ÐÕÃû£º¶«Ïþ»¢
Ö°³Æ£º¸±½ÌÊÚ¡¢²©µ¼
½ÌÓýÓëÊÂÇéÂÄÀú£º
2005-2009 ¹«º£²Ê´¬£¨±±¾©£© ±¾¿Æ
2009-2014 ¹«º£²Ê´¬£¨±±¾©£© ²©Ê¿Ñо¿Éú
2014-2016 University of Calgary ²©Ê¿ºó
2016-ÏÖÔÚ ¹«º£²Ê´¬£¨±±¾©£©Î÷ϯ
СÎÒ˽¼ÒÖ÷Ò³£º https://www.researchgate.net/profile/Xiaohu_Dong
µç×ÓÓÊÏ䣺 dongxh@cup.edu.cn
ÁªÏµµç»°£º 13466794958
Ñо¿Æ«Ïò£º ³íÓÍÈÈÁ¦²ÉÓÍÊÖÒÕ¡¢·ÇͨÀýÓÍÆø²Ø¿ª·¢¡¢¶þÑõ»¯Ì¼Ìá¸ßʯÓͲÉÊÕÂÊ¡¢ÃºÌ¿µØÏÂÆø»¯¿ª·¢µÈ
´ú±íÐÔÂÛÎÄ£º
[1]. Insights into adsorption and diffusion behavior of shale oil in slit nanopores: A molecular dynamics simulation study, Journal of Molecular Liquids, 2022, 359, 119322. (SCI, EI)
[2]. Experimental investigation on the recovery performance and steam chamber expansion of multi-lateral well SAGD process, Journal of Petroleum Science and Engineering, 2022, 214, 110597. (SCI, EI)
[3]. An Experimental Investigation on the Pore Structure Evolution of Coal in Underground Coal Gasification Process, ACS Omega, 2022, 7(13): 11252-11263. (SCI, EI)
[4]. A Production Performance Model of the Cyclic Steam Stimulation Process in Multilayer Heavy Oil Reservoirs, Energies, 2022, 15, 5. (SCI, EI)
[5]. Effect of solvent on the adsorption behavior of asphaltene on silica surface: A molecular dynamic simulation study, Journal of Petroleum Science and Engineering, 2022, 212, 110212. (SCI, EI)
[6]. ¸ßº¬Ë®²ãÓÍÉ°SAGDÏàËÆÎïÀíÄ£ÄâʵÑéÑо¿. ʯÓÍѧ±¨����£¬ 2022����£¬43 (5): 658-667. £¨EI£©
[7]. ΢-Äɱê×¼¿×϶²î±ðÀàÐÍÁ÷ÌåµÄ¸³´æ״̬Êýѧģ×Ó. ¹«º£²Ê´¬Ñ§±¨£¨×ÔÈ»¿Æѧ°æ£©, 2021, 45(02): 87-95. £¨EI£©
[8]. Pore-Scale Movability Evaluation for Tight Oil EOR methods Based on Miniature Core Test and Digital Core Constructure. Industrial & Engineering Chemistry Research. 2021, 60(6): 2625-2633. (SCI, EI)£¨·âÃæÂÛÎÄ£©
[9]. A novel experimental investigation on the occurrence state of fluids in microscale pores of tight reservoirs. Journal of Petroleum Science and Engineering, 2021, 196, 107656. (SCI, EI)
[10]. Steam Conformance along Horizontal Well with Different Well Configurations of Single Tubing: An Experimental and Numerical Investigation, SPE Production & Operations, 2020, 35(3): 549 - 563. SPE-195799-PA. (SCI, EI)
[11]. Experimental Investigation on the Steam Injection Profile along Horizontal Wellbore, Energy Reports, 2020, 6, 264-271. (SCI, EI)
[12]. Enhanced Oil Recovery Techniques for Heavy Oil and Oilsands Reservoirs after Steam Injection. Applied Energy, 2019, 239, 1190-1211. (SCI, EI) £¨ESI¸ß±»Òý£©
[13]. CNOOC studies steam recovery in offshore Bohai heavy oil field. Oil & Gas Journal, 2018,116.4, 46-51. (SCI, EI)
[14]. An Empirical Correlation to Predict the SAGD Recovery Performance. Journal of Computational Methods in Sciences and Engineering. 2017, 17, 333-345. (EI)
[15]. Performance of Multiple Thermal Fluids Assisted Gravity Drainage Process in Post SAGD Reservoirs. Journal of Petroleum Science and Engineering. 2017, 154, 528-536. (SCI, EI)
[16]. Mathematical Modeling of heat transfer and pressure drops in single- and dual-pipe horizontal well. Journal of Thermal Science and Engineering Applications. 2017, 9(1), 011016-10. (SCI, EI)
[17]. ·ÇÄýÎöÆøÓëÕôÆû»ìעˮƽ¾®¾®Í²Á÷¶¯´«ÈÈÌØÕ÷. ¹«º£²Ê´¬Ñ§±¨(×ÔÈ»¿Æѧ°æ). 2016, 40(2), 105-114. (EI)
[18]. Study of the confined behavior of hydrocarbons in organic nanopores by the potential theory. Fluid Phase Equilibria. 2016, 429, 214-226. (SCI, EI)
[19]. Polymer-Enhanced Foam Injection Process: An Improved- Oil-Recovery Technique for Light Oil Reservoirs after Polymer Flooding. Energy Sources, Part A: Recovery, Utilization, and Environmental Effects. 2016, 38(3): 354-361. (SCI, EI)
[20]. Multi-thermal Fluid Assisted Gravity Drainage Process: A New Improved-Oil-Recovery Technique for Thick Heavy Oil Reservoir. Journal of Petroleum Science and Engineering. 2015, 133, 1-11. (SCI, EI)
[21]. Experimental investigation of miscible gas injection with different gases in petroleum reservoirs. International Journal of Oil, Gas and Coal Technology. 2015, 9(3), 280-295. (SCI, EI)
[22]. Flow and Heat Transfer Characteristics of Multi-thermal Fluid in a Dual-String Horizontal Well. Numerical Heat Transfer, Part A: Application. 2014, 66(2), 185-204. (SCI, EI)
[23]. The flow and heat transfer characteristics of multi-thermal fluid in horizontal wellbore coupled with flow in heavy oil reservoirs. Journal of Petroleum Science and Engineering. 2014, 122, 56-68. (SCI, EI)
[24]. Simulation Modeling and Kinetics for Low-Temperature Oxidation of Light Crude Oil. Chemistry and Technology of Fuels and Oils. 2013, 49(1), 16-24. (SCI, EI)
[25]. Non-Newtonian flow characterization of heavy crude oil in porous media. Journal of Petroleum Exploration and Production Technology. 2013, 3(1), 43-53. (EI)
[26]. Air-Foam Injection Process: An Improved¨COil-Recovery Technique for Waterflooded Light-Oil Reservoirs. SPE Reservoir Evaluation & Engineering. 2012, 15 (4), 436-444. SPE-163044-PA. (SCI, EI)
[27]. Gasification chamber evolution and recovery performance of underground coal gasification in deep coal seam: A numerical simulation study. 2021 SPE/AAPG/SEG Asia Pacific Unconventional Resources Technology Conference, URTEC 208271. (EI)
[28]. Vapor-liquid Equilibria and Diffusion of CO2/n-dacane Mixture in the Nanopores Of Shale Reservoirs. 2020 SPE Annual Technical Conference and Exhibition, SPE 201269. (EI)
[29]. Steam Conformance along Horizontal Well with Different Well Configurations: An Experimental and Numerical Investigation. 2019 SPE Annual Technical Conference and Exhibition, SPE 195799. (EI)
[30]. Confined Behavior of CO2/Hydrocarbon System in Nanopores of Tight and Shale Rocks. 2019 Unconventional Resources Technology Conference, URTeC 116. (EI)
[31]. EOR Potential in the Post Steam Injection Era: Current and Future Trends. 2018 SPE Improved Oil Recovery Conference, SPE 190195. (EI)
[32]. Polymer-Enhanced Foam (PEF) Injection Technique to Enhance the Oil Recovery for the Post Polymer-flooding Reservoir. 2016 SPE Western Reginal Meeting, SPE 180426. (EI)
[33]. Phase Behavior of Hydrocarbon Mixtures in the Organic Nanopores of Unconventional Gas Condensate Reservoirs. 2016 Unconventional Resources Technology Conference, URTEC 2460485. (EI)
[34]. The Thermal Recovery Methods and Technical Limits of Bohai Offshore Heavy Oil Reservoirs: A Case Study. 2015 Offshore Technology Conference Brazil, OTC 26080. (EI)
[35]. Feasibility of the Steam-Assisted-Gravity-Drainage Process in Offshore Heavy Oil Reservoirs with Bottom Water. 2014 Offshore Technology Conference Asia, OTC 24763. (EI)
[36]. Flexibility Research of Hot-Water Flooding followed Steam Injection in Heavy Oil Reservoirs. 2011 SPE Enhanced Oil Recovery Conference, SPE 144012. (EI)
ѧÊõרÖø£º
[1] Dong X., Liu H., Chen Z. Hybrid Enhanced Oil Recovery Processes for Heavy Oil Reservoirs. Developments in Petroleum Science, Elsevier, 2021.
[2] ¶«Ïþ»¢, Áõ»ÛÇä. ¶àÉøÁ÷ÆÁÕϳ¬³íÓÍÕôÆû¸¨ÖúÖØÁ¦Ð¹ÓÍ¿ª·¢ÀíÂÛÓëÊÖÒÕ. Çൺ£º¹«º£²Ê´¬³öÊéÉç, 2021.
[3] Áõ»ÛÇä, ¶«Ïþ»¢. ³íÓÍÓͲØÕôÆûÈȲɺóÆÚÌá¸ß²ÉÊÕÂÊÊÖÒÕÓëÓ¦ÓÃ. Çൺ£º¹«º£²Ê´¬³öÊéÉç, 2021.
¿ÆÑнÌѧ½±Àø£º
[1] ¸ß±¶ÒýÂÛÎÄTOP25£¨2018-2022£©, Applied Energy, 2022.
[2] ÖйúʯÓͺͻ¯Ñ§¹¤ÒµÍŽá»á¿Æ¼¼Ç°½ø¶þµÈ½±����£¬ÅÅÃû2/10����£¬2021.
[3] ¹«º£²Ê´¬£¨±±¾©£©Ð£¼¶½ÌѧЧ¹û¶þµÈ½±����£¬2021.
[4] Ç°1%¸ß±¶ÒýÂÛÎÄ£¨2018-2019£©, Applied Energy, 2020.
[5] ½üÎåÄêÇ°1%¸ß±¶Òý×÷Õߣ¨2015-2019£©, Industrial & Engineering Chemistry Research, 2020.
[6] ½ÌÓý²¿¿Æ¼¼Ç°½ø¶þµÈ½±����£¬ÅÅÃû2/15����£¬2019.
[7] ¹«º£²Ê´¬£¨±±¾©£©¿Æ¼¼Á¢ÒìÓÅÒìÖ¸µ¼Î÷ϯ����£¬2018.
[8] ¹«º£²Ê´¬£¨±±¾©£©ÓÅÒ첩ʿÂÛÎÄ����£¬2016.
[9] ÖйúʯÓͺͻ¯Ñ§¹¤ÒµÍŽá»á¿Æ¼¼Ç°½øÒ»µÈ½±����£¬ÅÅÃû12/15����£¬2013.
·¢Ã÷רÀû£º
[1] ÓͲãÓàÈȼòÖ±¶¨ÒªÁìºÍ×°ÖÃ����£¬¹ûÕæ����£¬2021
[2] Ò»ÖÖʵÑé×°Öü°¶à½éÖʸ´ºÏSAGD¿ª·¢³íÓÍÓͲØʵÑéÒªÁì����£¬¹ûÕæ����£¬2021
[3] ÓÍÉ°SAGDÊÖÒÕµÄÎïÀíÄ£ÄâʵÑéϵͳ¡¢×°Öü°ÒªÁì, ÊÚȨ����£¬2021
[4] ¿×϶Á÷Ìå³õʼ¸³´æ״̬µÄ»ñÈ¡ÒªÁì¼°Æä×°ÖÃ����£¬ÊÚȨ����£¬2021.
[5] ÓÃÓÚ³íÓÍÈȲɵÄͬÐÄË«¹Ü×¢²Éˮƽ¾®ÎïÀíÄ£Äâ×°ÖÃ����£¬ÊÚȨ����£¬2020.
[6] Ò»ÖÖ³íÓÍÓͲØÈȲɿÉÊÓ»¯ÎïÀíÄ£Äâ×°ÖÃ����£¬ÊÚȨ����£¬2018.
[7] ¶à¹¦Ð§×¢ÕôÆûÈȲÉÈýάÎïÀíÄ£ÄâʵÑé×°ÖÃ����£¬ÊÚȨ����£¬2017.
[8] ³íÓÍÈȲÉˮƽ¾®¶ÎÑس̱äÖÊÁ¿Á÷¶¯Ä£ÄâʵÑé×°ÖÃ����£¬ÊÚȨ����£¬2017.
³Ðµ��£¿ÆÑÐÏîÄ¿£º
[1] ¹ú¼Ò×ÔÈ»¿Æѧ»ù½ð����£¬ÆóÒµÁ¢ÒìÉú³¤ÍŽá»ù½ð����£¬ÄѲɳíÓͶàÔªÈȸ´ºÏ¸ßЧ¿ª·¢»úÀíÓëÒªº¦ÊÖÒÕ»ù´¡Ñо¿����£¬2021-2024����£¬¿ÎÌâÈÏÕæÈË.
[2] ¹ú¼Ò×ÔÈ»¿Æѧ»ù½ð����£¬ÇàÄê»ù½ð����£¬Ò³ÑÒ΢Äɱê×¼·Ç¾ùÐÔ¿×϶Á÷ÌåÏà±ä»úÖÆÑо¿����£¬2021-2023����£¬ÏîÄ¿ÈÏÕæÈË.
[3] ±±¾©ÊÐ×ÔÈ»¿Æѧ»ù½ð����£¬ÃæÉÏ»ù½ð����£¬Ò³ÑÒÓͲØÄÉÃ×¼¶¿×϶Á÷ÌåµÄÏÞÓòÐÐΪÓë´«Êä»úÖÆÑо¿����£¬2021-2023����£¬ÏîÄ¿ÈÏÕæÈË.
[4] ±±¾©ÊÐ×ÔÈ»¿Æѧ»ù½ð����£¬ÇàÄê»ù½ð����£¬ÖÂÃÜ-Ò³ÑÒ´¢²ã΢ÄÉÃ×ÏÞÓò¿Õ¼äÄÚµÄÁ÷Ì帳´æ»úÖƼ°Ïà±ä¼ÍÂÉÑо¿����£¬2018-2019����£¬ÏîÄ¿ÈÏÕæÈË.
[5] Öк£ÓÍÑо¿×ÜÔºÓÐÏÞÔðÈι«Ë¾����£¬º£Éϲî±ð¾®ÐͲî±ðÈȽéÖÊÍÌͲúÄÜÆÀ¼ÛÒªÁìÑо¿����£¬2021-2022����£¬ÏîÄ¿ÈÏÕæÈË.
[6] ÖйúʯÓͼ¯ÍÅÀÈ·»¿ÆѧÊÖÒÕÑо¿Ôº����£¬Æø»¯Ð§¹ûµÄÓ°ÏìÒòËØÄ£ÄâÑо¿����£¬2021-2022����£¬ÏîÄ¿ÈÏÕæÈË.
[7] ÖйúʯÓͼ¯ÍÅÀÈ·»¿ÆѧÊÖÒÕÑо¿Ôº����£¬Æø»¯Ãº¿éµÄ¿×Éøת±äÆÊÎö����£¬2020-2021����£¬ÏîÄ¿ÈÏÕæÈË.
[8] ¹«º£²Ê´¬£¨±±¾©£©Òý½øÈ˲ſÆÑÐÆô¶¯»ù½ð£º »ùÓÚ¶àÒòËØñîºÏµÄ·ÇͨÀý´¢²ãÁ÷ÌåÏà̬ÌØÕ÷Ñо¿����£¬2017-2019����£¬ÏîÄ¿ÈÏÕæÈË.
[9] ¡°Ê®ÈýÎ塱¹ú¼Ò¿Æ¼¼ÖØ´óרÏî����£¬ÓÍÉ°SAGD¿ª·¢ÎïÀíÄ£ÄâʵÑéÑо¿����£¬2016-2020����£¬Ö÷ÑÐÖ°Ô±.
Éç»áÓëѧÊõ¼æÖ°£º
[1] SPE»áÔ±
[2] ±±¾©ÄÜÔ´ÓëÇéÐÎѧ»á¾©½ò¼½×¨¼ÒίԱ»áίԱ
[3] Petroleum Science ¸±Ö÷±à
[4] ¡¶Ê¯ÓÍ¿Æѧת´ï¡·Ö´Ðбàί
[5]¡¶¹«º£²Ê´¬Ñ§±¨£¨×ÔÈ»¿Æѧ°æ£©¡·ÇàÄê±àί
[6] Frontiers in Earth Science ¿Í×ùÖ÷±à (2021-2022), Geofluids (2018, 2021), Fluids(2021-2022)¿Í×ù±à¼
[7] ¾Û»áίԱ£º2022̼´ï·å̼ÖкÍÅä¾°Ï¿±Ì½¿ª·¢ÊÖÒÕÁ¢ÒìÓëÉú³¤×êÑлá; IWRED 2020. (http://iwred.org/)����£»GEESD 2020 (www.icgeesd.cn)����£»
[8] ÆÚ¿¯Éó¸åÈË: Nature Communications, Energy, Engineering, Fuel, Energy & Fuels, Fluid Phase Equilibria, SPE J, SPE REE, JPSE, IECRµÈ
[9] Elsevier³öÊéÉçͼÊéÙÉÐÐÆÀÉóר¼Ò
[10] ¹ú¼Ò×ÔÈ»¿Æѧ»ù½ðÏîĿͨѶÆÀÒéר¼Ò
