2009123113583635骞伟中

博士,教授,博士生导师

 

个人简历:

1992年,北京理工大学,化工与材料学院,本科毕业

1999年,北京服装学院,化工研究所,硕士毕业

2002年,清华大学,化工系,博士毕业

2002.7-2005.11,清华大学化工系,助理研究员

2005.11-2015.12清华大学化工系,副研究员

200812- 清华大学化工系,博士生导师

2008.2-2008.8美国康奈尔大学材料科学与工程系(访问副教授)

2015.12-, 清华大学化工系,教授

 

讲授课程:

本科生课程:石油化工工艺学(煤/天然气化工工艺),化工英语实践

研究生课程:化工高等实验

 

研究方向:

(1)   碳纳米材料(碳纳米管,石墨烯)制备技术及其金属基复合材料

(2)   超级电容储能用碳纳米电极材料、离子液体电解液及新型集流体开发

(3)   碳基复合吸附剂处理工业三废技术开发

(4)   微纳米分子筛合成及甲醇制芳烃催化剂开发

(5)   多段流化反应器技术及产业化(苯胺合成,甲醇芳构化,甲烷芳构化,甲醇合成,氯乙烯合成,间苯二腈及百菌清合成,氢氧复合,六氨氯化镁分解等)

学术兼职:

中国颗粒学会理事,能源颗粒材料专业委员会副主任

工信部“新兴产业百人会”成员

中国电工技术学会,超级电容器与储能技术专业委员会委员

中国硅酸盐学会,矿物加工分委会理事

中国超级电容产业联盟,技术与学术研究委员会副主任

《氮肥与合成气》,编委

2007年亚太颗粒会秘书长

2009年国际纳米管科学与应用大会秘书长

2011A3(中日韩)纳米材料会秘书长

2011年中国颗粒学会能源颗粒技术研讨会秘书长

 

研究团队:

在研团队:

博士后(陈兆辉)、博士生(田佳瑞,侯一林,杨周飞,胡日勒朝克图,张晨曦(合带),戴晓业(合带),李敬(合带))、硕士生(胡琼方,陈航,多尼(合带))、本科生(杨逸风,郭志韬,宋文龙)、技术人员(李敏,杨奕菲,于翔,汪剑)

已出站或毕业人员:

博士后(张鲁湘,王宁),博士生(郑超,沈葵,崔超婕,温倩(合带),王彤(合带),余云涛),硕士生(苏倡,孔垂岩,张金贵,田涛,聂晶琦,恽松,卢俨俨,李琰(合带),黄河(合带),凌晨(合带),刁士刚(合带),刘唐(合带),孙玉建(合带)),本科生(许骜然,李欢,马洋,常睿,蒋胜麟,郭晨怿,周志江,张颖华,黄巍,林大川)

 

工业业绩:

在中国建成3-10万吨/年苯胺流化床8台。

国际首套的万吨级甲醇制芳烃流化床再生系统。

 

所获荣誉:

中国产业研合作创新成果一等奖(2016,排名4

教育部自然科学一等奖(2015,排名3

中国石化联合会科技进步一等奖(2015,排名2

中石化科技进步三等奖(2014,排名8

教育部技术发明一等奖(2012,排名2

中国石油和化学工业协会青年科技突出贡献奖(2012

中国专利奖优秀奖(2010年,排名1

中国颗粒学会青年颗粒学奖(2008

国家科技进步二等奖(2008年,排名8,本单位排名2

教育部新世纪优秀人才计划(2007

教育部自然科学一等奖(2005,排名2

全国优秀博士学位论文奖(2005

 

指导学生所获荣誉:

北京市优秀硕士毕业生、清华大学优秀硕士论文、优秀硕士毕业生(崔超婕)(2012)(导师)

“三井化学杯”第五届大学生化工设计竞赛全国总决赛特等奖及最佳表现奖团队(指导教师)(2011

 

学术成果(*通讯作者):

1.  魏飞,骞伟中,《碳纳米管的宏量制备技术》,科学出版社,2012.

2.  碳纳米材料及储能代表工作

(1)               Cui CJ, Qian WZ*, Xiang L, Wei F* et al., Highly Electroconductive Mesoporous Graphene Nanofibers and Their Capacitance Performance at 4 V . J Am Chem Soc. 2014, 136,2256. ESI高被引文章.

(2)               Zhang RF, Zhang YY*, Zhang Q, Qian WZ, Wei F*.Superlubricity in centimetres-long double-walled carbon nanotubes under ambient conditions. Nature Nanotechn, 2013, 8,912。封面文章.

(3)               Wen Q, Qian WZ*, Nie JQ, Cao AY, Wei F*. et al. 100 mm long, Semiconducting, Triple-walled Carbon Nanotubes. Adv. Mater. 2010,22,1867.封面文章

(4)               Liu Y, Qian WZ*, Zhang Q, Cao AY, Li ZF, Zhou WP, Ma Y, Wei F. Hierarchical agglomerates of carbon nanotubes as high-pressure cushions. Nano Lett 2008,8,1323.

(5)               Xiang R, Luo GH, QianWZ*Zhang Q, Wei F*  et al. Encapsulation, compensation, and substitution of catalyst particles during continuous growth of carbon nanotubes. Adv. Mater. 2007, 19, 2360.

(6)               Kong CY, Qian WZ*, et al., Raising the performance of a 4 V supercapacitor based on an EMIBF4- single walled carbon nanotube nanofluid electrolyte, Chem Commun. 2013,49,10727.

(7)               Qian WZ*, Tian T, Guo CY, Wen Q, et al. Enhanced activation and decomposition of CH4 by the addition of C2H4 or C2H2 for hydrogen and carbon nanotube production. J. Phys. Chem. C 2008, 112,7588.

(8)               Yu YT, Cui CJ, Qian WZ*, Full capacitance potential of SWCNT electrode in ionic liquids at 4 V. J. Mater. Chem A, 2014,2,19897.

(9)               Qian WZ*, Wei F, Wang ZW, et al. What causes the carbon nanotubes collapse in a CVD process, J Chem Phys, 2003,118,878.

(10)           Cheng H, Qian WZ*, et al., Graphene-carbon nanotube hybrids as robust, rapid, reversible adsorbents for organics. Carbon 2017, 116,409.

3.分子筛合成及催化代表工作

(1)               Shen K, Qian WZ*, et al., Fabrication of c-Axis Oriented ZSM-5 Hollow Fibers Based on an in Situ Solid-Solid Transformation Mechanism, J Am Chem Soc, 2013,135,15322.

(2)               Zhang JG, Qian WZ*, etal., Increasing Para-xylene Selectivity in making aroamtics from methanol over a surface modified Zn/P/ZSM-5 catalyst. ACS Catal. 2015,5,2982.

(3)               Wang N, Qian WZ*, Wei F et al., Bayberry-like ZnO/MFI Zeolite as High Performance Methanol-to aromatics Catalyst. Chem Commun. 2016,52(10),2011,封面文章.

(4)               Shen K, Wang N, Qian WZ*, et al., Atmospheric pressure synthesis of nanosized ZSM-5 with enhanced catalytic performance for methanol to aromatics reaction. Catal Sci Techn. 2014,4,3840.

(5)               Hou YL, Wang N, Qian WZ*, Highly selective synthesis of large aromatic molecules with nano-zeolite: beyond the shape selectivity effect. RSC Adv., 2017, 7, 14309.

(6)               Wang N, Qian WZ*, Wei F. Fabrication and catalytic properties of three dimensional ordered zeolite arrays with interconnected micro-meso-macroporous structure. J Mater Chem A, 2016, 4,10834. 封面文章

4.      流化床强化工艺代表性工作

(1)               Su C, Qian WZ*, Xie Q, Wei F et al. Conversion of methanol with C5–C6 hydrocarbons into aromatics in a two-stage fluidized bed reactor. Catal Today 2016,264,63.

(2)               Wang T, Tang XP, Qian WZ*, Wei F. et al., Conversion of methanol to aromatics in fluidized bed reactor. Catal Today, 2014, 233,8.

(3)               Wei XB, Shi HB, Qian WZ,* Wei F*, et al., Gas-Phase Catalytic Hydrochlorination of Acetylene in a Two-Stage Fluidized-Bed Reactor. Ind Eng Chem Res, 2009,48,128.

(4)               Liu Y, Qian WZ*, Wei F, et al. Synthesis of High-Quality, Double-Walled Carbon Nanotubes in a Fluidized Bed Reactor. Chem Eng Techn. 2009,32,73.

(5)               Yong S, Qian WZ*, Wei F. et al., Highly selective synthesis of single-walled carbon nanotubes from methane in a coupled Downer-turbulent fluidized-bed reactor. J Energy Chem. 2013, 22,567.

(6)               Qian WZ, Liu T, Wang ZW, Wei F, Li YD et al., Production of hydrogen and carbon nanotubes from methane decomposition in a two-stage fluidized bed reactor. Appl Catal A, 2014, 260,223. 国际埃尼奖提名

(7)               Diao SG, Qian WZ*, Luo GH, Wei F, Wang Y. Gaseous catalytic hydrogenation of nitrobenzene to aniline in a two-stage fluidized bed reactor. Appl Catal A, 2005, 286,30

(8)               Qian WZ, Wei F*, Wang ZW, et al., Production of carbon nanotube in a packed bed and a fluidized bed.  AIChE J 2003, 49,619.