◎研究方向
地下石油污染迁移与绿色修复、二氧化碳提高采收率与碳储、极限条件微流控芯片设计与应用、流体力学等

◎学术兼职
Energies特刊Subsurface Energy and Environmental Protection客座编辑（2022.5-2023.5）

◎主讲课程
本科生课程：
海洋油气开发环境保护（英语）、（工程）流体力学、流体力学模拟与实验等

研究生课程：
海洋油气安全与环保

◎指导研究生
指导并联合指导10余名研究生

◎承担科研课题
15. 国家环境保护土壤环境管理与污染控制重点实验室开放课题，基于微流控芯片的石油污染孔隙尺度迁移与绿色修复研究，2023-2023（1/10）
14. 科技部，“绿色智能”石油与天然气工程一流学科团队引智项目，2022-2023（1/1）
13. 山东省自然科学基金-面上项目，非均质石油污染土壤微观修复基础研究，2022-2024（1/8）
12. 横向项目，CO2响应性凝胶体系的裂缝封窜性能测试，2022
11. 横向项目，降粘复合开采机理研究及参数优化，2022
10. 国家自然科学基金-面上项目，海域泥质细粉砂天然气水合物储层分解前沿控制机理研究，2021-2024（2/8）
9. 国家自然科学基金-面上项目，油页岩催化剂辅助注蒸汽原位开采方法及机理研究，2020-2023（2/9）
8. 国家自然科学基金-面上项目，非常规致密储层压裂液伤害的微生物修复方法及机理研究，2019-2022（2/8）
7. 国家自然科学基金-青年基金，利用趋化细菌修复非均质地下水系统中石油污染的机理研究，2016-2018（1/8）
6. 高校自主创新科研计划-青年基金，微流控技术在土壤石油污染物处理中的应用研究，2015-2016（1/5）
5. 校人才引进计划，趋化性微生物对有孔介质中石油污染物的生物修复，2015-2016（1/1）
4. 国家科技重大专项专题，储层敏感性特征评价，2016-2019，（3/16）
3. 973项目，海洋深水油气安全高效钻完井基础研究，2015-2019（参与）
2. 美国国家科学基金，Collaborative Research: A Multiscale Analysis of the Transport of Chemotactic Bacteria in Heterogeneous Porous Media，2011-2015（3/10）
1. 美国国家科学基金，Collaborative Research: Chemotaxis in Porous Media: Experimental Observations and Upscaling for Development of a Descriptive Theory，2007-2011（3/10）

◎获奖情况
教学类：
教育部，海洋深水钻井平台认知及关键作业程序实训—国家级虚拟仿真实验教学一流课程，2020，排名：15
中国石油大学（华东），流体力学“544”课程体系的建设与实践，教学成果二等奖，2017，排名：12
2011-2012年度弗吉尼亚大学杰出助教奖（1/25）

科研类：
2013年度Louis T. Rader化工奖（1/50）
2008年度Harmon博士奖学金（1/11)

◎荣誉称号
青岛市黄岛区第二批高层次紧缺人才
2020年度中国石油大学（华东）百优班主任

◎论文
34. Gao, B., Wang, X.*, & Ford, R. M.* (2022). Chemotaxis along local chemical gradients enhanced bacteria dispersion and PAH bioavailability in a heterogeneous porous medium. Science of the Total Environment, 160004 (Q1, IF: 10.754)
33. Wang, X., Ren, L., Long, T., Geng, C., & Tian, X. (2022). Migration and remediation of organic liquid pollutants in porous soils and sedimentary rocks: a review. Environmental Chemistry Letters, 1-18 (Q1, IF: 13.615)
32. Wang, X., Tian, X., Chen, X., Ren, L., & Geng, C. (2022). A review of end-of-life crystalline silicon solar photovoltaic panel recycling technology. Solar Energy Materials and Solar Cells, 248, 111976 (Q1, IF: 7.305)
31. Wang, X., Hou, L., He, T., Diao, Z., Yao, C., Long, T., & Fan, L. (2022). Numerical simulation of the enrichment of chemotactic bacteria in oil-water two-phase transfer fields of heterogeneous porous media. Applied Sciences, 12(10), 5215 (Q2, IF: 2.838)
30. Li, H., Zhou, Z., Long, T., Wei, Y., Xu, J., Liu, S., & Wang, X.* (2022). Big-data analysis and machine learning based on oil pollution remediation cases from CERCLA database. Energies, 15(15), 5698 (Q3, IF: 3.252)
29. Wang, Z., Liu, S., Li, H., Li, S., Xu, J., & Wang, X. (2022). A numerical simulation study of methane hydrate reformation during the dissociation process induced by depressurization. Fuel, 313, 122983 (Q1, IF: 8.035)
28. Wang, Y., Li, H., Xu, J., Liu, S., & Wang, X. (2022). Machine learning assisted relative permeability upscaling for uncertainty quantification. Energy, 245, 123284 (Q1, IF: 8.857)
27. Xu, J., Zhou, W., Li, H., Wang, X., Liu, S., & Fan, L. (2022). Stochastic simplex approximation gradient for reservoir production optimization: Algorithm testing and parameter analysis. Journal of Petroleum Science and Engineering, 209, 109755 (Q1, IF: 5.168)
26. Xu, J., Bu, Z., Li, H., Wang, X., & Liu, S. (2022). Permeability models of hydrate-bearing sediments: a comprehensive review with focus on normalized permeability. Energies, 15(13), 4524 (Q3, IF: 3.252)
25. Da, Q., Yao, C., Zhang, X., Wang, X., Qu, X., Lei, G. (2022). Investigation on microscopic invasion characteristics and retention mechanism of fracturing fluid in fractured porous media. Petroleum Science, 19 (4), 1745-1756 (Q1, IF: 4.757)
24. Wang, X., Wang, X., He, T., Li, Y., & Hou, L. (2021). The mechanism of NAPL layer formation in a microfluidic device with dual-permeability: experiments and numerical simulation. In IOP Conference Series: Earth and Environmental Science, 675, 1, 012175 (EI)
23. Li, S., Wu, D., Wang, X., & Hao, Y. (2021). Enhanced gas production from marine hydrate reservoirs by hydraulic fracturing assisted with sealing burdens. Energy, 232, 120889 (Q1, IF: 8.857)
22. Li, S., Wang, Z., Li, S., Wang, X., & Hao, Y. (2021). Investigations on performance of hydrate dissociation by depressurization near the quadruple point. Journal of Natural Gas Science and Engineering, 90, 103929 (Q1, IF: 5.285)
21. Fan, L., Tan, Q., Li, H., Xu, J., Wang, X., & Liu, S. (2021). Simulation on effects of injection parameters on CO2 enhanced gas recovery in a heterogeneous natural gas reservoir. Advanced Theory and Simulations, 4(8), 2100127 (Q2, IF: 4.105)
20. Li, S., Ding, S., Wu, D., Wang, X., Hao, Y., Li, Q., & Pang, W. (2021). Analysis of stratum subsidence induced by depressurization at an offshore hydrate-bearing sediment. Energy & Fuels, 35(2), 1381-1388 (Q2, IF: 4.654)
19. Xu, J., Du, S., Yang, X., Hao, Y., & Wang, X. (2021). Molecular dynamics simulation of the effects of different salts on methane hydrate formation: an analysis of NaCl, KCl and CaCl2. IOP Conference Series: Earth and Environmental Science, 675, 1, 012180 (EI)
18. Chen, Y., Gao, Y., Zhang, N., Chen, L., Wang, X., & Sun, B. (2020). Microfluidics application for monitoring hydrate phase transition in flow throats and evaluation of its saturation measurement. Chemical Engineering Journal, 383, 123081 (Q1, IF: 13.273)
17. Pan, B., Gong, C., Wang, X., Li, Y., & Iglauer, S. (2020). The interfacial properties of clay-coated quartz at reservoir conditions. Fuel, 262, 116461 (Q1, IF: 8.035)
16. Pan, B., Li, Y., Zhang, M., Wang, X., & Iglauer, S. (2020). Effect of total organic carbon (TOC) content on shale wettability at high pressure and high temperature conditions. Journal of Petroleum Science and Engineering, 193, 107374 (Q1, IF: 5.168)
15. Liu, S., Sun, B., Xu, J., Li, H., & Wang, X. (2020). Study on competitive adsorption and displacing properties of CO2 enhanced shale gas recovery: advances and challenges. Geofluids, 2020 (Q2, IF: 2.176)
14. Chen, Y., Sun, B., Chen, L., Wang, X., Zhao, X., & Gao, Y. (2019). Simulation and observation of hydrate phase transition in porous medium via microfluidic application. Industrial & Engineering Chemistry Research, 58(12), 5071-5079 (Q2, IF: 4.326)
13. Pan, B., Li, Y., Xie, L., Wang, X.*, He, Q., Li, Y., Hejazi, S. (2019). Iglauer, S., Role of fluid density on quartz wettability, Journal of Petroleum Science and Engineering, 172, 511-516 (Q1, IF: 2.382)
12. Xu, J., Li, L., Liu, J., Wang, X., Yan, Y., & Zhang, J., The molecular mechanism of the inhibition effects of PVCaps on the growth of sI hydrate: an unstable adsorption mechanism, Physical Chemistry Chemical Physics, 2018, 20 (12), 8326-8332 (Q1, IF: 4.123)
11. 王晓璞，丁廷稷，陈哲，徐加放，微流控技术在石油工程流体流变性测试中的应用[J]，实验技术与管理，2017, 34 (2) pp. 57-61 （中文核心教育论文）
10. Cameron, M., Xu, J., Wang, X., Zhang, J., Chen, Z., & Li, X. (2017). Molecular dynamics simulation of hydrated Na-montmorillonite with inorganic salts addition at high temperature and high pressure, Applied Clay Science, 146, 206-215 (Q1, IF: 3.101)
9. Xu, J., Chen, Z., Liu, J., Sun, Z., Wang, X., & Zhang, J. (2017). A molecular dynamic study on the dissociation mechanism of SI methane hydrate in inorganic salt aqueous solutions, Journal of Molecular Graphics and Modelling. 75, 403-412 (Q2, IF: 1.754)
8. Wang, X., Lanning, L. M. & Ford, R. M. (2016). Enhanced retention of chemotactic bacteria in a pore network with residual NAPL contamination, Environmental Science & Technology, 50 (1), 165-172 (Q1, IF: 6.198)
7. Xu, K., Wang, X., Ford, R. M. & Landers, J. P. (2016). Self-partitioned droplet array on laser-patterned superhydrophilic glass surface for wall- less cell arrays, Analytical Chemistry, 88 (5), 2652–2658 (Q1, IF: 6.320)
6. Xu, J., Gu, T., Sun, Z., Li, X. & Wang, X.* (2016). Molecular dynamics study on the dissociation of methane hydrate via inorganic salts, Molecular Physics, 114 (1), 34-43 (Q2, IF: 1.733)
5. Xu, J., Gu, T., Shen, W., Wang, X., Ma, Y., Peng, L. & Li, X. (2016). Influence simulation of inorganic salts on montmorillonite elastic mechanical parameters and experimental study, Journal of China University of Petroleum, Edition of Natural Science, 40 (2), 83-90 (Chinese Essential Journal List)
4. Wang, X., Atencia J. & Ford, R. M. (2015). Quantitative analysis of chemotaxis towards toluene by Pseudomonas putida in a convection- free microfluidic device, Biotechnology & Bioengineering, 112 (5) 896-904 (Q1, IF: 4.481)
3. Wang, X., Long, T. & Ford, R. M. (2012). Bacterial chemotaxis toward a NAPL source within a pore-scale microfluidic chamber, Biotechnology & Bioengineering, 109 (7), 1622-1628 (Q1, IF: 4.481)
2. Kamei, K., Guo, S., Yu, Z. T. F., Takahashi, H., Gschweng, E., Shu, C., Wang, X., Tang, J., McLaughlin, J., Witte, O. N., Lee, K. B. & Tseng, H. R. (2009). An integrated microfluidic culture device for quantitative analysis of human embryonic stem cells, Lab on Chip, 9 (4), 555-563 (Q1, IF: 6.045)
1. Yu, Z. T. F., Kamei, K., Takahashi, H., Shu, C., Wang, X., He, W., Silverman, R., Radu, C. G., Witte, O. N., Lee, K. B. & Tseng H. R. (2009). Integrated microfluidic devices for combinatorial cell-based assays, Biomedical Microdevices, 11 (3), 547-555 (Q2, IF: 3.323)

◎专利
国家发明专利
3. 一种用于模拟土壤-地下水非均质系统的微流控芯片，2022.06.07，ZL202011212867.5，排名：1
2. 应用微流控技术测量流体粘度的实验装置及实验方法，2018.03.13，ZL201611011840.3，排名：1
1. 模拟地下水系统中有机溶剂污染的微流控芯片，2017.07.28，ZL201610895101.9 ，排名：1

◎学术交流
2021.10 学组汇报，第二届全国土壤修复大会，南京
2020.12 学组汇报，美国AGU年会，线上
2020.09 学组汇报，美国InterPore年会，线上
2018.12 学组报告，美国AGU年会，美国华盛顿特区
2018.05 展板报告，美国InterPore年会，美国新奥尔良
2018.01 大会汇报，第一届国际水环境可持续发展会议，中国沈阳
2017.07 大会报告，第七届全国环保型钻井液及钻井废弃物处理技术研讨会，中国成都
2012.08 学组报告，美国化学协会年度会议，美国费城
2011.10 展板报告，美国化学工程师协会年度会议，美国明尼阿波利斯市
2011.09 会展报告，弗吉尼亚大学工学院研究论坛，美国夏洛兹维尔市
2010.12 展板报告，美国地球物理协会年度会议，美国旧金山市