes in the limit of steric exclusion, Physical Review Fluids, 2024, 9: 044202

[62] Haoxuan Li; Xinyi Ma; Runfeng Zhou; Mehdi Neek-Amal; Chengzhen Sun*. Deciphering the Liquid Continuum: Thermophysical and Slippage Dynamical Behavior of Water in Graphene Oxide Nanochannels, Journal of Physical Chemistry C, 2024, 128: 4362-4371.

[61] Shuaiqi Zhao; Rui Zhang; Han Huang; Chengzhen Sun; Hui Jin; Kunpeng Zhao; Bofeng Bai*;  Intrapore water-gas shift reaction inhibits coal gasification in supercritical water, Chemical Engineering Science, 2024. 289: 119843

[60] Chengzhen Sun*; Keteng Tang; Runfeng Zhou; Bofeng Bai; Two-phase imbibition of water-oil displacement in silica nanochannels, International Journal of Multiphase Flow, 2024, 172: 104710

[59] Rui Zhang; Shuaiqi Zhao; Chengzhen Sun; Hui Jin; Kunpeng Zhao*; Bofeng Bai*; Particle Morphology Evolution and Its Enhancement for Lignite Gasification in Supercritical Water. Industrial&Engineering Chemistry Research, 2023, 62(40): 16268–16279

[58] Chengzhen Sun*; Keteng Tang; Shaohua Zhu; A Regulation Method of the Wettability of Solid Surfaces: Oil–Water Wettability Alteration by Replacing Adsorbed Polar Molecules via Salt Ions, Industrial&Engineering Chemistry Research, 2023, 62(42): 16958–16967

[57] Haoxuan Li; Bin Zhao; Chengzhen Sun*; Bofeng Bai; Semiempirical equations of state of H2O/CO2 binary mixtures in graphite nanoslits, SCIENCE CHINA Physics, Mechanics & Astronomy, 2023, 66(8): 284711

[56] Zhixiang Zhao*; Yonghui Jin; Runfeng Zhou; Chengzhen Sun*; Xiang Huang; Unexpected Behavior in Thermal Conductivity of Confined Monolayer Water. Journal of Physical Chemistry B, 2023, 127 (18): 4090-4098.

[55] Runfeng Zhou; Zhiling Qiu; Chengzhen Sun*; Bofeng Bai; Entrance loss of capillary flow in narrow slit nanochannels. Physics of Fluids, 2023, 35: 042005

[54] Chengzhen Sun*; Qiyuan Wang; Keteng Tang; Dong Wei; Bofeng Bai; Undifferentiated Permeation of Long-Chain Hydrocarbon Molecules through Graphene Nanopores and Its Implications for Alkane Separations. Journal of Physical Chemistry C, 2023, 127 (14): 6835-6842.

[53] Chengzhen Sun*; Runfeng Zhou; Bofeng Bai; How to accurately predict nanoscale flow: Theory of single-phase or two-phase?, Physics of Fluids, 2023, 35: 012013

[52] Z. Javdani; N. Hassani; F. Faraji; Runfeng Zhou, Chengzhen Sun; B. Radha; E. Neyts; Francois M. Peeters; Mehdi Neek-Amal*; Clogging and Unclogging of Hydrocarbon-Contaminated Nanochannels, The Journal of Physical Chemistry Letters, 2022, 13: 11454–11463

[51] Chengzhen Sun*; Mehdi Neek-Amal; Gerald J. Wang; Zhixiang Zhao; Editorial: Nanoconfined Fluids in Energy Applications. Frontier in Energy Research, 2022, 10: 919288

[50] Bin Zhao; Runfeng Zhou; Chengzhen Sun*; Bofeng Bai*; PVT properties and diffusion characteristics of H2O/H2/CO2 mixtures in graphite nanoslits, Chemical Physics Letters, 2022, 795: 139502.  
[49] Kaituo Jiao; Ruitao Yang; Chengzhen Sun; Bo Yu; Bofeng Bai; Stratum temperature recovery considering groundwater advection in periodic operations of deep borehole heat exchangers, Applied Thermal Engineering, 2022, 206: 118113.  
[48] Shaohua Zhu; Keteng Tang; Mei Liu; Chengzhen Sun*; Bofeng Bai; Ion-induced oil–water wettability alteration of rock surfaces. Part III: Ion-bridging interactions between oil and solid, Chemical Engineering Science, 2022, 252: 117275.
[47] Kaituo Jiao; Chengzhen Sun; Ruitao Yang; Bo Yu; Bofeng Bai; Long-term heat transfer analysis of deep coaxial borehole heat exchangers via an improved analytical model, Applied Thermal Engineering, 2021, 197: 117370.
[46] Shaohua Zhu; Hongwei Yu; Gengping Yan; Jun Li; An Cao; Chengzhen Sun*; Miscibility Process of Hydrocarbon Mixture Gas and Crude Oil: Insights from Molecular Dynamics, Industrial & Engineering Chemistry Research, 2021, 60: 13710-13718. 
[45] Chengzhen Sun*; Cheng Liu; Kailin Luo; Bofeng Bai; Quasi-Unidirectional Transport Bilayer Two-Dimensional Nanopores for Highly-Efficient Molecular Sieving, Frontiers in Energy Research, 2021, 9: 773924.
[44] Runfeng Zhou; Xinyi Ma; Haoxun Li; Chengzhen Sun*; Bofeng Bai; Specific Heat Capacity of Confined Water in Extremely Narrow Graphene Nanochannels, Frontiers in Energy Research, 2021, 9: 736713.
[43] Boyao Wen; Chengzhen Sun; Zhengyuan Luo; Xi Lu; Haibo Wang; Bofeng Bai; A hydrogen bond-modulated soft nanoscale water channel for ion transport through liquid–liquid interfaces, Soft Matter, 2021, 17(42): 9736-9744.
[42] Wenxiu Zheng; Boyao Wen; Chengzhen Sun; and Bofeng Bai; Effects of surface wettability on contact line motion in liquid–liquid displacement, Physics of Fluids, 2021, 33: 082101.
[41] Chengzhen Sun*; Runfeng Zhou; Zhixiang Zhao; Bofeng Bai; Unveiling the hydroxyl-dependent viscosity of water in graphene oxide nanochannels via molecular dynamics simulations, Chemical Physics Letters, 2021, 778: 138808.
[40] Chengzhen Sun*; Runfeng Zhou; Zhixiang Zhao; Bofeng Bai; Extending the classical continuum theory to describe water flow through two-dimensional nanopores, Langmuir, 2021, 37(20): 6158-6167.
[39] Shuheng Cui; Jianfeng Fu; Minling Guo; Zhixiang Zhao*; Chengzhen Sun*; Yujun Wang; Diffusion of High-Temperature and High-Pressure CH4 Gas in SiO2 Nanochannels, Frontiers in Energy Research, 2021, 9: 667640.
[38] Runfeng Zhou; Chengzhen Sun*; Bofeng Bai; Wall friction should be decoupled from fluid viscosity for the prediction of nanoscale flow, The Journal of Chemical Physics, 2021, 154: 074709.
[37] Chengzhen Sun*; Kailin Luo; Runfeng Zhou; Bofeng Bai; Theoretical description of molecular permeation via surface diffusion through graphene nanopores, Physical Chemistry Chemical Physics, 2021, 23: 7057-7065.(封面论文
[36] Mei Liu; Shijing Xu; Shaohua Zhu; Jiazhong Wu; Bofeng Bai; Chengzhen Sun*; Ion-induced oil–water wettability alteration of rock surfaces. Part II: Base interactions between oil and solid, Chemical Engineering Science, 2021, 236: 116521.
[35] Chengzhen Sun*; Runfeng Zhou; Bofeng Bai; Yuansheng Lin*; Bangming Li; Multilayer Graphene Sheet with Conical Nanopores as a Membrane for High-Permeance Molecular Separation, The Journal of Physical Chemistry C, 2021, 125: 3047-3054.
[34] Chengzhen Sun*; Mei Liu; Shijing Xu; Shaohua Zhu; Jiazhong Wu; Bofeng Bai; Ion-induced oil–water wettability alteration of rock surfaces. Part I: Polar interactions between oil and solid, Chemical Engineering Science, 2021, 232: 116366. 
[33] Zhixiang Zhao; Runfeng Zhou; Chengzhen Sun*; Hierarchical thermal transport in nanoconfined water, The Journal of Chemical Physics, 2020, 153: 234701.
[32] Chengzhen Sun*; Shaohua Zhu; Shijing Xu; Mei Liu; Jiazhong Wu; Bofeng Bai; Molecular physics in ion-bridging effect for wettability alteration of rock surfaces, Chemical Physics Letters, 2021, 763: 138201.
[31] Maochang Liu; Dongxing Song; Xin Wang; Chengzhen Sun; Dengwei Jing*; Asymmetric Two-Layer Porous Membrane for Gas Separation, The Journal of Physical Chemistry Letters, 2020, 11(15): 6359-6363.
[30] Chengzhen Sun*; Runfeng Zhou; Zhixiang Zhao; Bofeng Bai; Nanoconfined Fluids: What Can We Expect from Them?, The Journal of Physical Chemistry Letters, 2020, 11(12): 4678-4692.
[29] Zhixiang Zhao; Runfeng Zhou; Chengzhen Sun*; Molecular Dynamics Study of Water Diffusivity in Graphene Nanochannels, International Journal of Thermophysics, 2020, 41: 79. 
[28] Zhixiang Zhao; Chengzhen Sun*; Runfeng Zhou; Thermal conductivity of confined-water in graphene nanochannels, International Journal of Heat and Mass Transfer, 2020, 152: 119502.
[27] Boyao Wen; Chengzhen Sun; Wenxiu Zheng; Bofeng Bai*; Eric Lichtfouse; Evidence for water ridges at oil–water interfaces: implications for ion transport, Soft Matter, 2020, 16: 826-832.
[26] Wenxiu Zheng; Chengzhen Sun; Boyao Wen; Bofeng Bai*; Eric Lichtfouse; Effects of Molecular Chain Length on the Contact Line Movement in Water/n-Alkane/Solid Systems, Polymers, 2019, 11: 2081.
[25] Chengzhen Sun*; Shaohua Zhu; Maochang Liu; Shaohua Shen; Bofeng Bai; Selective Molecular Sieving through a Large Graphene Nanopore with Surface Charges, The Journal of Physical Chemistry Letters, 2019, 10: 7188-7194.
                                                                                          
[24] Chengzhen Sun*; Mei Liu; Bofeng Bai*; Molecular simulations on graphene-based membranes, Carbon, 2019, 153: 481-494.
[23] Chengzhen Sun*; Xiuzhi Zheng; Bofeng Bai*; Hydrogen purification using nanoporous graphene membranes and its economic analysis, Chemical Engineering Science, 2019, 208: 115141.
[22] Wenxiu Zheng; Chengzhen Sun; Boyao Wen; Bofeng Bai*; Moving mechanisms of the three-phase contact line in a water–decane–silica system, RSC Advances, 2019, 9: 3092-3101.
[21] Boyao Wen; Chengzhen Sun; Bofeng Bai*; Nanoparticle-induced ion-sensitive reduction in decane–water interfacial tension, Physical Chemistry Chemical Physics, 2018, 20: 22796-22804.

[20] Shijing Xu; Jingyao Wang; Jiazhong Wu; Qingjie Liu; Chengzhen Sun*; Bofeng Bai; Oil Contact Angles in a Water-Decane- Silicon Dioxide System: Effects of Surface Charge, Nanoscale Research Letters, 2018, 13: 108.

[19] Chengzhen Sun; Bofeng Bai*; Improved CO2/CH4 Separation Performance in Negatively Charged Nanoporous Graphene Membranes, The Journal of Physical Chemistry C, 2018, 122: 6178-6185. 

 

[18] Chengzhen Sun; Bofeng Bai*; Selective Permeation of Gas Molecules through a Two-Dimensional Graphene Nanopore, Acta Physico-Chimica Sinica, 2018, 34(10): 1136-1143.

 

[17] Chengzhen Sun; Bofeng Bai*; Wenqiang Lu; Thermal Transport in Sheared Nanoparticle Suspensions: Effect of Temperature, Heat Transfer Engineering, 2019, 40: 1383-1392.

[16] Wenxiu Zheng; Chengzhen Sun; Bofeng Bai*; Molecular Dynamics Study on the Effect of Surface Hydroxyl Groups on Three-Phase Wettability in Oil-Water-Graphite Systems, Polymers, 2017, 9: 370.

[15] Boyao Wen; Chengzhen Sun; Bofeng Bai*; Elizaveta Ya. Gatapova; Oleg A. Kabov; Ionic hydration-induced evolution of decane–water interfacial tension, Physical Chemistry Chemical Physics, 2017, 19: 14606-14614.

[14] Chengzhen Sun; Bofeng Bai*; Molecular sieving through a graphene nanopore: non-equilibrium molecular dynamics simulation, Science Bulletin, 2017, 62: 554-562.

[13] Chengzhen Sun; Bofeng Bai*; Fast mass transport across two-dimensional graphene nanopores: Nonlinear pressure-dependent gas permeation flux, Chemical Engineering Science, 2017, 165: 186-191.

[12] Chengzhen Sun; Bofeng Bai*; Diffusion of gas molecules on multilayer graphene surfaces: Dependence on the number of graphene layers, Applied Thermal Engineering, 2017, 116: 724-730.(ESI高引论文

[11] Chengzhen Sun; Bofeng Bai*; Gas diffusion on graphene surfaces, Physical Chemistry Chemical Physics, 2017, 19: 3894-3902.(ESI高引论文

[10] Chengzhen Sun; Boyao Wen; Bofeng Bai*; Application of nanoporous graphene membranes in natural gas processing: Molecular simulations of CH4/CO2, CH4/H2S and CH4/N2 separation, Chemical Engineering Science, 2015, 138: 616-621.

[9] Chengzhen Sun; Boyao Wen; Bofeng Bai*; Recent advances in nanoporous graphene membrane for gas separation and water purification, Science Bulletin, 2015, 60(21): 1807-1823.(期刊年度最佳论文

[8] Boyao Wen; Chengzhen Sun*; Bofeng Bai*; Inhibition effect of a non-permeating component on gas permeability of nanoporous graphene membranes, Physical Chemistry Chemical Physics, 2015, 17: 23619-23626.

[7] Chengzhen Sun; Michael S. H. Boutilier; Harold Au; Pietro Poesio; Bofeng Bai; Rohit Karnik; Nicolas G. Hadjiconstantinou*; Mechanisms of Molecular Permeation through Nanoporous Graphene Membranes, Langmuir, 2014, 30: 675-682. (引用突破200次

[6] Michael S. H. Boutilier; Chengzhen Sun; Sean C. O’Hern; Harold Au; Nicolas G. Hadjiconstantinou; Rohit Karnik*; Implications of Permeation through Intrinsic Defects in Graphene on the Design of Defect-Tolerant Membranes for Gas Separation, ACS Nano, 2014, 8(1): 841-849.

[5] Chengzhen Sun; Wenqiang Lu*; Bofeng Bai*; Jie Liu; Novel flow behaviors induced by a solid particle in nanochannels: Poiseuille and Couette, Chinese Science Bulletin, 2014, 59(20): 2478-2485.

[4] Chengzhen Sun; Bofeng Bai*; Wenqiang Lu*; Jie Liu; Shear-rate dependent effective thermal conductivity of H2O+SiO2 nanofluids, Physics of Fluids, 2013, 25(5): 052002.

[3] Chengzhen Sun; Wenqiang Lu*; Bofeng Bai; Jie Liu; Transport properties of Ar–Kr binary mixture in nanochannel Poiseuille flow, International Journal of Heat and Mass Transfer, 2012, 55: 1732-1740.

[2] Chengzhen Sun; Wenqiang Lu*; Bofeng Bai; Jie Liu; Anomalous enhancement in thermal conductivity of nanofluid induced by solid walls in a nanochannel, Applied Thermal Engineering, 2011, 31: 3799-3805. 

[1] Chengzhen Sun; Wenqiang Lu*; Jie Liu; Bofeng Bai; Molecular dynamics simulation of nanofluid’s effective thermal conductivity in high-shear-rate Couette flow, International Journal of Heat and Mass Transfer, 2011, 54: 2560-2567.

个人论文引用情况请见Google学术主页(Chengzhen Sun

Paper in Chinese

[18] 周润峰; 孙成珍*; 白博峰; 石墨烯表面气体扩散系数的原子模型, 中国科学:物理学力学 天文学, 2024, 54(02): 84-93.

[17] 孙成珍; 纳米空间受限流体的能质输运专题·编者按, 中国科学:物理学 力学 天文学, 2024, 54(02): 5.

[16] 马欣怡; 孙成珍*; 多层级纳米通道实现高效离子选择性输运及盐差能发电, 中国科学:物理学 力学 天文学, 2024, 54(02): 104-114.

[15] 王睿; 孙成珍*; 杨旭; 深层页岩高温高压纳米孔中甲烷赋存与流动特性, 工程热物理学报, 2024 (已录用).

[14] 孙成珍*; 罗东; 白博峰; 二维材料气体分离膜及其应用研究进展. 科学通报, 2023, 68 (1): 53-71.

[13] 焦开拓; 孙成珍; 白博峰; 杨瑞涛; 地下水渗流对中深层地埋管取热性能的影响规律, 天然气工业, 2022, 42(04): 85-93.

[12] 俞宏伟; 李实; 李金龙; 朱韶华; 孙成珍*; 气驱油油气混相过程的界面传质特性及其分子机制, 物理化学学报, 2022, 38: 2006061.(SCI收录

[11] 孙成珍*; 刘美; 白博峰; 伍家忠; 史永兵; 无机盐离子对石英表面油-水润湿性的影响, 科学通报, 2020, 65(25): 2775-2782. 

[10] 孙成珍*; 白博峰; 石墨烯基分离膜可行吗?, 科学通报, 2020, 65(1): 3-5.

[9] 孙成珍*; 周润峰; 白博峰; 基于静电效应的石墨烯纳米孔选择性渗透特性, 物理化学学报, 2020, 36(11): 1911044. (SCI收录

[8] 孙成珍; 白博峰*; 气体分子在石墨表面的吸附与扩散特性, 工程热物理学报, 2018, 39(1): 110-113.

[7] 温伯尧; 孙成珍; 车煜全; 白博峰*; 十二烷基苯磺酸钠在癸烷-水界面吸附的MD模拟, 工程热物理学报, 2016, 37(5): 1011-1015. 

[6] 郑文秀; 孙成珍; 熊涛; 吕小明; 白博峰*; 壁面粗植度对油-水-固三相接触线的影响, 工程热物理学报, 2016, 37(9): 1901-1905.

[5] 温伯尧; 孙成珍; 白博峰*; 多孔石墨烯分离CH4/CO2的分子动力学模拟, 物理化学学报, 2015, 31(2): 261-267.(SCI收录

[4] 孙成珍; 张锋; 柳海; 白博峰*; 多孔石墨烯气体分离膜分子渗透机理, 化工学报, 2014, 65(8): 3026-3031.

[3] 孙成珍; 白博峰*; 卢文强; 刘捷; 剪切流场中纳米流体等效热导率的实验测量, 工程热物理学报, 2013, 34(12): 2288-2291.

[2] 孙成珍; 卢文强*; 白博峰; 刘捷; 原子势能对纳米通道中二元流体形态和传热性能的影响, 工程热物理学报, 2012, 33(11): 1908-1911.

[1] 孙成珍; 卢文强*; 刘捷; 白博峰; 高剪切率的Couette流下液氩流体热导率的分子动力学模拟, 工程热物理学报, 2011, 32(07): 1153-1156.

Patent

[7] 孙成珍; 郭金浪; 井家斌; 刘毅; 魏东; 都文轩; 一种渗透蒸发海水淡化和废水处理膜组件、系统及方法, 2024-07-30. 中国, CN2024110340959.

[6] 孙成珍; 井家斌; 刘毅; 郭金浪; 基于二维薄膜的反渗透海水淡化膜组件、装置及淡化方法, 2023-10-30, 中国, 2023114199630. 

[5] 孙成珍; 刘毅; 丁振杰; 刘城; 顾跃雷; 白博峰; 一种大面积氧化石墨烯薄膜的制备方法及反渗透组件, 2023-05-10, 中国, 2023105259558.

[4] 白博峰; 孙成珍; 杨瑞涛; 杨超辉; 侯学明; 刘建宏; 张睿国; 高荣兴; 纪阳;一种基于测井曲线获取地层热导率的方法,2020-10-22,中国, ZL202011141892.9.

[3] 孙成珍; 白博峰; 刘城; 一种基于氧化石墨烯分离膜的反渗透海水淡化装置及其淡化方法, 2021-01-29, 中国, 202110130567.0.

[2] 孙成珍; 白博峰; 一种多孔石墨烯分离膜及其制备方法, 2021-11-19, 中国, ZL202010055265.7.

[1] 孙成珍; 白博峰; 卢文强; 剪切流场中非牛顿流体等效热导率测量装置, 2015-3-4, 中国, ZL201210150189.3.