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首页 > 师资队伍 > 教师 > 给水排水教研所 > 正文

给水排水教研所

王小𠇔

邮箱:wangxiaomao@tsinghua.edu.cn

电话:010-62781386

地点:888vip优惠活动大厅主页888vip优惠活动大厅主页,100084

教育背景

1999.9-2004.7 888vip优惠活动大厅主页环境科学与工程系,获工学博士学位

1994.9-1999.7 888vip优惠活动大厅主页环境科学与工程系,获工学学士学位


工作履历

2017.8至今    888vip优惠活动大厅主页888vip优惠活动大厅主页,副研究员

2011.11 - 2017.7  888vip优惠活动大厅主页888vip优惠活动大厅主页,副教授

2010.11 - 2011.11 香港大学土木工程系,研究助理教授

2009.8 - 2010.11 香港大学土木工程系,博士后

2006.10 - 2009.8 澳大利亚新南威尔士大学土木与888vip优惠活动大厅主页,研究助理

2004.8 - 2006.9 香港大学土木工程系,研究助理


研究领域

纳滤等饮用水深度处理技术和工艺;强化常规深度降浊技术;非常规水资源利用;功能膜开发及应用


研究概况

研究项目

  1. 国家重点研发计划课题,“流域典型地区海水淡化技术装备研发与应用示范”项目之课题四“泥质海岸带宽温盐海水取水及高效预处理技术”(2022YFC3202904),2023/ 01‒2025/12,课题主持

  2. 国家自然科学基金面上项目,电荷马赛克疏松纳滤膜的制备及无机盐/天然有机物截留选择性提升机制(52270007),2023/01‒2026/12,主持

  3. 崂山实验室子课题,“氢岛—海上能源互联制氢系统集成关键技术研究及示范”之子课题三“低维护免药剂高能效海水淡化系统研发和集成”(2021WHZZB0103-03),2021.11‒2023.10,主持

  4. 国家重点研发计划课题,“长距离调水水源水质调控与高效深度处理技术研究与示范”之任务“构建节能型纳滤膜元件及其深度处理系统”,2021/12‒2025/11,参加

  5. 环境模拟与污染控制国家重点联合实验室自由探索课题,基于关键残余铝组分识别和消减的纳滤膜污染控制方法研究(21Y01ESPCT),2021/06‒2023/06,主持

  6. 国家自然科学基金面上项目,纳滤对微量有机物和钙镁离子的选择性截留原理及活性层调控策略(51978367),2020/01‒2023/12,主持

  7. 环境模拟与污染控制国家重点联合实验室自由探索课题,保障饮用水安全和健康的选择性截留纳滤膜的制备研究(18Y01ESPCT),2018/06‒2020/06,主持

  8. 国家水专项子课题,城镇供水系统运行管理关键技术评估与标准化(2017ZX07501002),2017/01‒2020/6,参加

  9. 国家自然科学基金中美国际合作项目子课题,城市水系统可持续转型的优化设计理论与保障技术(51761125013),2018/01‒2021/12,参加

  10. 国家自然科学基金面上项目,基于纳滤过程微量有机物分配和传质机理的混合基质膜制备优化研究(51678331),2017/01‒2020/12,主持

  11. 环境模拟与污染控制国家重点联合实验室自由探索课题,微量有机物与高压膜活性层材料的相互作用机理及对传质的影响研究(15Y01ESPCT),2015/08‒2017/08,主持

  12. 国家自然科学基金面上项目,纳米材料混合基质膜新型制备方法的开发及抗生物污染性能的优化研究(51278268),2013/01‒2016/12,主持

  13. 北京市自然科学基金面上项目,正渗透对药物及个人护理品的截留规律及膜污染的影响研究(8132043),2013/01‒2015/12,主持

  14. 国家自然科学基金重大项目子课题,水质净化过程中复合污染物的协同转化与调控(51290284),2013.01‒2017.12,参加

  15. 国家水专项子课题,给水系统运行特性与工艺设计技术研究(2012ZX07408001),2012/01‒2015/12,参加

  16. 国家水专项子课题,南水北调京津受水区供水安全保障技术研究与示范(2012ZX07404002),2012/01‒2015/12,参加



科技奖励

  1. 李晓岩,张健君,孙飞云,王小𠇔,肖峰等,膜水界面调控及膜法净水效率提升技术与应用,环境保护科学技术奖二等奖(2019)

  2. 雷晶,赵凯,王小𠇔,黄霞,李国平等,基于流道水动力提升的长效安全反渗透膜元件研发及净水产业化应用,中国膜工业协会科学技术奖二等奖(2022)


学术成果

  1. Gao YW, Wang XM*, Huang X, The Veiled Impacts of H plus on Interfacial Polymerization and Its Effects on Nanofiltration Performance, Environmental Science & Technology Letters, 10 (2023) 274−279.

  2. Fu RY, Zhang T, Wang XM*, Rigorous determination of pore size non-uniformity for nanofiltration membranes by incorporating the effects on mass transport, Desalination, 549 (2023) 116318.

  3. Wang KP, Fu WJ, Wang XM*, Xu CY, Gao YW, Liu YL, Zhang XY, Huang X*, Molecular design of the polyamide layer structure of nanofiltration membranes by sacrificing hydrolyzable groups toward enhanced separation performance, Environmental Science & Technology, 56 (2022) 17955−17964.

  4. Liu YL, Wang KP, Zhou ZX, Wei XX, Xia SJ, Wang XM*, Xie YF, Huang X, Boosting the performance of nanofiltration membranes in removing organic micropollutants: trade-off effect, strategy evaluation, and prospective development, Environmental Science & Technology, 56 (2022), 15220−15237.

  5. Gao YW, Zhao YY, Wang XM*, Tang CY*, Huang X, Modulating the asymmetry of the active layer in pursuit of nanofiltration selectivity via differentiating interfacial reactions of piperazine, Environmental Science & Technology, 56 (2022) 14038−14047.

  6. Chen QY, Zhao K, Li GP, Luo JY, Li X, Zeng YJ, Wang XM*, Highly permeable polylactic acid membrane grafted with quaternary ammonium salt for effective and durable water disinfection, ACS Appl. Mater. Interfaces, 14 (2022) 43741−43748.

  7. Cabrera J, Guo HY, Yao JL, Wang XM*, The effect of different carbon sources on biofouling in membrane fouling simulators: microbial community and implications, Biofouling, 38 (2022) 747−763.

  8. He ZH, Wang KP, Liu YL, Zhang T, Wang XM*, Fabrication of Loose Nanofiltration Membranes with High Rejection Selectivity between Natural Organic Matter and Salts for Drinking Water Treatment, Membranes, 12 (2022) 887.

  9. Zhang T, He ZH, Wang KP, Wang XM*, Xie YF, Hou LA, Loose nanofiltration membranes for selective rejection of natural organic matter and mineral salts in drinking water treatment, Journal of Membrane Science 662 (2022) 120970.

  10. Gao YW, Wang KP, Wang XM*, Huang X, Exploitation of Amine Groups Cooped up in Polyamide Nanofiltration Membranes to Achieve High Rejection of Micropollutants and High Permeance of Divalent Cations, Environmental Science & Technology, 56 (2022) 10954-10962.

  11. Yuan ZY, Li YF, Li TY, Yao JL, Zhang JF, Wang XM*, Identifying key residual aluminum species responsible for aggravation of nanofiltration membrane fouling in drinking water treatment, Journal of Membrane Science, 659 (2022) 120833.

  12. Yuan ZY, Li TY, Zhang JF, Wang XM*, Fluorescence-based method for fast quantification of active aluminums in natural and treated water, Journal of Hazardous Materials, 433 (2022) 128815.

  13. Chen R, Zhang K, Wang H, Wang XM*, Zhang XH, Huang X, Incorporating catalytic ceramic membrane into the integrated process of in situ ozonation, membrane filtration and biological degradation: Enhanced performance and underlying mechanisms, Journal of Membrane Science, 652 (2022) 120509.

  14. Zhang T, Fu RY, Wang KP, Gao YW, Li HR, Wang XM*, Xie YFF, Hou LA, Effect of synthesis conditions on the non-uniformity of nanofiltration membrane pore size distribution, Journal of Membrane Science, 647 (2022) 120304.

  15. Lin WC, Wang Q, Sun LQ, Wang DY, Cabrera J, Li DY, Hu LG, Jiang GB, Wang XM*, Huang X*, The critical role of feed spacer channel porosity in membrane biofouling: Insights and implications, Journal of Membrane Science, 649 (2022) 120395.

  16. Wang KP, Wang XM, Januszewski B, Liu YL, Li DY, Fu RY, Elimelech M, Huang X*, Tailored design of nanofiltration membranes for water treatment based on synthesis-property-performance relationships, CHEMICAL SOCIETY REVIEWS 51(2) (2022) 672–719.

  17. Lin WC, Lei J, Wang Q, Wang XM*, Huang X*, Performance enhancement of spiral-wound reverse osmosis membrane elements with novel diagonal-flow feed channels, Desalination 523 (2022) 115447.

  18. Lin WC, Zhang YT, Li DY, Wang XM*, Huang X*, Roles and performance enhancement of feed spacer in spiral wound membrane modules for water treatment: A 20-year review on research evolvement, Water Research 198 (2021) 117146.

  19. Liu DY#, Cabrera J#, Zhong LJ, Wang WJ, Duan DY, Wang XM*, Liu SM, Xie YFF, Using loose nanofiltration membrane for lake water treatment: A pilot study, Frontiers of Environmental Science & Engineering, 15 (4) (2021), 69.

  20. Wang S, Wang ZY, Xia JZ*, Wang XM*, Polyethylene-supported nanofiltration membrane with in situ formed surface patterns of millimeter size in resisting fouling, Journal of Membrane Science, 620 (2021) 118830.

  21. Lin WC, Shao RP, Wang XM*, Huang X*, Impacts of non-uniform filament feed spacers characteristics on the hydraulic and anti-fouling performances in the spacer-filled membrane channels: Experiment and numerical simulation, Water Research 185 (2020) 116251.

  22. Zhang T, Tao YZ, Yang HW, Chen Z*, Wang XM*, Xie YF, Study on the removal of aesthetic indicators by ozone during advanced treatment of water reuse, Journal of Water Process Engineering 36 (2020) 101381.

  23. Guo Y, Li TY, Xiao K*, Wang XM*, Xie YF, Key foulants and their interactive effect in organic fouling of nanofiltration membranes, Journal of Membrane Science 610 (2020) 118252.

  24. Liu YL, Wang XM*, Gao XQ, Zheng JF, Wang J, Volodin A, Xie YF, Huang X, Van der Bruggen B, Zhu JY*, High-performance thin film nanocomposite membranes enabled by nanomaterials with different dimensions for nanofiltration, Journal of Membrane Science 596 (2020) 117717.

  25. Liu YL, Zhu JY*, Zheng JF, Gao XQ, Wang J, Wang XM, Xie YF, Huang X, Van der Bruggen B, A facile and scalable fabrication procedure for thin-film composite membranes: Integration of phase inversion and interfacial polymerization, Environmental Science & Technology 54 (2020) 1946−1954.

  26. Zhang K, Zhang ZH, Wang H, Wang XM*, Zhang XH*, Xie YF, Synergistic effects of combining ozonation, ceramic membrane filtration and biologically active carbon filtration for wastewater reclamation, Journal of Hazardous Materials 382: No. 121091, 2020.

  27. Liu YL, Zhao YY, Wang XM*, Wen XH, Huang X, Xie YF, Effect of varying piperazine concentration and post-modification on prepared nanofiltration membranes in selectively rejecting organic micropollutants and salts, Journal of Membrane Science 582 (2019) 274–283.

  28. Wei CJ*, Li XY, Xie YF, Wang XM*, Direct photo transformation of tetracycline and sulfanomide group antibiotics in surface water: Kinetics, toxicity and site modeling, Science of the Total Environment 686: 1–9, 2019.

  29. Zhao YY, Liu YL, Wang XM*, Huang X*, Xie YF, Impacts of metal-organic frameworks on structure and performance of polyamide thin-film nanocomposite membranes, ACS Applied Materials & Interfaces 11: 13724–13734, 2019.

  30. Fu WJ, Fu J, Li XY, Li B*, Wang XM*, Occurrence and fate of PPCPs in typical drinking water treatment plants in China, Environmental Geochemistry and Health 41: 5–15, 2019.

  31. Liu YL, Xiao K, Zhang AQ, Wang XM*, Yang HW, Huang X, Xie YFF, Exploring the interactions of organic micropollutants with polyamide nanofiltration membranes: A molecular docking study, Journal of Membrane Science 577: 285–293, 2019.

  32. Liu YL, Wang XM*, Yang HW, Xie YFF, Huang X, Preparation of nanofiltration membranes for high rejection of organic micropollutants and low rejection of divalent cations, Journal of Membrane Science 572: 152–160, 2019.

  33. Zhao YY, Wang XM*, Yang HW, Xie YFF, Effects of organic fouling and cleaning on the retention of pharmaceutically active compounds by ceramic nanofiltration membranes, Journal of Membrane Science 563: 734–742, 2018.

  34. Wang Z, Xiao K, Wang XM*, Role of coexistence of negative and positive membrane surface charges in electrostatic effect for salt rejection by nanofiltration, Desalination 444: 75–83, 2018.

  35. Liu YL, Wei W, Wang XM*, Yang HW, Xie YFF, Relating the rejections of oligomeric ethylene glycols and saccharides by nanofiltration: Implication for membrane pore size determination, Separation and Purification Technology 205: 151–158, 2018.

  36. Wei CJ, Xie YF, Wang XM*, Li XY, Calcium hydroxide coating on highly reactive nanoscale zero-valent iron for in situ remediation application, Chemosphere 207: 715–724, 2018.

  37. Liu YL, Wang XM*, Yang HW, Xie YFF, Quantifying the influence of solute-membrane interactions on adsorption and rejection of pharmaceuticals by NF/RO membranes, Journal of Membrane Science 551: 37–46, 2018.

  38. Liu YL, Wang XM*, Yang HW, Xie YFF, Adsorption of pharmaceuticals onto isolated polyamide active layer of NF/RO membranes, Chemosphere 200: 36–47, 2018.

  39. Chen XD, Wang Z, Liu DY, Xiao K, Guan J, Xie YF, Wang XM*, Waite TD, Role of adsorption in combined membrane fouling by biopolymers coexisting with inorganic particles, Chemosphere 191: 226–234, 2018.

  40. Li RH, Wang XM, Li XY, A membrane bioreactor with iron dosing and acidogenic co-fermentation for enhanced phosphorus removal and recovery in wastewater treatment, Water Research 129: 402–412, 2018.

  41. Wei CJ, Wang XM, Li XY*, Core-shell structured mZVI/Ca(OH)2 particle: Morphology, aggregation and corrosion, Journal of Colloid and Interface Science 510: 199–206, 2018.

  42. Zhao YY, Kong FX, Wang Z, Yang HW, Wang XM*, Xie YFF, Waite TD, Role of membrane and compound properties in affecting the rejection of pharmaceuticals by different RO/NF membranes, Frontiers of Environmental Science & Engineering 11: paper no. 20, 2017.

  43. Liu YL, Kong FX, Wang XM*, Yang HW, Xie YFF, Thin-film composite forward osmosis membrane in rejecting trace organic compounds: Impact of molecular charge, Desalination and Water Treatment 66: 23–35, 2017.

  44. Tang S, Wang XM, Liu ST, Yang HW*, Xie YFF, Yang XY, Mechanism and kinetics of halogenated compound removal by metallic iron: Transport in solution, diffusion and reduction within corrosion films, Chemosphere 178: 119–128, 2017.

  45. Kong FX, Yang HW, Wang XM*, Xie YFF, Assessment of the hindered transport model in predicting the rejection of trace organic compounds by nanofiltration, Journal of Membrane Science 498: 57–66, 2016.

  46. Dong LX, Huang XC, Wang Z, Yang Z, Wang XM*, Tang CY, A thin-film nanocomposite nanofiltration membrane prepared on a support with in situ embedded zeolite nanoparticles, Separation and Purification Technology, 166: 230-239, 2016.

  47. Liu ST, Yang HW, Liu WJ, Zhao Y, Wang XM*, Xie YF, Evaluation of backwash strategies on biologically active carbon filters by using chloroacetic acids as indicator chemicals, Process Biochemistry, 51 (7): 886-894, 2016.

  48. Zhao Y, Yang HW, Liu ST, Tang S, Wang XM*, Xie YFF, Effects of metal ions on disinfection byproduct formation during chlorination of natural organic matter and surrogates, Chemosphere 144: 1074–1082, 2016.

  49. Ao L, Liu WJ*, Zhao L, Wang XM, Membrane fouling in ultrafiltration of natural water after pretreatment to different extents, Journal of Environmental Sciences, 43: 234-243, 2016.

  50. Liu DY, Wang XM, Xie YF, Tang HL*, Effect of capacitive deionization on disinfection by-product precursors, Science of the Total Environment 568: 19-25, 2016.

  51. Xiao K, Sun JY, Shen YX, Liang S, Liang P, Wang XM*, Huang X*, Fluorescence properties of dissolved organic matter as a function of hydrophobicity and molecular weight: case studies from two membrane bioreactors and an oxidation ditch, RSC Advances 6: 24050–24059, 2016.

  52. Chen XD, Yang HW, Liu WJ, Wang XM*, Xie YF. Filterability and structure of the fouling layers of biopolymer coexisting with ferric iron in ultrafiltration membrane. Journal of Membrane Science 495: 81–90, 2015.

  53. Wang XM*, Li B, Zhang T, Li XY. Performance of nanofiltration membrane in rejecting trace organic compounds: Experiment and model prediction. Desalination 370: 7–16, 2015.

  54. Zhang XL, Yang HW, Wang XM*, Karanfil T, Xie YF. Trihalomethane hydrolysis in drinking water at elevated temperatures. Water Research, 78: 18–27, 2015.

  55. Zhang XL, Yang HW, Wang XF, Zhao Y, Wang XM*, Xie YF. Concentration levels of disinfection by-products in 14 swimming pools of China. Frontiers of Environmental Science & Engineering, 9: 995-1003, 2015.

  56. Dong LX, Yang HW, Liu ST, Wang XM*, Xie YF. Fabrication and anti-biofouling properties of alumina and zeolite nanoparticle embedded ultrafiltration membranes. Desalination, 365: 70–78, 2015.

  57. Yang HW, Liu WJ, Wang XM*, Sun LL, Xie YF. Bromate control by dosing hydrogen peroxide and ammonia during ozonation of the Yellow river water. Ozone-Science & Engineering, 37 (2): 127-133, 2015.

  58. Tang S, Wang XM, Mao YQ, Zhao Y, Yang HW*, Xie YF. Effect of dissolved oxygen concentration on iron efficiency: Removal of three chloroacetic acids. Water research, 73: 342–352, 2015.

  59. Wang XM, Mao YQ, Tang S, Yang HW*, Xie YFF. Disinfection byproducts in drinking water and regulatory compliance: A critical review. Frontiers of Environmental Science & Engineering, 9 (1): 3–15, 2015.

  60. Wang XM, Yang HW, Li ZY*, Yang SX, Xie YF. Pilot study for the treatment of sodium and fluoride-contaminated groundwater by using high-pressure membrane systems. Frontiers of Environmental Science & Engineering, 9 (1): 155-163, 2015.

  61. Kong FX, Yang HW, Wu YQ, Wang XM*, Xie YF. Rejection of pharmaceuticals during forward osmosis and prediction by using the solution–diffusion model. Journal of Membrane Science, 476: 410–420, 2015.

  62. Mao YQ, Wang XM, Yang HW*, Wang HY, Xie YF. Effects of ozonation on disinfection byproduct formation and speciation during subsequent chlorination. Chemosphere, 117: 515-520, 2014.

  63. Xiao K, Shen YX, Liang S, Liang P, Wang XM*, Huang X*. A systematic analysis of fouling evolution and irreversibility behaviors of MBR supernatant hydrophilic/hydrophobic fractions during microfiltration. Journal of Membrane Science, 467: 206-216, 2014.

  64. Wang XM, Leal GMI, Zhang XL, Yang HW, Xie YF*. Haloacetic acids in swimming pool and spa water in the United States and China. Frontiers of Environmental Science & Engineering, 8(6): 820–824, 2014.

  65. Kong FX, Yang HW, Wang XM*, Xie YF. Rejection of nine haloacetic acids and coupled reverse draw solute permeation in forward osmosis. Desalination, 341: 1–9, 2014.

  66. Chang FF, Liu WJ*, Wang XM. Comparison of polyamide nanofiltration and low-pressure reverse osmosis membranes on As(III) rejection under various operational conditions. Desalination, 334: 10-16, 2014.

  67. Wang XM, Li XY*. Modeling of the initial deposition of individual particles during the cross-flow membrane filtration. Colloids and Surfaces A-Physicochemical and Engineering Aspects, 440: 91-100, 2014.

  68. Sun FY, Wang XM, Li XY*. An innovative membrane bioreactor (MBR) system for simultaneous nitrogen and phosphorus removal. Process Biochemistry, 48: 1749-1756, 2013.

  69. Tang S, Wang XM, Yang HW*, Xie YF. Haloacetic acid removal by sequential zero-valent iron reduction and biologically active carbon degradation. Chemosphere, 90: 1563-1567, 2013.

  70. Zhang XL, Yang HW, Wang XM*, Fu J, Xie YF. Formation of disinfection by-products: Effect of temperature and kinetic modeling. Chemosphere, 90: 634-639, 2013.

  71. Wang XM*, Li XY. A unified model for quantification of concentration polarization (CP) of particles during cross-flow membrane filtration. Colloids and Surfaces A-Physicochemical and Engineering Aspects, 407: 99-107, 2012.

  72. Wang XM, Li XY, Shih K*. Spontaneous formation of nano-fibrillar boehmite and the enhancement effect of polyethylene glycol. Journal of the American Ceramic Society, 94: 4435-4443, 2011.

  73. Wang XM, Sun FY, Li XY*. Investigation of the role of biopolymer clusters in MBR membrane fouling using flash freezing and environmental scanning electron microscopy. Chemosphere, 85: 1154-1159, 2011.

  74. Wang XM*, Li XY, Waite TD. Quantification of solid pressure in the concentration polarization (CP) layer of colloidal particles and its impact on ultrafiltration. Journal of Colloid and Interface Science, 358: 290-300, 2011.

  75. Xiao K, Wang XM, Huang X*, Waite TD, Wen XH. Combined effect of membrane and foulant hydrophobicity and surface charge on adsorptive fouling during microfiltration. Journal of Membrane Science, 373: 140-151, 2011.

  76. Sun FY, Wang XM, Li XY*. Change in the fouling propensity of sludge in membrane bioreactors (MBR) in relation to the accumulation of biopolymer clusters. Bioresource Technology, 102: 4718-4725, 2011.

  77. Wang XM, Li XY, Shih K*. In situ embedment and growth of anhydrous and hydrated aluminum oxide particles on polyvinylidene fluoride (PVDF) membranes. Journal of Membrane Science, 368, 134-143, 2011.

  78. Yang NN, Wen XH*, Waite TD, Wang XM, Huang X. Natural organic matter fouling of microfiltration membranes: Prediction of constant flux behavior from constant pressure materials properties determination. Journal of Membrane Science, 366, 192-202, 2011.

  79. Sun FY, Wang XM, Li XY*. Effect of biopolymer clusters on the fouling property of sludge from a membrane bioreactor (MBR) and its control by ozonation. Process Biochemistry, 46: 162-167, 2011.

  80. Wang XM, Waite TD*. Iron speciation and iron species transformation in activated sludge membrane bioreactors. Water Research, 44: 3511-3521, 2010.

  81. Chen W, Sun FY, Wang XM, Li XY*. A membrane bioreactor for an innovative biological nitrogen removal process. Water Science and Technology, 61: 671-676, 2010.

  82. Wang XM, Waite TD*. Role of gelling soluble and colloidal microbial products in membrane fouling. Environmental Science & Technology, 43: 9341-9347, 2009.

  83. Xiao K, Wang XM, Huang X*, Waite TD, Wen XH. Analysis of polysaccharide, protein and humic acid retention by microfiltration membranes using Thomas’ dynamic adsorption model. Journal of Membrane Science, 342: 22-34, 2009.

  84. Wang XM, Waite TD*. Retention of soluble microbial products in submerged membrane bioreactors. Desalination and Water Treatment-Science and Engineering, 6: 131-137, 2009.

  85. Sun FY, Wang XM, Li XY*. Visualisation and characterisation of biopolymer clusters in a submerged membrane bioreactor. Journal of Membrane Science, 325: 691-697, 2008.

  86. Wang XM, Waite TD*. Impact of gel layer formation on colloid retention in membrane filtration processes. Journal of Membrane Science, 325: 486-494, 2008.

  87. Wang XM, Waite TD*. Gel layer formation and hollow fiber membrane filterability of polysaccharide dispersions. Journal of Membrane Science, 322: 204-213, 2008.

  88. Kovalsky P*, Wang XM, Bushell G, Waite TD. Application of local material properties to prediction of constant flux filtration behaviour of compressible matter. Journal of Membrane Science, 318: 191-200, 2008.

  89. Wang XM, Chang S, Kovalsky P, Waite TD*. Multiphase flow models in quantifying constant pressure dead-end filtration and subsequent cake compression - 1. Dilute slurry filtration. Journal of Membrane Science, 308: 35-43, 2008.

  90. Wang XM, Kovalsky P, Waite TD*. Multiphase flow models in quantifying constant pressure dead-end filtration and subsequent cake compression - 2. Concentrated slurry filtration and cake compression. Journal of Membrane Science, 308: 44-53, 2008.

  91. Wang XM and Li XY*. Accumulation of biopolymer clusters in a submerged membrane bioreactor and its effect on membrane fouling. Water Research, 42: 855-862, 2008.

  92. Huang X*, Wang XM. Toxicity change patterns and its mechanism during the degradation of nitrogen-heterocyclic compounds by O3/UV. Chemosphere, 69: 747-754, 2007.

  93. Wang XM, Li XY*, Huang X. Membrane fouling in a submerged membrane bioreactor (SMBR): characterisation of the sludge cake and its high filtration resistance. Separation and Purification Technology, 52: 439-445, 2007.

  94. Li XY*, Wang XM. Modelling of membrane fouling in a submerged membrane bioreactor. Journal of Membrane Science, 278: 151-161, 2006.

  95. Wang XM, Huang X*, Zuo CY, Hu HY. Kinetics of quinoline degradation by O3/UV in aqueous phase. Chemosphere, 55: 733-741, 2004.

  96. Meng YB, Huang X*, Wu YX, Wang XM, Qian Y. Kinetic study and modeling on photocatalytic degradation of para-chlorobenzoate at different light intensities. Environmental Pollution, 117: 307-313, 2002.