Centre for Energy Storage Science and EngineeringCentre for Energy Storage Science and Engineering

多项复杂系统国家重点工程实验室

研究员

丁玉龙

个人简介

    研究中心主任,研究员,博士生导师,国家“千人计划”特聘专家。于1997年获英国伯明翰大学工学博士学位。其后作为博士后研究员任职于英国伦敦帝国理工和英国伯明翰大学。2001年获英国利兹大学终身教职,先后任讲师、高级讲师和教授。2009 年入选首批中组部国家“千人计划”,负责过程工程研究所储能工程团队的建设。

    

      近 10 年来,先后主持了研究项目 60 余项,包括多项与能源工程有关的项目,例如热-电-冷-储能联合系统的开发(英国工程与物理科学基金 EPSRC资助)、太阳能光电-热电过程及相关材料的研究、气固两相流在特定尺度的流动与传热、煤燃烧和熔融还原、(EPSRC资助)、液氮/液态空气汽车(HPS资助)、高温除尘(EPSRC资助)、新型循环流化床技术(EPSRC资助)、新型氢气生产技术(EPSRC资助)及二氧化碳减排技术(EPSRC & Air Products 资助)等,  还包括多项大型纳米工程项目,比如宝洁公司(P&G)、英国工程与物理科学基金(EPSRC)、英国工业贸易部(DTi)、英国约克郡区域发展组织(YORKSHIRE FORWARD)等资助的项目。

 

     近年来共出版专著 1 本,编著 10 本,发表论文近 300篇,其中 SCI 收录 110 余篇,论文总的它引次数约为 1650,发表论文的 H-Index为 20。任 10 余个国际学术会议主席或分会主席,超过 50 次特邀学术报告。现任英国皇家化学会会士、英国工程与物理科学基金评委及专家组成员、英国化学工程师学会期刊评奖专家委员、中国颗粒学会理事、英国化学工程师学会颗粒技术委员会委员、英国皇家化学会颗粒测量学技术委员会委员。担任过壳牌石油公司(Shell)、英国葛兰素(GlaxoSmithKline)及宝洁(P&G)等公司的技术顾问。担任美国Petroleum Research Funds 基金、意大利 Fondazione Cariverona 基金、捷克国家科学基金、新加坡国家科学基金等多个国际研究基金的评审人。

 

电话:010- 82544814;E-mail:ylding@home.ipe.ac.cn

 

现任职务

 

2010年3月至今  中科院过程工程研究所 研究员、博士生导师、国家千人计划特聘专家
2007年8月至今  英国利兹大学过程环境与材料工程学院 教授
2006年2月至今  英国Dispersia有限公司创建董事

近期研究项目及经费

 

  近年来,先后主持研究项目近60项,支配的总经费折合成人民币超过7500万。以下是自2001年6月份已来的主要研究课题和经费来源情况:

[1]中国科学院知识创新重要方向项目(中国科学院),850万人民币,基于超临界过程的空气储能技术的研究,2010年12月-2013年12月。

[2]欧盟第七框架项目:700万欧元,全欧纳米材料安全测试(QNano - A Pan-European Infrastructure for Quality in Nanomaterials Safety Testing),2011年2月 – 2015年1月。

[3]国家重点实验室科研仪器专项(财政部),265万元人民币,基于深冷技术的电能储存平台,2010-2012年。

[4]多相复杂系统国家重点实验室自主研究项目,150万元人民币,纳微结构储能材料的开发和性能研究,2010年。

[5]多相复杂系统国家重点实验室开发基金,10万元人民币,多相复杂燃油喷雾场的激光诱导荧光测试技术研究,2011-2012年。

[6]多相复杂系统国家重点实验室开发基金,10万元人民币,碳载体诱导生长氧化还原聚合物储能机理及双功能大电容复合电极制备,2011-2012年。

[7]英国工程与物理科学基金(EPSRC):43.9万英镑,基于深冷技术的生物质燃料微型冷热电联供系统(BMT-CES - Biofuel Micro-Trigeneration with Cryogenic Energy), 2008年12月 – 2011年12月。

[8]英国工程与物理科学基金(EPSRC)知识转化人员借调(Knowledge Transfer Secondment):14万英镑,2011年3月 – 2012年2月。

[9]英国约克郡区域发展组织:8万英镑,纳米制造人员支持(Nanofactory fellowship),2010年8月 – 2011年7月。

[10]英国工程与物理科学基金(EPSRC):65.7万英镑, 太阳能士兵(The Solar soldier),2009年10月 – 2011年9月。

[11]英国工程与物理科学基金(EPSRC):39.5万英镑,基于纳米流体自调控反应系统(Understanding and controlling of nanofluids for responsive reacting systems),2008年1月 – 2011年6月。

[12]英国工程与物理科学基金(EPSRC):33万英镑,基于吸附分离促进化学反应过程的废品甘油制氢技术(Converting glycerol to hydrogen using sorption enhanced reaction processes), 2007年10月 – 2009年4月。

[13]英国工程与物理科学基金(EPSRC)和宝洁(英国)公司(Procter & Gamble UK):72.5万英镑,限制空间纳米流体结构化的研究(Nanofluids structuring in confined geometries),2007年10月 – 2011年5月。

[14]英国工程与物理科学基金(EPSRC):11万英镑,基于天然原料的自适应过程技术研究(Adaptive process for natural feedstock),2007年10月 – 2009年9月。

[15]英国工程与物理科学基金(EPSRC)和英国高瞻公司(Highview Enterprises Ltd):9万英镑,Dorothy Hodgkin博士奖学金 (Dorothy Hodgkin Additional PhD Award),2007年12月 – 2011年6月。

[16]英国高瞻公司(Highview Enterprises Ltd):35万英镑,基于深冷技术的储能系统研发(Cryogenic based energy storage system),2006年3月 – 2012年3月。

[17]宝洁(英国)公司(Procter & Gamble UK):22.8万英镑,纳米流体的表面润湿性能研究(Wetting and spreading of nanofluids),2004年10月 – 2008年10月。

[18]英国工程与物理科学基金(EPSRC):6万英镑,用于纳米颗粒/流体制备的易放大界面反应器研发(An fully scalable interfacial reactor for nanoparticle production),2007年3月 – 2009年11月。

[19]英国AstraZeneca公司和工程与物理科学基金:10万英镑,制药颗粒湿法造粒过程基础研究(The fundamentals of pharmaceutical particle aggregation in wet granulation),2006年2月 – 2009年11月。

[20]英国Particles R&D 公司:9.5万英镑,纳米级和亚微米颗粒的分级和表征及其低温条件下纳米流体的流动和混合技术研究(Nano and submicron particle classification and characterisation,and flow and mixing of nanofluids under cryogenic conditions),2005年1月 –2006年5月。

[21]英国工程与物理科学基金(EPSRC):6.3万英镑,基于纳米颗粒悬浮液的过程强化技术研究(Nanoparticle suspensions for process intensification),2005年7月 – 2007年7月。

[22]英国工程与物理科学基金(EPSRC)和宝洁(英国)公司(Procter & Gamble UK):6万英镑,纳米流体在限制空间的流动性能研究(The flow behaviour of nanofluids in confined regions),2004年10月 – 2008年7月。

[22]利兹纳米制造研究院(Leeds UII Nanomanufacturing)和宝洁(英国)公司(Procter & Gamble UK):7.5万英镑, 智能型抗菌纳米复合材料(Smart nano-composites for antimicrobial applications),2004年10月 – 2008年7月。

[23]国际细颗粒研究院(International Fine Particle Research Institute):21.6万美元,有机颗粒材料研磨技术研究(Milling of organic solids), 2004年9月 – 2010年9月。

[24]宝洁(英国)公司(Procter & Gamble UK),6.2万英镑,纳米颗粒稳定微悬浮液德研究(Nanoparticle engineering of micro-suspensions),2003年10月 – 2007年11月。

[25]英国工程与物理科学基金(EPSRC):14.4万英镑,低温制氢技术研究(Low temperature hydrogen production),2003年7月 – 2006年6月。

[26]英国工程与物理科学基金(EPSRC):6.5万英镑,气固两相流在固定床中的流动行为研究(Flow of a gas-solid two phase mixture through a packed structure), 2002年3月 – 2004年10月。

[27]英国约克郡区域性组织(YF/Nanofactory):53万英镑,纳米技术装备专项经费(Nanotechnology equipment funding),2005年1月 – 2005年5月。

[28]壳牌公司(Shell Global Solutions):5.9万英镑,纳米流体强化换热技术研究(Nanofluids for enhanced heat transfer), 2003年8月 – 2005年2月。

[29]英国工程与物理科学基金(EPSRC)和英国工贸部(DTi):20万英镑,未来纳米颗粒技术研究:纳米颗粒可控组装(ACORN Nanoparticles for the future: Production of nano-assemblies),2002年6月 – 2005年9月。

[30]英国工程与物理科学基金(EPSRC)和四家公司(P&G, Pfizer, Borax and Hosokawa Micron):45.6万英镑,高剪切力颗粒造球技术及其规模化研究(Effect of the scale of high shear mixer granulator on the structure of granules), 2003年9月 – 2008年8月。

[31]英国MSD公司(Merck Sharpe & Dohme Ltd):19.6万英镑,药物颗粒摩擦带电问题研究(Tribocharging of pharmaceutical powders),2002年12月 – 2006年5月。

[32]英国核燃料公司(BNFL):20.2万英镑,基于单颗粒行为和特性的颗粒群特性预测研究(Establishment of relationships between properties and behaviour of single particles and those of the bulk),2002年9月 – 2004年12月。

[33]英国战略性基础设施基金(SRIF2),10万英镑,纳米流体制造装备研发(Nanofluids production unit),2004年。

[34]英国战略性基础设施基金(SRIF2),20万英镑,超临界水反应系统研制(Supercritical water system),2004年。

[35]英国战略性基础设施基金(SRIF2),10万英镑,超临界CO2环境下的颗粒制造技术和装备研发(Supercritical CO2 particle formation facility),2004年。

 

专利成果

 

 获得超过13项专利,其中包括近期专利成果7项。


[1]丁玉龙,金翼和汪翔等(2011):内燃发电机系统低谷电及余热回收、储存和再利用,申请号:201110020886.2

[2]丁玉龙,李永亮和金翼等(2011):一种高峰负荷发电装置,申请号:201010194828.7

[3]M. Povey and Y.L. Ding (2009): Production of nanoemulsions, PCT/GB2009/051305

[4]Y.L. Ding (2006): Particulate phase chromatography, WO2006/082431.

[5]A.D. Brooker, R.N. Somerville, D.W. York and Y.L. Ding (2007): Nano-based cleaning method, WO 2007/109239.

[6]H.S. Chen, Y.L. Ding, T. Peters and F. Berger (2007): A method of storing energy and a cryogenic energy storage system, WO 2007/096656.

[7]Y.L. Ding, D.S. Wen and P. Dearman (2007) Cryogenic engines, WO 2007/080394

[8]S. Liu, T.J. Yang, D.Q. Cang, Z.L. Gao and Y.L. Ding (1993): Oxy-coal combustor with multi-jet of oxygen, ZL 93 2 23772.X

[9]Y.L. Ding, D.Q. Cang, Y.S. Zhou, T.J. Yang and S.L. Liu (1992): A novel combustor for BF tuyere pulverised coal injection, ZL 92 2 05037.6

[10]T.J. Yang, Y.S. Zhou, D.Q. Cang, Y.L. Ding, S.L. Liu, Y.R. Chen, and Y.S. Shen (1991): An oxy-coal combusting device for BF PCI, ZL 91 2 24336.8

[11]J.S. Xu, J.G. Zhang, Z. Zhou, D.Q. Cang and Y.L. Ding (1990): A fully hot air oil burner with an automatic air/fuel proportional controller, ZL 90 2 09441.6

[12]J.S. Xu, X.X. Zhang, Z.L. Gao, D.Q. Cang, Y.L. Ding and J.G. Zhang (1990): A self-preheating combustor with a recuperator, ZL 90 2 01755.1

[13]J.S. Xu, J.G. Zhang, X.Y. Zhang, D.Q. Cang, M.L. Wu, and Y.L. Ding (1990): A rapid oil combustor, ZL 90 2 00974.5

论著目录

 

I 学术专著

[1] S.J. Antony, W. Hoyle and Y.L. Ding, Granular Materials – Fundamentals and Applications, 371 pages, London, Royal Society of Chemistry (ISBN 0-85404-586-4), 2004.
[2] T.J. Yang, D.Q. Cang and Y.L. Ding, Oxygen Enriched BF Pulverised Coal Injection, 341 pages, Beijing, Metallurgical Industry Press (ISBN 7-5024-1769-9), 1996.


II 合作著作

[3] S. Witharana, H.S. Chen and Y.L. Ding, Nanofluids for Heat Transfer, a chapter for Handbook of Nanophysics, Klaus Sattler eds., Taylor & Francis (CRC Press), 2010.
[4] M. Ghadiri, C.C. Kwan and Y.L. Ding, Analysis of Milling and the Role of Feed Properties. In: Chapter 14 of Handbook of Powder Technology, Salman A., Ghadiri M. and Hounslow M. eds., Elsevier Science B.V., 605-634, 2007 
[5] M.J.W. Povey, T.S. Awad, R. Huo and Y.L. Ding, Crystallization in monodisperse emulsions with particles in size Range 20–200 nm, in Chapter 27 of Food Colloids, 399-411, Royal Society of Chemistry, ISBN 978-0-85404-271-5, 2007.
[6] Y.L. Ding, Transport phenomena, W. Sha, Advances in Materials Science and Engineering Research, 34-63, Beijing, Mechanical Industry Press, 2000.
[7] Y.L. Ding, S.J. Antony and J.P.K. Seville, Granular motion in the transverse plane of rotating drums, 336-354, S.J. Antony et al., Granular Materials – Fundamentals and Applications, 336-354, London, Royal Society of Chemistry, 2004.
[8] Y.L. Ding, Properties of coal for BF injection, T.J. Yang et al., Oxygen Enriched BF Pulverised Coal Injection, 20-58, Beijing, Metallurgical Industry Press, 1996.
[9] Y.L. Ding, Hydrodynamics at the exit of lances for pulverised coal injection, T.J. Yang et al., Oxygen Enriched BF Pulverised Coal Injection, 59-127, Beijing, Metallurgical Industry Press, 1996.
[10] Y.L. Ding, Gas-solid flows in pulverised coal injection units, T.J. Yang et al., Oxygen Enriched BF Pulverised Coal Injection, 128-190, Beijing, Metallurgical Industry Press, 1996.
[11] Y.L. Ding, Numerical modelling of oxygen enriched pulverised coal injection, T.J. Yang et al., Oxygen Enriched BF Pulverised Coal Injection, 238-329, Beijing, Metallurgical Industry Press, 1996.

 

III 期刊论文

2011年
[12] E. K. Goharshadi, Y.L. Ding, X. Lai and P. Nancarrow (2011) Facile and green synthesis of ZnO nanostructures in a room temperature ionic liquid 1-hexyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide1, Inorganic Materials, 47, 379-384.
[13] H.S. Chen, Y.L. Ding, N.T. Cong, B.L. Dou, V. Dupont, M. Ghadiri and P.T. Williams (2011) A comparative study on hydrogen production from steam-glycerol reforming: thermodynamics and experimental. Renewable Energy, 36, 779-788.
[14] Y. Wang, Y. Huang, E. Chiremba, A. P. Roskilly, N. Hewitt, Y.L. Ding, D. Wua, H Yu, X. Chen, Y. Li, , J. Huang, R. Wang and J. Wu, Z. Xia, C. Tan (2011) An investigation of a household size trigeneration running with hydrogen, Applied Energy, Accepted.
[15] S. Witharana, H.S. Chen and Y.L. Ding (2011) Stability of nanofluids in quienscient and shear flow fields, Nanoscale Research Letters, 6, 231.
[16] L.L. Zhang, S.Q. Li, X.M. Liu, D.Q. Cang and Y.L. Ding (2011) Disinfection of water and wastewater using ZnO nanofluids - effect of shaking speed of incubator, Advanced Materials Research, 183 – 185, 2298-2302.
[17] V. Sibanda, Y.L. Ding, R.W. Greenwood, J.P.K. Seville and S.E. Iyuke (2011)  Predicting particle segregation during cross-flow filtration, Powder Technology, Accepted.
[18] D. Olusanmi, K. Roberts, M.Ghadiri, Y.L. Ding (2011) The breakage behaviour of Aspirin under quasi-static indentation and single particle impact loading: effect of crystallographic anisotropy., International Journal of Pharmaceutics, Accepted.
[19] Y. He, C. Qi, Y. Hu, B. Qin, F. Li and Y.L. Ding (2011) Lattice Boltzmann simulation of alumina-water nanofluid in a square cavity, Nanoscale Research Letters, 6, 184.
[20] X.H. Li, W.L. Li, Y.G. Xing, Y.H. Jiang, Y.L. Ding and P.P. Zhang (2011) Effects of nano-ZnO power-coated PVC film on the physiological properties and microbiological changes of fresh-cut ‘Fuji’ apple, Advanced Materials Research, 152-153, 450-453.
[21] C.Y. Yang and Y.L. Ding (2011) Multi-scale modelling of liquid suspensions of micron particles in the presence of nanoparticles,  Advances in Transport Phenomena 2011, Accepted.
[22] 叶锋, 曲江兰, 仲俊瑜, 王彩霞, 孟立静, 杨军, 丁玉龙(2011)相变储热材料研究进展, 过程工程学报, 已录用。

 

2010年
[23] D. Xu, C. Hodges, Y. Ding, S. Biggs, A. Brooker and D. York (2010) Adsorption kinetics of laponite and ludox silica nanoparticles onto a deposited poly(diallyldimethylammonium chloride) layer measured by a quartz crystal microbalance and optical reflectometry, Langmuir, 26, 18105-18112.
[24] C.S. Hodges, Y.L. Ding, S.R. Biggs (2010) The influence of nanoparticle shape on the drying of colloidal suspensions, Journal of Colloid and Interface Science, 352, 99-106.
[25] Yi Jin, W.P. Lee, Z. Musina and Y.L. Ding (2010) A one-step method for producing microencapsulated phase change materials, Particuology,  8, 588-590.
[26] Y. Li, Y. Jin, H. Chen, C. Tan and Y.L. Ding (2010) An integrated system for thermal power generation, electrical energy storage and CO2 capture, International Journal of Energy Research, accepted.
[27] Y. Li, H. Chen, X. Zhang, C. Tan and Y.L. Ding (2010) Renewable energy carriers: hydrogen or liquid air  /  nitrogen? Applied Thermal Engineering, 30, 1985-199.
[28] H.S. Chen, Y.L. Ding, Y.L. Li, X.J. Zhang and C.Q. Tan (2010) Air fuelled zero emission road transportation: A comparative study, Applied Energy, 88, 337–342.
[29] H.S. Chen, Y.L. Ding, N.T. Cong, B.L. Dou, V. Dupont, M. Ghadiri and P.T. Williams (2010) Progress in low temperature hydrogen production with simultaneous CO2 abatement. Chemical Engineering Research and Design, In Press.
[30] D. Olusanami, Y. Ding, M. Ghadiri and K.J. Roberts (2010) Effect of temperature and humidity on the breakage behaviour of aspirin and sucrose, Powder Technology, 201, 248-252.
[31] Y.L. Li, H.S. Chen and Y.L. Ding (2010) Fundamentals and applications of cryogen as a thermal energy carrier, International Journal of Thermal Sciences, in Press.
[32] Y.D. Wang, Y. Huang, A.P. Roskilly, Y.L. Ding and N. Hewitt (2010) Trigeneration running with raw jatropha oil, Fuel Processing Technology, in Press.
[33] B. Dou, Rickett, V. Dupont, P.T. Williams, H.S. Chen, Y.L. Ding and M. Ghadiri (2010) Steam reforming of crude glycerol with in-situ CO2 sorption, Bioresource Technology, 101, 2436-2442.
[34] D. Xu, C.S. Hodges, Y.L. Ding, S.R. Biggs, A. Brooker and D.J. York (2010) A QCM study on the adsorption of colloidal laponite at the solid/liquid interface, Langmuir, in press.
[35] C.S. Hodges, Y.L. Ding and S.R. Biggs (2010) The influence of nanoparticles on polystyrene adhesion, Advanced Powder Technology, 21, 13-18.
[36] Y.L. Ding, H.S. Chen, Z. Musina, Y. Jin, T.F. Zhang, S. Witharana and W. Yang (2010) Relationship between thermal conductivity and shear viscosity of nanofluids, Physica Scripta T, in Press. 
[37] D.C. Venerus et al. (68 co-authors from 33 organisations worldwide) (2010) Viscosity measurements on colloidal dispersions (nanofluids) for heat transfer applications, Journal of Applied Rheology, accepted for publication.

 

2009年
[38] Waipeng Lee, Albert Martinez, Dan Xu, Anju Brooker, David York and Yulong Ding (2009) Effects of laponite and silica nanoparticles on the cleaning performance of amylase enzyme towards starch soils, Particuology, in press.
[39] Jacopo Buongiorno et al. (68 co-authors from 33 organisations worldwide) (2009) A benchmark study on the thermal conductivity of nanofluids, Journal of Applied Physics, accepted for publication.
[40] Liang Wang, Guiping Lin, Haisheng Chen, Y.L. Ding, (2009), Convective heat transfer of Nano-enabled phase change material, Science in China - E Series, 52, 1744-1750
[41] Y.R. He, Y.B. Men, X. Liu, H. Lu, H. Chen, Y.L. Ding (2009) Study on Forced Convective Heat Transfer of Non-Newtonian Nanofluids, Journal of Thermal Science, 18(1), 20-26.
[42] X. Fan, B.H. Ng, Y.L. Ding and M. Ghadiri, Impact of surface tension and viscosity on solid motion in a conical high shear mixer granulator, AIChE J., accepted for publication, 2009.
[43] H.S. Chen, Y.L. Ding and A.A. Lpakin, Rheological behaviour of nanofluids containing tube / rod-like nanoparticles, Powder Technology, accepted for publication, 2009.
[44] H.S. Chen and Y.L. Ding, Heat transfer and rheological behaviour of nanofluids – a review, Advances in Transport Phenomena, accepted, 2009.
[45] B.H. Ng, Y.L. Ding and M. Ghadiri, Modelling of Dense and Complex Granular Flow in High Shear Mixer Granulator - a CFD Approach, Chemical Engineering Science, accepted, 2009.
[46] H.S. Chen, T. Zhang, B. Dou, V. Dupont, P.T. Williams, M. Ghadiri and Y.L. Ding, Thermodynamic Analyses of Adsorption Enhanced Steam Reforming of Glycerol for Hydrogen Production, International Journal of Hydrogen Energy, in press.
[47] L. Zhang, Y. Jiang, Y.L. Ding, N. Daskalakis and L. Jeuken, M. Povey and D.W. York, Mechanistic investigation into antibacterial behaviour of suspension of ZnO nanoparticles against E. coli, Journal of Nanoparticle Research, 2009, Accepted.
[48] W.P. Lee, H. Chen, R. Dryfe and Y.L. Ding, Kinetics of Nanoparticles Synthesis by Liquid-liquid Interfacial Reaction, Colloids and Surfaces A, in press, 2009.
[49] H. Chen, Y.L. Ding, A. Lapkin and X. Fan, Rheological behaviour of ethylene glycol-titanate nanotube nanofluids, Journal of Nanoparticle Research, in press, 2009
[50] Binlin Dou, Valerie Dupont, P.T. Williams, H. Chen and Y.L. Ding, Thermogravimetric kinetics of crude glycerol, Bioresource Technology, 100 (9), 2613-2620, 2009.
[51] Y. He, Y. Men, Y. Zhao, H.L. Lu, Y.L. Ding, Numerical investigation into the convective heat transfer of TiO2 nanofluids flowing through a straight tube under the laminar flow conditions, Applied Thermal Engineering, 29(10), 1965-1972, 2009.
[52] H. Chen, N.T. Cong, W. Yang, C. Tan, Y.L. Li, Y.L. Ding, Progress in electrical energy storage system—a critical review, 19 (3), 291-312, Progress in Natural Science, 2009.
[53] H. Chen, S. Witharana, Y. Jin, C.Y. Kim, Y.L. Ding,  Predicting thermal conductivity of liquid suspensions of nanoparticles (nanofluids) based on rheology, 7(2), 151-157, Particuology, 2009
[54] H. Chen, Y.L. Ding and A. Lapkin, Rheological behaviour of nanofluids containing tube / rod-like particles, Powder Technology, in press, 2009.
[55] A. Hassanpour, C.C. Kwan, N. Rahmanian, Y.L. Ding, S.J. Antony, X. Jia and M. Ghadiri, Effect of granulation scale-up on the structure and strength of granules, Powder Technology, 189, 304-312, 2009.
[56] B.L. Dou, V. Dupont, G. Rickett, N. Blakeman, P.T. Williams, H. Chen, Y.L. Ding and M. Ghadiri (2009) Hydrogen production by sorption-enhanced steam reforming of glycerol, Bioresource Technology, in press, 2009.
[57] M.J.W. Povey, T.S. Awad, R. Huo and Y.L. Ding (2009) Quasi-isothermal crystallisation kinetics, non-classical nucleation and surfactant-dependent crystallisation of emulsions, European Journal of Lipid Science & Technology, 111, 236-242.

 

2008年
[58] D. Wen, Y.L. Ding and G. Lin, Phase change heat transfer of liquid nitrogen upon injection into aqueous based TiO2 nanofluids, Journal of Nanoparticle Research, 10, 987-996, 2008.
[59] W. Yang and Y.L. Ding, Gas classification of particles using a packed bed, Particle and Particle System Characterisation, 25, 376-382, 2008.
[60] X. Fan, H. Chen, Y.L. Ding, P.K. Plucinski and A.A. Lapkin, Potential of ‘nanofluids’ to further intensify microreactors, Green Chemistry, 10, 670-677, 2008.   
[61] Y. Song, N. McMillan, D. Long, J. Thiel, Y.L. Ding, H. Chen, N. Gadegaard and L. Cronin, Design of hydrophobic polyoxometalate hybrid assemblies beyond surfactant encapsulation, Chemistry - A European Journal, 14, 2349 – 2359, 2008.
[62] Y.L. Ding, Y. He, N.T. Cong, W. Yang and H. Chen, Hydrodynamics and heat transfer of gas-solid two-phase mixtures flowing through packed beds, Progress in Natural Science, 18, 1185-1196, 2008.
[63] M. Giraldo, Y.L. Ding and R.A. Williams, Boundary integral study of nanparticle flow behaviour in the proximity of a solid wall, Journal of Physics D: Applied Physics, 41, 085503, 2008.
[64] L. Zhang, Y.L. Ding, M. Povey and D.W. York, ZnO nanofluids - a potential antibacterial agent, Progress in Natural Science, 18, 939-944, 2008.  
[65] E.K. Goharshadi, Y.L. Ding and P. Nancarrow, Green synthesis of ZnO nanoparticles in a room-temperature ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide, Journal of Physics and Chemistry of Solids, 69, 2057-2060, 2008.
[66] H. Chen, Y. He, J. Zhu, H. Alias, Y.L. Ding, P. Nancarrow, C. Hardacre, D. Rooney and C. Tan, Rheological and heat transfer behaviour of the ionic liquid, [C4mim][NTf2], International Journal of Heat and Fluid Flow, 29, 149-155, 2008.   
[67] B.H. Ng, Y.L. Ding and M. Ghadiri, On the relative importance of the kinetic and frictional contributions to granular motion in an annular Couette flow, Chemical Engineering Science, 63, 1733-17399, 2008.
[68] B.H. Ng, C.C. Kwan, Y.L. Ding, M. Ghadiri, X.F. Fan and D.J. Parker, Granular flow fields in vertical high shear mixer granulators, AIChE Journal, 54, 415-426, 2008.
[69] E.K. Goharshadi, Y.L. Ding and P. Nancarrow, Ultrasound-assisted green synthesis of nanocrystalline ZnO in the ionic liquid [hmim] [NTf2], Ultrasonics Sonochemistry, 16, 120-123, 2008.
[70] N. Rahmanian, M. Ghadiri and Y.L. Ding, Effect of scale of operation on granule strength in high shear granulators, Chemical Engineering Science, 63, 915-923, 2008.
[71] W. Yang, F. Yang and Y.L. Ding, A numerical investigation into the solids phase chromatography using a combined continuous and discrete approach, Particuology, 6, 557-571, 2008.

 

2007年
[72] L. Gao, X. Zhou and Y.L. Ding, Effective thermal and electrical conductivity of carbon nanotube composites, Chemical Physics Letters, 434, 297-300, 2007.
[73] N.T. Cong, Y. He, H. Chen, Y.L. Ding and D. Wen, Heat transfer of gas-solid two-phase mixtures flowing through a packed bed under constant wall heat flux conditions, Chemical Engineering Journal, 130, 1-10, 2007.
[74] W. Yang, C.C. Kwan, Y.L. Ding, M. Ghadiri and K.J. Roberts, Milling of sucrose, Powder Technology, 174, 14-17, 2007.
[75] H. Watanabe, M. Ghadiri, T. Matsuyama, Y.L. Ding, K.G. Pitt, H. Maruyama, S. Matsusaka and H. Masuda, Triboelectrification of pharmaceutical powders by particle impact, International Journal of Pharmaceutics, 334, 149-155, 2007.
[76] L. Zhang, Y.L. Ding, M. Povey and D.W. York, Investigation into the antibacterial behaviour of suspensions of ZnO nanoparticles (ZnO nanofluids), Journal of Nanoparticle Research, 9, 479-489, 2007.
[77] B.H. Ng, C.C. Kwan, Y.L. Ding, M. Ghadiri and X.F. Fan, Solids motion in a conical frustum-shaped high shear mixer granulator, Chemical Engineering Science, 62, 756-765, 2007.
[78] Y. He, Y. Jin, H. Chen, Y.L. Ding, D. Cang, H. Lu, Heat transfer and flow behaviour of aqueous suspensions of TiO2 nanoparticles (nanofluids) flowing upward through a vertical pipe, International Journal of Heat and Mass Transfer, 50, 2272-2281, 2007.
[79] Y. He, H. Chen, Y.L. Ding, and B. Lickiss, Numerical study of particle segregation of binary mixtures in a rotating drum mixer, Chemical Engineering Research and Design, 85(A), 963-973, 2007.
[80] D. Wen, N.T. Cong, Y. He, H. Chen and Y.L. Ding, Heat transfer of gas-solid two-phase mixtures flowing through a packed bed, Chemical Engineering Science, 62, 4241-4249, 2007.
[81] Y.L. Ding, H. Chen, Y. He, A.A. Lapkin, M. Yeganeh, L. Siller and Y. Butenko, Forced convective heat transfer of nanofluids, Advanced Powder Technology, 18, 813-824, 2007.
[82] H.S. Chen, Y.L. Ding, Y.R. He and C.Q. Tan, Rheological behaviour of ethylene glycol based titania nanofluids, Chemical Physics Letter, 444, 333-337, 2007.
[83] G. Koumpouras, E. Alpay, A. Lapkin, Y.L. Ding and F. Stepanek, The effect of adsorbent characteristics on the performance of a continuous sorption-enhanced steam methane reforming process, Chemical Engineering Science, 62, 5632-5637, 2007.
[84] H. Chen, Y.L. Ding, and C. Tan, Rheological behaviour of nanofluids, New Journal of Physics, 9, 1-24, 2007.  
[85] Y.L. Ding, H. Chen, L. Wang, C.Y. Yang, Y. He, W. Yang, W.P. Lee, L. Zhang and R. Huo, Heat transfer intensification using nanofluids, KONA Powder and Particle, (25), 23-38 2007.
[86] H. Chen, W. Yang, Y. He, Y.L. Ding, L. Zhang, C. Tan, A. Lapkin and D.V. Bavykin, Heat transfer and flow behaviour of aqueous suspensions of titanate nanotubes (nanofluids), Powder Technology, 183, 63-72, 2007.     
[87] B.H. Ng, C.C. Kwan, Y.L. Ding, M. Ghadiri, X.F. Fan, Solids motion of calcium carbonate particles in a high shear mixer granulator: a comparison between dry and wet conditions, Powder Technology, 177, 1-11, 2007.     
[88] B.H. Ng, Y.L. Ding and M. Ghadiri, Assessment of the Kinetic-Frictional Model for Dense Granular Flow, Particuology, 50-58, 2007.     
[89] S.Y. Wang, Y. He, H. Lu, J. Zheng, G. Liu, and Y.L. Ding, Numerical simulations of flow behaviour of agglomerates of nano-size particles in bubbling and spouted beds with an agglomerate-based approach, Food and Bioproducts Processing, 85, 231-240, 2007.
[90] Y. He, H. Chen, Y.L. Ding and J.R Lickiss, Solids motion and segregation of binary mixtures in a rotating drum mixer, Chemical Engineering Research and Design,  85, 963-873, 2007.
[91] S. Li, Q. Yao, B. Chen, X. Zhang and Y.L. Ding, Molecular dynamics simulations of granular surface flow in rotating drums, Chinese Science Bulletin, 52, 692–700, 2007.

 

2006年
[92] D.S. Wen and Y.L. Ding, Heat transfer of gas flow through a packed bed, Chemical Engineering Science, 61, 3532-3542, 2006.
[93] S.Q. Li and Y.L. Ding Modelling of the behaviour of gas-solid two-phase mixtures flowing through packed beds, Chemical Engineering Science, 61, 1922-1931, 2006.
[94] D.S. Wen, H.S. Chen, Y.L. Ding and P. Dearman, Liquid nitrogen injection into a heat transfer fluid: pressure build-up and heat transfer, Cryogenics, 46, 740-748, 2006.
[95] Y.L. Ding, Hajar Alias, Dongsheng Wen, Richard A. Williams Heat transfer of aqueous suspensions of carbon nanotubes (CNT nanofluids), International Journal of Heat and Mass Transfer, 49, 240-250, 2006
[96] D.S. Wen and Y.L. Ding Natural convective heat transfer of suspensions of TiO2 nanoparticles (nanofluids), Transactions of IEEE on Nanotechnology, 5, 3, 220-227, 2006.
[97] Y.L. Ding, Z.L. Wang, D.S. Wen, M. Ghadiri, X. Fan and D. Parker Solids behaviour in a dilute gas-solid two-phase mixture flowing through monolith channels, Chemical Engineering Science, 61, 1561-1570, 2006.
[98] H. Watanabe, A. Samimi, Y.L. Ding, M. Ghadiri, T. Matsuyama and K. Pitt, Measurements of charge transfer due to single particle impact, Particle and Particle Systems Characterisation, 23, 2, 133-137, 2006.
[99] Y.R. He, H.L. Lu, D.S. Wen, Y.L. Ding, A numerical study on the gas fluidisation of secondary agglomerates of nanoparticles, Progress in Natural Science, 15, 111-116, 2006.
[100] Y.H. Jiang, D.P Liu, Y.L. Ding and  X.H. Liu, Study on polluting mechanism of dioctyl phthalate (DOP) released from polyvinyl chloride (PVC) packaging for apples, Progress in Natural Science, 15, 2006.
[101] Y. He, T.N. Cong and Y.L. Ding, Gas-solid two-phase mixtures flowing upward through a confined packed bed, Particle and Particle System Characterisation, 23, 1-10, 2006.
[102] Y.L. Ding, D. Wen and R.A. Williams, Pool boiling heat transfer of aqueous based TiO2 nanofluids, Journal of Enhanced Heat Transfer, 13, 231-244, 2006.
[103] H. Lu, Y.L. Ding and Y. He, Numerical simulations of flow behaviour of gas-solid two-phase flows in turbulent fluidised beds, Journal of Engineering Thermophysics, 2006.

 

2005年
[104] Y.L. Ding, Z.L. Wang, D.S. Wen, M. Ghadiri, X.F. Fan and D.J. Parker, Solids behaviour in a gas–solid two-phase mixture flowing through a packed particle bed, Chemical Engineering Science, 60, 5231-5239, 2005.
[105] Y.L. Ding, Z.L. Wang, D.S. Wen, M. Ghadiri, Hydrodynamics of gas–solid two-phase mixtures flowing upward through packed beds, Powder Technology, 153, 13-22, 2005.
[106] Y.L. Ding, Z.L. Wang, M. Ghadiri, D.S. Wen, Vertical upward flow of gas–solid two-phase mixtures through monolith channels, Powder Technology, 153, 51– 58, 2005.
[107] Y.L. Ding and D.S. Wen, Particle migration in a flow of nanoparticle suspensions, Powder Technology, 149, 84-92, 2005.
[108] D.S. Wen and Y.L. Ding, Experimental investigation into the pool boiling heat transfer of aqueous based  -alumina nanofluids, Journal of Nanoparticle Research, 7, 265-274, 2005.
[109] D.S. Wen and Y.L. Ding, Effect of particle migration on heat transfer in suspensions of nanoparticles flowing through minichannels, Microfluidics and Nanofluidics, 1, 2, 183– 189, 2005.
[110] D.J. Parker, X.F. Fan, R.N. Forster, P. Fowles, Y.L. Ding, J.P.K. Seville, Positron Imaging Studies of Rotating Drums, Canadian Journal of Chemical Engineering, 83, 83-87, 2005.
[111] C.C. Kwan, H. Mio, Y.Q. Chen, Y.L. Ding, F. Saito, D.G., Papadopoulos, A.C. Bentham, M. Ghadiri, Analysis of the milling rate of pharmaceutical powders using the Distinct Element Method (DEM), Chemical Engineering Science, 60, 5, 1441-1448, 2005.
[112] D.S. Wen and Y.L. Ding, Formulation of nanofluids for natural convective heat transfer applications, International Journal of Heat and Fluid Flow, 26, 855-864, 2005.