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Ali Reza Kamali

更新时间: 2019-01-18 13:58:27 阅读次数:4017
作者:


姓   名:

阿里·卡马里

性  别:


出生年月:

19772

国  籍:

英  国

毕业院校:

伊朗科学技术大学

E-mail :


ali@smm.neu.edu.cn, a.r.kamali@cantab.net


Homepage:

http://faculty.neu.edu.cn/smm/ali/dbdx.html



学术职位

  • 2016-今,4008com云顶集团,“双百计划”特聘教授。

  • 2017-2018剑桥大学客座教授

  • 2014-2017,剑桥大学,研究员

  • 2009-2014,剑桥大学,博士后研究员, 副研究员

  • 2007-2009,伊朗伊斯法罕技术大学,副教授、科研主任。


主要研究方向

  1. 先进材料(石墨烯、金刚石、钛合金、纳米硅等)的绿色制备

  2. 二次电池电极材料设计与优化

  3. 环境化学与保护


所在团队介绍

 Ali Reza Kamali,英国皇家化学会会士(FRSC),曾任职英国剑桥大学高级研究员、剑桥先进材料有限公司首席科学家,现任4008com云顶集团职教授,能源与环境材料研究中心(E2MC)主任。20199与英国伯恩茅斯大学合作建立4008com云顶集团-伯恩茅斯大学(NEU-BU)新材料联合研究中心,并获得国家留学基金委创新型人才国际合作项目资助,第一批资助期(2021-2023)内每年可自主选派5名联合培养博士生和2名联合培养硕士生前往英国学习交流

人才培养情况:

已指导出站1名博士后和毕业3名硕士研究生(人均发表2篇以上SCI检索论文);在读4名博士研究生(已发表多篇SCI检索论文);在读3名研三年级硕士生(人均已发表1SCI检索论文,人均在投稿1篇);在读研二年级硕士生3名。指导的研究生获得4008com云顶集团优秀硕士学位论文1人次,国家奖学金2人次,命名奖学金1人次。

实验室以英语作为日常科研活动语言,新生在2~4个月内均可顺利渡过语言交流障碍

科研项目情况:

以项目负责人主持英国、中国科研项目10余项,目前主持国家自然科学基金外国青年学者项目1项,中央高校基本科研业务费重点项目1项。

论文著作:

Energy Environ. Sci., J. Mater. Chemistry AGreen Chem.Carbon等期刊发表包括6篇封面文章在内的100余篇学术论文,论文引用1000余次。施普林格自然出版英文专著《Green Production of Carbon Nanomaterials in Molten Salts and Applications》。已获美国、英国、欧洲、澳大利亚、日本和中国授权专利共10项,完成5项成果转化。


5年期刊论文(https://www.researchgate.net/profile/Ali_Kamali7/research

20201著作,21篇论文,累计影响因子46.87,在SCI中被引用44

  1. A.R. Kamali, Green Production of Carbon Nanomaterials in Molten Salts and Applications, Springer Nature (2020) (Cited: 3)

  2.  W Zhu, A.R. Kamali*. Green molten salt synthesis and Li-ion storage performance of sodium dimolybdate, Journal of Alloys and Compounds, 831 (2020) 154781. (IF = 4.65, Cited: 5)

  3.  A Rezaei, B Kamali, A R Kamali*. Correlation between morphological, structural and electrical properties of graphite and exfoliated graphene nanostructures, Measurement, 150 (2020) 107087. (IF=3.36, Cited: 11)

  4. A R Kamali*,J Yang. Effect of molten salts on the structure, morphology and electrical conductivity of PET-derived carbon nanostructures, Polymer Degradation and Stability, 177 (2020) 109184. (IF=4.03, Cited: 5)  

  5.  Z He, A R Kamali*, Z Wang, Q Sun, Z Shi, D Wang. Rapid preparation and characterization of oxygen-deficient SnO2 nanobelts with enhanced Li diffusion kinetics, Journal of Electroanalytical Chemistry, 871 (2020) 114276. (IF=3.8, Cited: 2)

  6.  Tahereh Seifi, A.R.Kamali*, Anti-pathogenic activity of graphene nanomaterials: A review, Colloids and Surfaces B: Biointerfaces,https://doi.org/10.1016/j.colsurfb.2020.111509 (IF=4.39)  

  7.  K. Xie, A. R. Kamali*, Z. Shi, Q. Sun. Green electro-synthesis of Li2Fe3O5 microcrystals as high performance anode material for lithium-ion batteries, Journal of Electroanalytical Chemistry, 863 (2020) 114061. (IF = 3.8, Cited: 2)

  8.  L Labiadh, A R Kamali*. Textural, structural and morphological evolution of mesoporous 3D graphene saturated with methyl orange dye during thermal regeneration, Diamond and Related Materials, 103 (2020) 107698. (IF = 2.65, Cited: 6)

  9.  R Djouani, A R Kamali*. Preparation of photoactive graphene oxide-Cu2O/Cu nanostructures by the electrochemical treatment of Cu-Ni leaching solutions using graphite electrodes, Diamond and Related Materials, 109 (2020) 108088. (IF = 2.65, Cited: 2)

  10.  J Ye, A R Kamali*. Molten salt preparation and Li-storage performance of faceted Li2TiO3 crystals, Materials Letters, 277(2020) 128357. (IF = 3.2, Cited: 1)

  11. A R Kamali*. Clean production and utilisation of hydrogen in molten salts, RSC Advances, 10 (2020) 36020. (IF=3.12, Cited: 0)

  12.  S Wei, A R Kamali*. Dual-step air-thermal treatment for facile conversion of PET into porous carbon particles with enhanced dye adsorption performance, Diamond and Related Materials, 107 (2020) 107914. (IF = 2.65, Cited: 2)

  13.  D Qiao, K Xie, A R Kamali*. Green production of hydrogen-doped faceted cobalt microcrystals using water-assisted molten salt electro-reduction method, Materials Advances, 1 (2020) 2225-2235. (IF = pending)

  14.  L Tong, Q Zhao, A R Kamali, W Sand, H Yang. Effect of Graphite on Copper Bioleaching from Waste Printed Circuit Boards, Minerals, 10 (2020) 79. (IF = 2.38, Cited: 4)

  15.  Q Zhao, L Tong, A R Kamali, W Sand, H Y Yang*. Role of humic acid in bioleaching of copper from waste computer motherboards, Hydrometallurgy, 197 (2020) 105437. (IF = 3.38, Cited: 0)

  16.  G Born, S Tavakoli, I Dierking, A R Kamali, D Ege. Synergistic effect of graphene oxide and zoledronic acid for osteoporosis and cancer treatment, Scientific Reports, 10 (2020) 7827. (IF=4.00, Cited:1)

  17.  C Othmani, L Labiadh, C Liu, A R Kamali, F Takali. Influence of a piezoelectric ZnO intermediate layer on Rayleigh waves propagating in Sc43%AlN57%/ZnO/diamond hetero-structures subjected to uniaxial stress, European Physical Journal Plus, 135 (2020) 898. (IF=3.2)

  18.  P. Galář, A. Goyal, A. R. Kamali, D. Mariotti, W. Sun, Silicon nanostructures for energy conversion and devices: general discussion, Faraday Discussion 222 (2020) 433-435 (IF=3.712)

  19.  M. Dasog, A. Fucikova, A. Goyal, M. Greben, A.R. Kamali, K. Kůsová, M. Nestoklon, T. Popelář, W. Sun, M.L. Tang, Faraday Discussion 222 (2020) 294-303 (IF=3.712)

  20.  P. Ceroni, C. Crucho, A. Fucikova, A. Goyal, Y. He, A.R. Kamali, K.Kusova, G. Morselli, K. Dohnalova, J. Paulusse, H. Stephan, W. Sun, M.L. Tang, H. Zuilof, Synthesis and functionalisation of silicon nanostructures: general discussion, Optical and electronic properties: from theory to experiments: general discussion, Faraday Discussion 222 (2020)166-175 (IF=3.712)

  21.  P. Ceroni, Y. Chao, C. Crucho, L.De Cola, A. Fucikova, A. Goyal, J. Joo, A.R. Kamali, L. Osminkina, S. Silvestrini, H. Stephan, W. Sun, M. L. Tang, Silicon nanostructures for sensing and bioimaging: general discussion, Faraday Discussion 222 (2020) 384-389 (IF=3.712)

  22. L. Mohamadi, E. Bazrafshan, A. Rahdar, G. Labuto, A.R. Kamali*, Nanostructured MgO-enhanced catalytic ozonation of petrochemical wastewater, enhanced catalytic ozonation of petrochemical wastewater, Bol. Soc. Esp. Cerám. Vidr. (2020), https://doi.org/10.1016/j.bsecv.2020.06.002(IF=2.51)


2019 8篇论文,累计影响因子46.79,在SCI中被引用51

  1.  K Xie, A R Kamali*. Electro-reduction of hematite using water as the redox mediator, Green Chemistry, 21 (2019) 198-204. (IF=9.4, Cited: 5)

  2.  K Xie, A R Kamali*. Molten salt electrochemical production and in situ utilization of hydrogen for iron production, International Journal of Hydrogen Energy, 44 (2019) 24353-24359. (IF=4.9, Cited: 1)

  3.  L Labiadh, A R Kamali*. 3D graphene nanoedges as efficient dye adsorbents with ultra-high thermal regeneration performance, Applied Surface Science, 490(2019) 383-394. (IF=6.18, Cited: 13)

  4. A R Kamali*, S H Shishavan, M N Samani, A Rezaei, K B Kim. Ultra-fast shock-wave combustion synthesis of nanostructured silicon from sand with excellent Li storage performance, Sustainable Energy & Fuels, 3 (2019) 1396-1405. (IF=5.5, Cited: 5)

  5. A R Kamali*, J Yang, Q Sun. Molten salt conversion of polyethylene terephthalate waste into graphene nanostructures with high surface area and ultra-high electrical conductivity.Applied Surface Science, 476(2019) 539-551. (IF=6.18, Cited: 10)  

  6.  Z He, Q Sun, K Xie, P Lu, Z Shi,A R Kamali*. Reactive molten salt synthesis of natural graphite flakes decorated with SnO2 nanorods as high performance, low cost anode material for lithium ion batteries, Journal of Alloys and Compounds, 792 (2019) 1213-1222. (IF=4.65, Cited: 9)  

  7.  Z He, Q Sun, Z Shi, K Xie, A R Kamali*. Molten salt synthesis of oxygen-deficient SnO2 crystals with enhanced electrical conductivity, Applied Surface Science, 465(2019) 397-404. (IF=6.18, Cited: 6)  

  8.  L Labiadh, S. Ammar, A R Kamali. Oxidation/mineralization of AO7 by electro-Fenton process using chalcopyrite as the heterogeneous source of iron and copper catalysts with enhanced degradation activity and reusability, Journal of Electroanalytical Chemistry, 853 (2019) 113532. (IF=3.8, Cited: 2)  


2018 4篇论文,累计影响因子11.3,在SCI中被引用34

  1.  A. Rezaei, A. R. Kamali*. Green production of carbon nanomaterials in molten salts, mechanisms and applications, Diamond & Related Materials, 83 (2018) 146-161. (IF=2.65, Cited: 15)

  2. Kaya H, Bulut O, Kamali. AR, Ege D, L-Arginine modified multi-walled carbon nanotube/sulfonated poly(ether ether ketone) nanocomposite films for biomedical applications, Applied Surface Science, 444(2018) 168-176. (IF=6.18, Cited: 12)

  3.  F. Liu, X. Zhong, J. Xu, A. Kamali, Z. Shi, Temperature Dependence on Density, Viscosity, and Electrical Conductivity of Ionic Liquid 1-Ethyl-3-Methylimidazolium Fluoride, Applied Sciences, 8 (2018) 356. (IF=2.47, Cited: 5)

  4.  M.R. Kamali, A.R. Kamali, Preparation of borax pentahydrate from effluents of iron nanoparticles synthesis process, AIMS Energy 6 (2018) 1067. (IF=Pending, Cited:2)


2017 5篇论文,累计影响因子28.98,在SCI中被引用102

  1. A. R. Kamali*, H.K. Kim, K.B. Kim, V. R. Kumar, D. J. Fray, Large scale green production of ultra-high capacity anode consisting of graphene encapsulated silicon nanoparticles, Journal of Materials Chemistry A, 5(2017) 19126-19135. (IF=11.301, Cited: 32)

  2. A. R. Kamali*, Nanocatalytic conversion of CO2 into nanodiamonds, Carbon, 123 (2017) 205-215. (IF=8.82, Cited: 15)

  3. A. R. Kamali*, Scalable fabrication of highly conductive 3D graphene by electrochemical exfoliation of graphite in molten NaCl under Ar/H2 atmosphere, Journal of Industrial and Engineering Chemistry, 52 (2017) 18-27. (IF=5.278, Cited: 23)

  4.  D. Ege, I. Duru, A. R. Kamali, A. R. Boccaccini, Nitride, Zirconia, Alumina, and Carbide Coatings on Ti6Al4V Femoral Heads: Effect of Deposition Techniques on Mechanical and Tribological Properties, Advanced Engineering Materials, 19 (2017): 49-54. (IF=2.9, Cited: 5)

  5.  Duygu Ege, Ali Reza Kamali, Aldo R. Boccaccini, Graphene Oxide/Polymer-Based Biomaterials, Advanced Engineering Materials, 19 (2017): 16-34. (IF=2.906, Cited: 27)

2016 10篇论文,累计影响因子70.568,在SCI中被引用246

  1.  H.K. Kim, A. R. Kamali*, K.C. Roh, K.B. Kim, D. J. Fray, Dual coexisting interconnected graphene nanostructures for high performance supercapacitor applications, Energy & Environmental Science, 9(2016) 2249-2256. (IF=33.25, Cited: 60)

  2. A. R. Kamali*, Eco-friendly production of high quality low cost graphene and its application in lithium ion batteries, Green Chemistry 18 (2016) 1952-1964. (IF=9.4, Cited: 43)

  3. A. R. Kamali*, D. J. Fray, Electrochemical interaction between graphite and molten salts to produce nanotubes, nanoparticles, graphene and nanodiamonds, Journal of Materials Science 51 (2016), 569-576. (IF=3.44, Cited: 20)

  4.  C. Yerlikaya1, N. Ullah, A. R. Kamali*, R. V. Kumar,Size-controllable synthesis of lithium niobate nanocrystals using modified Pechini polymeric precursor method, Journal of Thermal Analysis and Calorimetery, 125 (2016)17-22. (IF=2.47, Cited: 9)

  5. A. R. Kamali*, J. Feighan, D. J. Fray, Towards large scale preparation of graphene in molten salts and its use in the fabrication of highly toughened alumina ceramics, Faraday Discussions, 190 (2016) 451-470. (IF=3.58, Cited: 23)

  6.  İ. Duru, D.u Ege, A.R. Kamali, Graphene Oxides for Removal of Heavy and Precious Metals from the Wastewater, Review Paper, Journal of Materials Science, DOI 10.1007/s10853-016-9913-8.(IF=2.59, Cited: 85)

  7. T.H. Okabe, A.R. Kamali et al., Advancement in knowledge of phenomena and processes: general discussion, Faraday Discussions, 190(2016) 525-549. (IF=3.712)

  8. T.H. Okabe, A. Kamali et al., Benefits to energy efficiency and environmental impact: general discussion, Faraday Discussions 190(2016) 161-204. (IF=3.712, Cited:2)

  9. T.H. Okabe, A. Kamali et al, Developments for nuclear reactors and spent fuels processing: general discussion, Faraday Discussions 190(2016) 399-419. (IF=3.712)

  10. Kuzmina, A.R. Kamali et al., Improvements of energy conversion and storage: general discussion, Faraday Discussions 190(2016) 291-306.  (IF=3.712, Cited:4)


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