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吴国钟

发布日期:2022-10-10    作者:吴国钟     来源:     点击:

广东工业大学生态环境与资源学院 教授

一、基本信息

吴国钟,天津大学博士,广东工业大学生态环境与资源学院教授,主要从事天然气水合物资源开发、持久性有机污染物环境迁移与传递转化等方面的研究。

二、研究方向

天然气水合物模拟开采、油气管道水合物流动安全保障、天然气固化存储、石油污染土壤评估与治理

三、教育经历

2007.09-2012.01 天津大学,化学工程,博士

2009.10-2010.12 Cranfield University, 环境工程,博士联合培养

2003.09-2007.06 华南理工大学,化学工程与工艺,学士

四、工作经历

2022.01-至今 广东工业大学,教授

2012.01-2021.12 清华大学,博士后、讲师

五、科研项目

1.广东省自然科学基金面上项目,南海沉积物孔隙通道及气泡表面天然气水合物的二氧化碳置换机理研究,2022-2024,主持

2.广东省自然科学基金面上项目,污染土壤老化过程中孔隙残留油絮凝与流动机理研究,2018-2021,主持

3.深圳市科技计划项目,基于环糊精与碳化硅泡沫陶瓷填料的水合物强化生成技术,2017-2019,主持

4.深圳市科技计划项目,沥青质与水合物在油气输送中的共聚机理及抑制技术研究,2016-2018,主持

5.国家自然科学基金青年基金项目,石油四组分与土壤有机质及无机矿物表面的交互作用:分子模拟与显微观测,2014-2016,主持

六、学术论文

1.G Wu*, L Tian, L Ha, F Feng, Z Yang, J Feng, F Coulon, Y Jiang, R Zhang, 2022. Influence of pipeline steel surface on the thermal stability of methane hydrate. J Mol Liq, 120486

2. C Yang, M Zi,G Wu, X Zou, K Liu, D Chen, 2022. Concentration effect of kinetic hydrate inhibitor on hydrate formation and inhibition.Fuel323: 124448.

3. L Tian, L Ha, L Wang, G Chen, F Coulon, Y Jiang, X Zeng, R Zhang,G Wu*, 2022. Location optimization of silicon carbide foam packings in the unstirred packing trays reactor for the enhancement of solidified natural gas storage.Chem Eng Sci253:117503

4. X Zeng#,G Wu#, S Zhang, L Sun, C Sun, G Chen, J Zhong, P Li, Z Yang, J Feng, 2022. In-situ Ramanstudy on kinetics behaviors of hydrated bubble in thickening.Sci Total Environ814:152476

5. Y Sun, B Cao, J Zhong, J Kan, R Li, J Niu, H Chen, G Chen,G Wu, C Sun, D Chen, 2022. Gas production from unsealed hydrate-bearing sediments after reservoir reformation in a large-scale simulator.Fuel308: 121957.

6. M Niu,G Wu, Z Yin, Y Sun, K Liu, D Chen, 2021. Effectiveness of CO2-N2injection for synergistic CH4recovery and CO2sequestration at marine gas hydrates condition.Chem Eng J420: 129615.

7. M Zi,G Wu, J Wang, D Chen, 2021. Investigation of gas hydrate formation and inhibition in oil-water system containing model asphaltene.Chem Eng J412: 128452.

8. L Tian,G Wu*, 2020. Microsecond molecular dynamics simulation of the adsorption and penetration of oil droplets on cellular membrane.J Hazard Mater397: 122683.

9. L Tian,G Wu*, 2020. Cyclodextrins as promoter or inhibitor for methane hydrate formation?Fuel264: 116828.

10. L Tian,G Wu *, 2020. Thermal analysis of methane hydrate formation in a high-pressure reactor packed with porous SiC foam ceramics.Fuel260: 116307.

11. Q Meng, L Sun, D Chen,G Wu*, 2019. Adsorption of asphaltenes at oil-water and oil-clay interfaces in presence of humic acids.Langmuir35: 16718-16725.

12. X Zeng,G Wu, J Wang, C Yang, Q Meng, G Chen, D Chen, 2020. Effects of inhibitors on the morphology and kinetics of hydrate growth on surface of bubble.J Nat Gas Sci Eng74: 103096.

13. X Liu, L Tian, D Chen,G Wu*, 2019. Accelerated formation of methane hydrates in the porous SiC foam ceramic packed reactor.Fuel257: 115858.

14.G Wu, L Tian, D Chen, M Niu, H Ji, 2019. CO2and CH4hydrates: replacement or cogrowth?J Phys Chem C123: 13401-13409.

15. M Zi, D Chen, J Wang, P Hu,G Wu*, 2019. Kinetic and rheological study of methane hydrate formation in water-in-oil emulsion: effects of emulsion composition and silica sands.Fuel255: 115708.

16. P Hu,G Wu, M Zi, L Li, D Chen, 2019. Effect of modified metal surface on the formation of methane hydrate.Fuel255: 115720.

17. X Zeng,G Wu, J Zhong, D Chen, C Sun, G Chen, 2019. Three-scale in situ investigation on the film morphology and mass transfer channels during the thickening growth of hydrates on gas bubble.Crystal Growth & Design19: 3158-3165.

18.G Wu, H Ji, L Tian, D Chen, 2018. Effects of salt ions on the methane hydrate formation and dissociation in the clay pore water and bulk water.Energy Fuels32: 12486-12494.

19. Q Meng, D Chen,G Wu*, 2018. Microscopic mechanisms for the dynamic wetting of a heavy oil mixture on a rough silica surface.J Phys Chem C122: 24977–24986.

20. M Zi,G Wu, L Li, D Chen, 2018. Molecular dynamics simulations of methane hydrate formation in model water-in-oil emulsion containing asphaltenes.J Phys Chem C122: 23299-23306.

21. M Zi, D Chen,G Wu*, 2018. Molecular dynamics simulation of methane hydrate formation on metal surface with oil.Chem Eng Sci191: 253 - 261.

22. P Hu, D Chen, M Zi,G Wu*, 2018. Effects of carbon steel corrosion on the methane hydrate formation and dissociation.Fuel230: 126 - 133.

23. X Zhu,G Wu, F Coulon, L Wu, D Chen, 2018. Correlating asphaltene dimerization with its molecular structure by potential of mean force calculation and data mining.Energy Fuels32: 5779-5788.

24. X Zhu, D Chen, Y Zhang,G Wu*, 2018. Insights into the oil adsorption and cyclodextrin extraction process on rough silica surface by molecular dynamics simulation.J Phys Chem C122: 2997-3005.

25. H Ji, D Chen, C Zhao,G Wu*, 2018. Molecular dynamics simulation of methane hydrate formation and dissociation in the clay pores with fatty acids.J Phys Chem C122: 1318-1325.

26. H Ji, D Chen,G Wu*, 2017. Molecular mechanisms for the cyclodextrin-promoted methane hydrate formation in water.J Phys Chem C121: 20967-20975.

27. H Sui, J Dong, M Wu, X Li, R Zhang,G Wu*, 2017. Continuous hydrogen production by dark fermentation in a foam SiC ceramic packed up-flow anaerobic sludge blanket reactor.Can J Chem Eng95: 62-68.

28. H Ji,G Wu, M Zi, D Chen, 2016. Microsecond molecular dynamics simulation of methane hydrate formation in humic-acid-amended sodium montmorillonite.Energy Fuels30: 7206-7213.

29. X Zhu,G Wu, D Chen, 2016. Molecular dynamics simulation of cyclodextrin aggregation and extraction of Anthracene from non-aqueous liquid phase.J Hazard Mater320: 169-175.

30. M Zi, D Chen, H Ji,G Wu*, 2016. Effects of asphaltenes on the formation and decomposition of methane hydrate: a molecular dynamics study.Energy Fuels30:5643-5650.

31. X Zhu, D Chen,G Wu *, 2016. Insights into asphaltene aggregation in the Na-montmorillonite interlayer. Chemosphere160: 62-70.

32. H Sui, L Li, X Zhu, D Chen,G Wu *, 2016. Modeling the adsorption of PAH mixture in silica nanopores by molecular dynamic simulation combined with machine learning.Chemosphere144: 1950-1959.

33. X Zhu, D Chen,G Wu *, 2015. Molecular dynamic simulation of asphaltene co-aggregation with humic acid during oil spill.Chemosphere138: 412-421.

34. H Sui, Z Hua, X Li, H Li,G Wu *, 2014. Influence of soil and hydrocarbon properties on the solvent extraction of high-concentration weathered petroleum from contaminated soils.Environ Sci Pollut Res21: 5774-5784.

35.G Wu, X Zhu, H Ji, D Chen, 2015. Molecular modeling of interactions between heavy crude oil and the soil organic matter coated quartz surface,Chemosphere119: 242-249.

36.G Wu, X Li, C Kechavarzi, R Sakrabani, H Sui, F Coulon, 2014. Influence and interactions of multi-factors on the bioavailability of PAHs in compost amended contaminated soils,Chemosphere107: 43-50.

37.G Wu, L He, D Chen, 2013. Sorption and distribution of asphaltene, resin, aromatic and saturate fractions of heavy crude oil on quartz surface: molecular dynamic simulation,Chemosphere92: 1465-1471.

38.G Wu, C Kechavarzi, X Li, S Wu, S Pollard, H Sui, F Coulon, 2013. Machine learning models for predicting PAHs bioavailability in compost amended soils,Chem Eng J223: 747-754.

39.G Wu, C Kechavarzi, X Li, H Sui, S Pollard, F Coulon, 2013. Influence of mature compost amendment on total and bioavailable polycyclic aromatic hydrocarbons in contaminated soils,Chemosphere90:2240-2246.

40.G Wu, F Coulon, Y Yang, H Li, H Sui, 2013. Combining solvent extraction and bioremediation for removing weathered petroleum from contaminated soil,Pedosphere23: 455-463.

41.G Wu, X Li, F Coulon, H Li, J Lian, H Sui, 2011. Recycling of solvent used in a solvent extraction of petroleum hydrocarbons contaminated soil,J Hazard Mater186: 533-539.

42.X Li, X Cao,G Wu, TTemple, F Coulon, H Sui, 2014. Ozonation of diesel-fuel contaminated sand and the implications for remediation end-points.Chemosphere109: 71-76.

43. L He, X Li,G Wu, F Lin, H Sui, 2013. Distribution of saturates, aromatics, resins and asphaltenes fractions in the bituminous layer of Athabasca oil sands,Energy Fuels27: 4677-4683.

44. X Li, Y Du,G Wu, Z Li, H Li, H Sui, 2012. Solvent extraction for heavy crude oil removal from contaminated soils,Chemosphere88 (2): 245-249.

45. Y Yang,G Wu, X Li, F Coulon, H Li, H Sui, 2012. Pilot application of SVE enhanced bioremediation technology for in situ clean up of light oil contaminated site,Pol J Environ Stud21: 1461-1466.

46. X Li, L He,G Wu, W Sun, H Li, H Sui, 2012. Operational parameters, evaluation methods, and fundamental mechanisms: aspects of non-aqueous extraction of bitumen from oil sands.Energy Fuels26: 3553-3563.

47. X Li, W Sun,G Wu, L He, H Li, H Sui, 2011. Ionic liquid enhanced solvent extraction for bitumen recovery from oil sands,Energy Fuels25 (11): 5224-5231.

七、联系方式

地址:广东工业大学生态环境与资源学院

邮箱:guozhong2022@hotmail.com

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