汪伟个人资料
汪伟博士,
四川人,四川大学 化学工院 副教授。
汪伟博士 个简人历
2012年 第20届青年师教职业技能培训“优秀学员”称号
2012年 四川优省秀大学毕业生
2011年 教育部“博士研究生学新术人奖”
2011年 宝钢教育基金优秀学生奖
2011年 第一届全国生学制药工程研究壁报大赛全国一奖等
2011年 陶化氏学暑期实习“Winner of 2011 Dow Summer Intern Business Competition”
2011年 四大川学“优秀博士”称号
2011年 四川大学“优秀究研生”称号
2010年 陶氏化学教育发展奖学金“秀优论文奖”
2010年 四川大学“创新人才奖”
2010年 四川大学“优秀博士”称号
2009年 “The 3rd Asian Conference on Colloid & Interface Science”国际会议优秀论文奖
2008年 四川大学“优秀研究生”称号
SCI收录论文
[1] Liu Z., Wang W., Xie R., Ju X.J., Chu L.Y., 2016. Stimuli-responsive smart gating membranes. Chemical Society Reviews, 45(3): 460-475. (2014 Impact Factor = 33.383)
This work has been featured as the Inside Front Cover
[2] Xie R., Chu L.Y., Deng J.G., 2008. Membranes and membrane processes for chiral resolution. Chemical Society Reviews, 37(6): 1243-1263. (2014 Impact Factor = 33.383)
[3] Wang W., Zhang M.J., Chu L.Y., 2014. Functional polymeric microparticles engineered from controllable microfluidic emulsions. Accounts of Chemical Research, 47(2): 373-384.(2014 Impact Factor = 22.323)
[4] Chu L.Y., Yamaguchi T., Nakao S., 2002. A molecular recognition microcapsule for environmental stimuli-responsive controlled-release. Advanced Materials, 14(5): 386-389. (2014 Impact Factor = 17.493)
This work was featured in the Front Cover
[5] Xia L.W., Xie R., Ju X.J., Wang W., Chen Q.M., Chu L.Y., 2013. Nano-structured smart hydrogels with rapid response and high elasticity. Nature Communications, 4: 2226, doi: 10.1038/ncomms3226. (2014 Impact Factor = 11.470)
Most-Read Articles of Nature Communications, ranked No.18 in the Top Content of Most-Read Articles on August 6, 2013; No.16 on August 7, 2013; No.14 on August 8, 2013; No.10 on August 9, 2013; No.8 on August 10, 2013; No.8 on August 11, 2013; No.8 on August 12, 2013; No.8 on August 14, 2013; No.5 on August 15, 2013.
[6] Zhao H., Guo X., He S., Zeng X., Zhou X., Zhang C., Hu J., Wu X., Xing Z., Chu L.Y., He Y., Chen Q.M., 2014. Complex self-assembly of pyrimido[4,5-d]pyrimidine nucleoside supramolecular structures. Nature Communications, 5: 3108, doi: 10.1038/ncomms4108. (2014 Impact Factor = 11.470)
[7] Wang W., Zhang M.J., Xie R., Ju X.J., Yang C., Mou C.L., Weitz D.A., Chu L.Y., 2013. Hole-shell microparticles from controllably evolved double emulsions. Angewandte Chemie International Edition, 52(31): 8084-8087.(2014 Impact Factor = 11.261)
Front Cover Story
[8] Chu L.Y., Utada A.S., Shah R.K., Kim J.W., Weitz D.A., 2007. Controllable monodisperse multiple emulsions. Angewandte Chemie International Edition, 46(47): 8970-8974.(2014 Impact Factor = 11.261)
This work has been featured in theFrontispiece;
Materials Today;
今材日料;
Chemical & Engineering News;
SEAS (School of Engineering and Applied Science) Soft Matter Wiki of Harvard University;
Poster for “New Concept in Microfluidics: Theory and Application (April 20, 2007, Harvard)”;
Poster (background image) for “32nd New England Complex Fluids Meeting (September 28, 2007, University of Connecticut)”;
“Complex Fluids” T-Shirt (image on the back) for “32nd New England Complex Fluids Meeting (September 28, 2007, University of Connecticut)”;
Flyer (optical micrographs for New England States fill) for “33rd New England Complex Fluids Meeting” (Harvard University, November 30, 2007);
Flyer (optical micrographs for New England States fill) for “37th New England Complex Fluids Meeting” (Harvard University, December 5, 2008);
Flyer (optical micrographs for New England States fill) for “49th New England Complex Fluids Meeting” (Harvard University, December 2, 2011);
Flyer (optical micrographs for New England States fill) for “53th New England Complex Fluids Meeting” (Harvard University, November 30, 2012); and
Flyer (optical micrographs for New England States fill) for “61st New England Complex Fluids Meeting” (Harvard University, December 5, 2014)
[9] Chu L.Y., Li Y., Zhu J.H., Chen W.M., 2005. Negatively thermoresponsive membranes with functional gates driven by zipper-type hydrogen-bonding interactions. Angewandte Chemie International Edition, 44(14): 2124-2127.(2014 Impact Factor = 11.261)
[10] Shah R.K., Shum H.C., Rowat A.C., Lee D., Agresti J.J., Utada A.S., Chu L.Y., Kim J.W., Fernandez-Nieves A., Martinez C.J., Weitz D.A., 2008. Designer emulsions using microfluidics. Materials Today, 11(4): 18-27.(2014 Impact Factor = 14.107)
Cover Story;
Invited Review;
Ranked No.11 in Top 25 Hottest Articles during 04/2008-06/2008
[11] Yao C., Liu Z., Yang C., Wang W., Ju X.J., Xie R., Chu L.Y., 2015. Poly(N-isopropylacrylamide)-clay nanocomposite hydrogels with responsive bending property as temperature-controlled manipulators. Advanced Functional Materials, 25(20): 2980-2991.(2014 Impact Factor = 11.805)
This work has been featured in the Back Cover
[12] Wei J., Ju X.J., Zou X.Y., Xie R., Wang W.,Liu Y.M., Chu L.Y., 2014. Multi-stimuli-responsive microcapsules for adjustable controlled-release. Advanced Functional Materials, 24(22): 3312-3323.(2014 Impact Factor = 11.805)
This work has been featured in the Inside Front Cover
[13] Liu Z., Luo F., Ju X.J., Xie R., Luo T., Sun Y.M., Chu L.Y., 2012. Positively K-responsive membranes with functional gates driven by host-guest molecular recognition. Advanced Functional Materials, 22(22): 4742-4750.(2014 Impact Factor = 11.805)
This work has been featured in theFrontispiece
[14] Yang M., Chu L.Y., Wang H.D., Xie R., Song H., Niu C.H., 2008. A thermo-responsive membrane for chiral resolution. Advanced Functional Materials, 18(4): 652-663.(2014 Impact Factor = 11.805)
[15] Chu L.Y., Kim J.W., Shah R.K., Weitz D.A., 2007. Monodisperse thermo-responsive microgels with tunable volume-phase transition kinetics. Advanced Functional Materials, 17(17): 3499-3504.(2014 Impact Factor = 11.805)
This work has been featured in the Front Cover
[16] Qu J.B., Chu L.Y., Yang M., Xie R., Hu L., Chen W.M., 2006. A pH-responsive gating membrane system with pumping effects for improved controlled-release. Advanced Functional Materials, 16(14): 1865-1872.(2014 Impact Factor = 11.805)
This work has been featured in the Front Cover; and
High-Tech Materials Alert
[17] Xiao X.C., Chu L.Y., Chen W.M., Wang S., Li Y., 2003. Positively thermo-sensitive monodisperse core-shell microspheres. Advanced Functional Materials, 13(11): 847-852.(2014 Impact Factor = 11.805)
This work was featured in the Front Cover
[18] Lin S., Wang W., Ju X.J., Xie R., Liu Z., Yu H.R., Zhang C., Chu L.Y., 2016. Ultrasensitive microchip based on smart microgel for real-time on-line detection of trace threat analytes. Proceedings of the National Academy of Sciences of the United States of America (PNAS), 113(8): 2023-2028.(2014 Impact Factor = 9.674)
[19] Chu L.Y., Li Y., Zhu J.H., Wang H.D., Liang Y.J., 2004. Control of pore size and permeability of a glucose-responsive gating membrane for insulin delivery. Journal of Controlled Release, 97(1): 43-53.(2014 Impact Factor = 7.705)
[20] Liu Z., Luo F., Ju X.J., Xie R., Sun Y.M., Wang W., Chu L.Y., 2013. Gating membranes for water treatment: Detection and removal of trace Pb ions based on molecular recognition and polymer phase transition. Journal of Materials Chemistry A, 1(34): 9659-9671.(2014 Impact Factor = 7.443)
This work has been featured as Inside Front Cover Story
[21] Liu Z., Liu L., Ju X.J., Xie R., Zhang B., Chu L.Y., 2011. K-recognition capsules with squirting release mechanisms. Chemical Communications, 47(45): 12283-12285.(2014 Impact Factor = 6.834)
This work has been featured in Back Cover;
Chemistry World;
Nano News Net; and
ChemRar
[22] Zhao H., He S.L., Yang M.L., Guo X.R., Xin G., Zhang C.Y., Ye L., Chu L.Y., Xing Z.H., Huang W., Chen Q.M., He Y., 2013. Micro-flowers changing to nano-bundle aggregates by translocation of the sugar moiety in Janus TA nucleosides. Chemical Communications, 49(36): 3742-3744.(2014 Impact Factor = 6.834)
[23] Yang X.L., Ju X.J., Mu X.T., Wang W., Xie R., Liu Z., Chu L.Y., 2016. Core-shell chitosan microcapsules for programmed sequential drug release. ACS Applied Materials & Interfaces, in press.(2014 Impact Factor = 6.723)
[24] He F., Wang W., He X.H., Yang X.L., Li M., Xie R., Ju X.J., Liu Z., Chu L.Y., 2016. Controllable multi-compartmental capsules with distinct cores and shells for synergistic release. ACS Applied Materials & Interfaces, in press.(2014 Impact Factor = 6.723)
[25] Shi K., Liu Z., Wei Y.Y., Wang W., Ju X.J., Xie R., Chu L.Y., 2015, Near-infrared light-responsive poly(N-isopropylacrylamide)/graphene oxide nanocomposite hydrogels with ultrahigh tensibility. ACS Applied Materials & Interfaces, 7(49): 27289-27298.(2014 Impact Factor = 6.723)
[26] He X.H., Wang W., Liu Y.M., Jiang M.., Wu F., Deng K., Liu Z., Ju X.J., Xie R., Chu L.Y., 2015. Microfluidic fabrication of bio-inspired microfibers with controllable magnetic spindle-knots for 3D assembly and water collection. ACS Applied Materials & Interfaces, 7(31): 17471-17481.(2014 Impact Factor = 6.723)
[27] Zhang M.J., Wang W., Yang X.L., Ma B., Liu Y.M., Xie R., Ju X.J., Liu Z., Chu L.Y., 2015. Uniform microparticles with controllable highly-interconnected hierarchical porous structures. ACS Applied Materials & Interfaces, 7(25): 13758-13767.(2014 Impact Factor = 6.723)
This work has been featured as the Cover Story
[28] Jiang M.Y., Ju X.J., Fang L., Liu Z., Yu H.R., Jiang L., Wang W., Xie R., Chen Q.M., Chu L.Y., 2014. A novel smart microsphere with K-induced shrinking and aggregating property based on responsive host-guest system.ACS Applied Materials & Interfaces, 6(21): 19405-19415.(2014 Impact Factor = 6.723)
[29] Liu Y.M., Ju X.J., Xin Y., Zheng W.C., Wang W., Wei J., Xie R., Liu Z., Chu L.Y., 2014. A novel smart microsphere with magnetic core and ion-recognizable shell for Pb adsorption and separation.ACS Applied Materials & Interfaces, 6(12): 9530-9542.(2014 Impact Factor = 6.723)
[30] Mei L., He F., Zhou R.Q., Wu C.D., Liang R., Xie R., Ju X.J., Wang W., Chu L.Y., 2014. A novel intestinal-targeted Ca-alginate-based carrier for pH-responsive protection and release of Lactic acid bacteria.ACS Applied Materials & Interfaces, 6(8): 5962-5970.(2014 Impact Factor = 6.723)
[31] Deng N.N., Sun J., Wang W., Ju X.J., Xie R., Chu L.Y., 2014. Wetting-induced coalescence of nanoliter drops as microreactors in microfluidics.ACS Applied Materials & Interfaces, 6(6): 3817-3821.(2014 Impact Factor = 6.723)
[32] Liu Y.M., Wang W., Zheng W.C., Ju X.J., Xie R., Zerrouki D., Deng N.N., Chu L.Y., 2013. Hydrogel-based micro-actuators with remote-controlled locomotion and fast Pb-response for micromanipulation.ACS Applied Materials & Interfaces, 5(15): 7219-7226.(2014 Impact Factor = 6.723)
[33] Meng Z.J., Wang W., Liang X., Zheng W. C., Deng N.N., Xie R., Ju X.J., Liu Z., Chu L.Y., 2015. Plug-n-play microfluidic systems from flexible assembly of glass-based flow-control modules. Lab on a Chip, 15(8): 1869-1878..(2014 Impact Factor = 6.115)
[34] Sun Y.M., Wang W., Wei Y.Y., Deng N.N., Liu Z., Ju X.J., Xie R., Chu L.Y., 2014. In situ fabrication of temperature- and ethanol-responsive smart membrane in microchip.Lab on a Chip, 14(14): 2418-2427.(2014 Impact Factor = 6.115)
This paper has been featured as “HOT Article” in Lab on a Chip Blog
[35] Lin S., Wang W., Ju X.J., Xie R., Chu L.Y., 2014. A simple strategy for in situ fabrication of smart hydrogel microvalve within microchannels for thermostatic control. Lab on a Chip, 14(15): 2626-2634.(2014 Impact Factor = 6.115)
This paper has been featured in Inside Front Cover; and as
“HOT Article” in Lab on a Chip Blog
[36] Deng N.N., Wang W., Ju X.J., Xie R., Weitz D.A., Chu L.Y., 2013. Wetting-induced formation of controllable monodisperse multiple emulsions in microfluidics. Lab on a Chip, 13(20): 4047-4052.(2014 Impact Factor = 6.115)
This work has been featured in Back Cover
[37] Deng N.N., Sun S.X., Wang W., Ju X.J., Xie R., Chu L.Y., 2013. A novel surgery-like strategy for droplet coalescence in microchannels. Lab on a Chip, 13(18): 3653-3657.(2014 Impact Factor = 6.115)
[38] Wang W., Xie R., Ju X.J., Luo T., Liu L., Weitz D.A., Chu L.Y., 2011. Controllable microfluidic production of multicomponent multiple emulsions. Lab on a Chip, 11(9): 1587-1592.(2014 Impact Factor = 6.115)
This work has been featured in Back Cover;
Chemistry World;
Micronews;
Lab on a Chip Blog;
Chemistry in Our Life;
I-Micronews; and
Most Read Articles in May 2011.
[39] Deng N.N., Meng Z.J., Xie R., Ju X.J., Mou C.L., Wang W., Chu L.Y., 2011. Simple and cheap microfluidic devices for preparation of monodisperse emulsions. Lab on a Chip, 11(23): 3963-3969.(2014 Impact Factor = 6.115)
This work has been featured in Back Cover; and
Lab on a Chip Blog
[40] Wahrmund J., Kim J.W., Chu L.Y., Wang C., Li Y., Fernandez-Nieves A., Weitz D.A., Krokhin A., Hu Z., 2009. Swelling kinetics of a microgel shell. Macromolecules, 42(23): 9357-9365.(2014 Impact Factor = 5.800)
[41] Utada A.S., Chu L.Y., Fernandez-Nieves A., Link D.R., Holtze C., Weitz D.A., 2007. Dripping, jetting, drops and wetting: The magic of microfluidics. MRS Bulletin, 32(9): 702-708.(2014 Impact Factor = 5.667)
“Technical Features” article;
This work was featured in the Front Cover
[42] Yu H.R., Ju X.J., Xie R., Wang W., Zhang B., Chu L.Y., 2013. Portable diagnosis method of hyperkalemia using potassium-recognizable poly(N-isopropylacrylamide-co-benzo-15-crown-5-acrylamide) copolymers. Analytical Chemistry, 85(13): 6477-6484. (2014 Impact Factor = 5.636)
.
l 主持项目
[1] 国家自然科学基金面上目项“惠斯通桥型微流控抗原检测片芯的构建及其微流体流动特性研究”(21576167),2016—2019,项目负责人;
[2] 国家自然科学金基项目“仿金毛狗蕨茸毛微结构壳的聚糖超细纤维膜的制备与性能究研”(21306117),2014—2016,项目负责人;
[3] 教育部高等校学博士学科点专项科研基金新教基师金项目“微型竹状结构超细纤的维微流控制备及其性能研究”(20130181120063),2014—2016,项目负责人;
[4] 四川大优学秀青年学者科研基金项目“微控流法构建结构可控的微尺度高分功子能材料”(2014SCU04A03),2014—2016,项目负责人;
[5] 广东省功能软凝聚态物质重点验实室开放课题基金项目(201501),2015—2016,目项负责人;
[6] 四川大学青年教师科研启动基金目项(2012SCU11073),2012—2013,项目负人责;
l 主研项目
[7] 国家自然科学金基重点项目“多相微分散体系流与动传递性能的基础研究”(20136002)子课题,2011—2014,子课题第一主研
[8] 国家杰出青年科基学金项目“环境响应型智能膜材创料新与膜过程强化基础研究”(20825622),2009—2012,第三主研
[9] 全国优秀博士学位论文作专者项资金资助项目“微流控构建尺微度乳液相界面及制备新型微球囊微材料的基础研究”(201163),2011—2015,第主四研
[10] 国自家然科学基金项目“环境响应型洛特伊木马式微囊膜可控制备与控传释质机理”(21076127),2011—2013,第四主研
[11] 国家自科然学基金项目“固载温敏性微球智的能复合膜的制备与亲和分离性研能究”(20806049),2009—2011,主研
[12] 教育部高等学校士博学科点专项科研基金新教师基项金目“新型温敏亲和分离智能复膜合的研究”(200806101045),2009—2011,主研
[13] 国重家点基础研究发展计划(973划计)课题“智能膜材料设计与制科备学研究”(2009CB623407),2009—2013,主研
[14] 国自家然科学基金重点项目“微流控建构微尺度相界面及制备新型功能料材的基础研究(21136006),2012—2016,主研
[15] 教育部“江长学者和创新团队发展计划”创团新队资助项目“生物医用高分子能功材料”(IRT1163),2012—2014,主研
1) 夏烈文, 褚良银, 晓巨洁, 谢锐, 汪伟. “高子分微凝胶复合结构的高强度水凝制胶备方法”. 中国发明专利申专请利申请日2012.5.7.
2) 汪伟, 褚良银, 谢锐, 巨晓洁, 罗涛, 刘丽. “制备单分散多组分多乳重液的微流控方法及装置”. 国中发明专利申请X, 专利申请日2011.3.20.
3) 刘丽, 褚良银, 杨平建, 汪伟, 巨晓洁, 谢锐. “具有pH突释特性的壳聚糖空中和核壳微囊的制备方法”. 国中发明专利申请, 专利申请日2011.2.24.
4) 汪伟, 褚良银, 刘丽, 巨晓洁, 谢锐. “热引发爆自式磁靶向微囊及其制备方法”. 中国发明专利专利申请日2009.7.13, 专利授权日2011. 7.1.
考参资料1. 汪伟博士 .四川大学化工学院“膜科学与功材能料研究室”[引用日期2012-10-19]2. 汪伟博士 个人简历 .四川大学[引用日期2016-04-09]3. SCI收录论文 .四川大学[引用日期2016-04-09]4. 汪伟博士 主持承担科研项目: .四川大学[引用日期2016-04-09]
汪伟简历
汪伟博士 个简人历
| 2003.9 - 2007.6 | 四川大学 吴玉章学院 科本 |
| 2007.9 - 2012.6 | 四川学大 化工学院 硕博连读 |
| 2012.7 - 2014.6 | 四川大学 化工院学 讲师 |
| 2011年 | 教育部博士研究生学术人新奖 |
| 2012年 | 四川大学“优秀青年人才”划计 |
| 2013年度 | 四川省优秀博士学位论文奖得获者 |
| 2014年 | 英国皇家化学会(RSC)《Lab on a Chip》2014年度新科学家(Lab on a Chip Emerging Investigator 2014) |
| 2015年 | 四大川学青年科技人才奖 |
| 2014.7 至今 | 四大川学 化工学院 副教授 |
汪伟奖获
2012年 第20届青年师教职业技能培训“优秀学员”称号
2012年 四川优省秀大学毕业生
2011年 教育部“博士研究生学新术人奖”
2011年 宝钢教育基金优秀学生奖
2011年 第一届全国生学制药工程研究壁报大赛全国一奖等
2011年 陶化氏学暑期实习“Winner of 2011 Dow Summer Intern Business Competition”
2011年 四大川学“优秀博士”称号
2011年 四川大学“优秀究研生”称号
2010年 陶氏化学教育发展奖学金“秀优论文奖”
2010年 四川大学“创新人才奖”
2010年 四川大学“优秀博士”称号
2009年 “The 3rd Asian Conference on Colloid & Interface Science”国际会议优秀论文奖
2008年 四川大学“优秀研究生”称号
汪伟学术论文
SCI收录论文
[1] Liu Z., Wang W., Xie R., Ju X.J., Chu L.Y., 2016. Stimuli-responsive smart gating membranes. Chemical Society Reviews, 45(3): 460-475. (2014 Impact Factor = 33.383)
This work has been featured as the Inside Front Cover
[2] Xie R., Chu L.Y., Deng J.G., 2008. Membranes and membrane processes for chiral resolution. Chemical Society Reviews, 37(6): 1243-1263. (2014 Impact Factor = 33.383)
[3] Wang W., Zhang M.J., Chu L.Y., 2014. Functional polymeric microparticles engineered from controllable microfluidic emulsions. Accounts of Chemical Research, 47(2): 373-384.(2014 Impact Factor = 22.323)
[4] Chu L.Y., Yamaguchi T., Nakao S., 2002. A molecular recognition microcapsule for environmental stimuli-responsive controlled-release. Advanced Materials, 14(5): 386-389. (2014 Impact Factor = 17.493)
This work was featured in the Front Cover
[5] Xia L.W., Xie R., Ju X.J., Wang W., Chen Q.M., Chu L.Y., 2013. Nano-structured smart hydrogels with rapid response and high elasticity. Nature Communications, 4: 2226, doi: 10.1038/ncomms3226. (2014 Impact Factor = 11.470)
Most-Read Articles of Nature Communications, ranked No.18 in the Top Content of Most-Read Articles on August 6, 2013; No.16 on August 7, 2013; No.14 on August 8, 2013; No.10 on August 9, 2013; No.8 on August 10, 2013; No.8 on August 11, 2013; No.8 on August 12, 2013; No.8 on August 14, 2013; No.5 on August 15, 2013.
[6] Zhao H., Guo X., He S., Zeng X., Zhou X., Zhang C., Hu J., Wu X., Xing Z., Chu L.Y., He Y., Chen Q.M., 2014. Complex self-assembly of pyrimido[4,5-d]pyrimidine nucleoside supramolecular structures. Nature Communications, 5: 3108, doi: 10.1038/ncomms4108. (2014 Impact Factor = 11.470)
[7] Wang W., Zhang M.J., Xie R., Ju X.J., Yang C., Mou C.L., Weitz D.A., Chu L.Y., 2013. Hole-shell microparticles from controllably evolved double emulsions. Angewandte Chemie International Edition, 52(31): 8084-8087.(2014 Impact Factor = 11.261)
Front Cover Story
[8] Chu L.Y., Utada A.S., Shah R.K., Kim J.W., Weitz D.A., 2007. Controllable monodisperse multiple emulsions. Angewandte Chemie International Edition, 46(47): 8970-8974.(2014 Impact Factor = 11.261)
This work has been featured in theFrontispiece;
Materials Today;
今材日料;
Chemical & Engineering News;
SEAS (School of Engineering and Applied Science) Soft Matter Wiki of Harvard University;
Poster for “New Concept in Microfluidics: Theory and Application (April 20, 2007, Harvard)”;
Poster (background image) for “32nd New England Complex Fluids Meeting (September 28, 2007, University of Connecticut)”;
“Complex Fluids” T-Shirt (image on the back) for “32nd New England Complex Fluids Meeting (September 28, 2007, University of Connecticut)”;
Flyer (optical micrographs for New England States fill) for “33rd New England Complex Fluids Meeting” (Harvard University, November 30, 2007);
Flyer (optical micrographs for New England States fill) for “37th New England Complex Fluids Meeting” (Harvard University, December 5, 2008);
Flyer (optical micrographs for New England States fill) for “49th New England Complex Fluids Meeting” (Harvard University, December 2, 2011);
Flyer (optical micrographs for New England States fill) for “53th New England Complex Fluids Meeting” (Harvard University, November 30, 2012); and
Flyer (optical micrographs for New England States fill) for “61st New England Complex Fluids Meeting” (Harvard University, December 5, 2014)
[9] Chu L.Y., Li Y., Zhu J.H., Chen W.M., 2005. Negatively thermoresponsive membranes with functional gates driven by zipper-type hydrogen-bonding interactions. Angewandte Chemie International Edition, 44(14): 2124-2127.(2014 Impact Factor = 11.261)
[10] Shah R.K., Shum H.C., Rowat A.C., Lee D., Agresti J.J., Utada A.S., Chu L.Y., Kim J.W., Fernandez-Nieves A., Martinez C.J., Weitz D.A., 2008. Designer emulsions using microfluidics. Materials Today, 11(4): 18-27.(2014 Impact Factor = 14.107)
Cover Story;
Invited Review;
Ranked No.11 in Top 25 Hottest Articles during 04/2008-06/2008
[11] Yao C., Liu Z., Yang C., Wang W., Ju X.J., Xie R., Chu L.Y., 2015. Poly(N-isopropylacrylamide)-clay nanocomposite hydrogels with responsive bending property as temperature-controlled manipulators. Advanced Functional Materials, 25(20): 2980-2991.(2014 Impact Factor = 11.805)
This work has been featured in the Back Cover
[12] Wei J., Ju X.J., Zou X.Y., Xie R., Wang W.,Liu Y.M., Chu L.Y., 2014. Multi-stimuli-responsive microcapsules for adjustable controlled-release. Advanced Functional Materials, 24(22): 3312-3323.(2014 Impact Factor = 11.805)
This work has been featured in the Inside Front Cover
[13] Liu Z., Luo F., Ju X.J., Xie R., Luo T., Sun Y.M., Chu L.Y., 2012. Positively K-responsive membranes with functional gates driven by host-guest molecular recognition. Advanced Functional Materials, 22(22): 4742-4750.(2014 Impact Factor = 11.805)
This work has been featured in theFrontispiece
[14] Yang M., Chu L.Y., Wang H.D., Xie R., Song H., Niu C.H., 2008. A thermo-responsive membrane for chiral resolution. Advanced Functional Materials, 18(4): 652-663.(2014 Impact Factor = 11.805)
[15] Chu L.Y., Kim J.W., Shah R.K., Weitz D.A., 2007. Monodisperse thermo-responsive microgels with tunable volume-phase transition kinetics. Advanced Functional Materials, 17(17): 3499-3504.(2014 Impact Factor = 11.805)
This work has been featured in the Front Cover
[16] Qu J.B., Chu L.Y., Yang M., Xie R., Hu L., Chen W.M., 2006. A pH-responsive gating membrane system with pumping effects for improved controlled-release. Advanced Functional Materials, 16(14): 1865-1872.(2014 Impact Factor = 11.805)
This work has been featured in the Front Cover; and
High-Tech Materials Alert
[17] Xiao X.C., Chu L.Y., Chen W.M., Wang S., Li Y., 2003. Positively thermo-sensitive monodisperse core-shell microspheres. Advanced Functional Materials, 13(11): 847-852.(2014 Impact Factor = 11.805)
This work was featured in the Front Cover
[18] Lin S., Wang W., Ju X.J., Xie R., Liu Z., Yu H.R., Zhang C., Chu L.Y., 2016. Ultrasensitive microchip based on smart microgel for real-time on-line detection of trace threat analytes. Proceedings of the National Academy of Sciences of the United States of America (PNAS), 113(8): 2023-2028.(2014 Impact Factor = 9.674)
[19] Chu L.Y., Li Y., Zhu J.H., Wang H.D., Liang Y.J., 2004. Control of pore size and permeability of a glucose-responsive gating membrane for insulin delivery. Journal of Controlled Release, 97(1): 43-53.(2014 Impact Factor = 7.705)
[20] Liu Z., Luo F., Ju X.J., Xie R., Sun Y.M., Wang W., Chu L.Y., 2013. Gating membranes for water treatment: Detection and removal of trace Pb ions based on molecular recognition and polymer phase transition. Journal of Materials Chemistry A, 1(34): 9659-9671.(2014 Impact Factor = 7.443)
This work has been featured as Inside Front Cover Story
[21] Liu Z., Liu L., Ju X.J., Xie R., Zhang B., Chu L.Y., 2011. K-recognition capsules with squirting release mechanisms. Chemical Communications, 47(45): 12283-12285.(2014 Impact Factor = 6.834)
This work has been featured in Back Cover;
Chemistry World;
Nano News Net; and
ChemRar
[22] Zhao H., He S.L., Yang M.L., Guo X.R., Xin G., Zhang C.Y., Ye L., Chu L.Y., Xing Z.H., Huang W., Chen Q.M., He Y., 2013. Micro-flowers changing to nano-bundle aggregates by translocation of the sugar moiety in Janus TA nucleosides. Chemical Communications, 49(36): 3742-3744.(2014 Impact Factor = 6.834)
[23] Yang X.L., Ju X.J., Mu X.T., Wang W., Xie R., Liu Z., Chu L.Y., 2016. Core-shell chitosan microcapsules for programmed sequential drug release. ACS Applied Materials & Interfaces, in press.(2014 Impact Factor = 6.723)
[24] He F., Wang W., He X.H., Yang X.L., Li M., Xie R., Ju X.J., Liu Z., Chu L.Y., 2016. Controllable multi-compartmental capsules with distinct cores and shells for synergistic release. ACS Applied Materials & Interfaces, in press.(2014 Impact Factor = 6.723)
[25] Shi K., Liu Z., Wei Y.Y., Wang W., Ju X.J., Xie R., Chu L.Y., 2015, Near-infrared light-responsive poly(N-isopropylacrylamide)/graphene oxide nanocomposite hydrogels with ultrahigh tensibility. ACS Applied Materials & Interfaces, 7(49): 27289-27298.(2014 Impact Factor = 6.723)
[26] He X.H., Wang W., Liu Y.M., Jiang M.., Wu F., Deng K., Liu Z., Ju X.J., Xie R., Chu L.Y., 2015. Microfluidic fabrication of bio-inspired microfibers with controllable magnetic spindle-knots for 3D assembly and water collection. ACS Applied Materials & Interfaces, 7(31): 17471-17481.(2014 Impact Factor = 6.723)
[27] Zhang M.J., Wang W., Yang X.L., Ma B., Liu Y.M., Xie R., Ju X.J., Liu Z., Chu L.Y., 2015. Uniform microparticles with controllable highly-interconnected hierarchical porous structures. ACS Applied Materials & Interfaces, 7(25): 13758-13767.(2014 Impact Factor = 6.723)
This work has been featured as the Cover Story
[28] Jiang M.Y., Ju X.J., Fang L., Liu Z., Yu H.R., Jiang L., Wang W., Xie R., Chen Q.M., Chu L.Y., 2014. A novel smart microsphere with K-induced shrinking and aggregating property based on responsive host-guest system.ACS Applied Materials & Interfaces, 6(21): 19405-19415.(2014 Impact Factor = 6.723)
[29] Liu Y.M., Ju X.J., Xin Y., Zheng W.C., Wang W., Wei J., Xie R., Liu Z., Chu L.Y., 2014. A novel smart microsphere with magnetic core and ion-recognizable shell for Pb adsorption and separation.ACS Applied Materials & Interfaces, 6(12): 9530-9542.(2014 Impact Factor = 6.723)
[30] Mei L., He F., Zhou R.Q., Wu C.D., Liang R., Xie R., Ju X.J., Wang W., Chu L.Y., 2014. A novel intestinal-targeted Ca-alginate-based carrier for pH-responsive protection and release of Lactic acid bacteria.ACS Applied Materials & Interfaces, 6(8): 5962-5970.(2014 Impact Factor = 6.723)
[31] Deng N.N., Sun J., Wang W., Ju X.J., Xie R., Chu L.Y., 2014. Wetting-induced coalescence of nanoliter drops as microreactors in microfluidics.ACS Applied Materials & Interfaces, 6(6): 3817-3821.(2014 Impact Factor = 6.723)
[32] Liu Y.M., Wang W., Zheng W.C., Ju X.J., Xie R., Zerrouki D., Deng N.N., Chu L.Y., 2013. Hydrogel-based micro-actuators with remote-controlled locomotion and fast Pb-response for micromanipulation.ACS Applied Materials & Interfaces, 5(15): 7219-7226.(2014 Impact Factor = 6.723)
[33] Meng Z.J., Wang W., Liang X., Zheng W. C., Deng N.N., Xie R., Ju X.J., Liu Z., Chu L.Y., 2015. Plug-n-play microfluidic systems from flexible assembly of glass-based flow-control modules. Lab on a Chip, 15(8): 1869-1878..(2014 Impact Factor = 6.115)
[34] Sun Y.M., Wang W., Wei Y.Y., Deng N.N., Liu Z., Ju X.J., Xie R., Chu L.Y., 2014. In situ fabrication of temperature- and ethanol-responsive smart membrane in microchip.Lab on a Chip, 14(14): 2418-2427.(2014 Impact Factor = 6.115)
This paper has been featured as “HOT Article” in Lab on a Chip Blog
[35] Lin S., Wang W., Ju X.J., Xie R., Chu L.Y., 2014. A simple strategy for in situ fabrication of smart hydrogel microvalve within microchannels for thermostatic control. Lab on a Chip, 14(15): 2626-2634.(2014 Impact Factor = 6.115)
This paper has been featured in Inside Front Cover; and as
“HOT Article” in Lab on a Chip Blog
[36] Deng N.N., Wang W., Ju X.J., Xie R., Weitz D.A., Chu L.Y., 2013. Wetting-induced formation of controllable monodisperse multiple emulsions in microfluidics. Lab on a Chip, 13(20): 4047-4052.(2014 Impact Factor = 6.115)
This work has been featured in Back Cover
[37] Deng N.N., Sun S.X., Wang W., Ju X.J., Xie R., Chu L.Y., 2013. A novel surgery-like strategy for droplet coalescence in microchannels. Lab on a Chip, 13(18): 3653-3657.(2014 Impact Factor = 6.115)
[38] Wang W., Xie R., Ju X.J., Luo T., Liu L., Weitz D.A., Chu L.Y., 2011. Controllable microfluidic production of multicomponent multiple emulsions. Lab on a Chip, 11(9): 1587-1592.(2014 Impact Factor = 6.115)
This work has been featured in Back Cover;
Chemistry World;
Micronews;
Lab on a Chip Blog;
Chemistry in Our Life;
I-Micronews; and
Most Read Articles in May 2011.
[39] Deng N.N., Meng Z.J., Xie R., Ju X.J., Mou C.L., Wang W., Chu L.Y., 2011. Simple and cheap microfluidic devices for preparation of monodisperse emulsions. Lab on a Chip, 11(23): 3963-3969.(2014 Impact Factor = 6.115)
This work has been featured in Back Cover; and
Lab on a Chip Blog
[40] Wahrmund J., Kim J.W., Chu L.Y., Wang C., Li Y., Fernandez-Nieves A., Weitz D.A., Krokhin A., Hu Z., 2009. Swelling kinetics of a microgel shell. Macromolecules, 42(23): 9357-9365.(2014 Impact Factor = 5.800)
[41] Utada A.S., Chu L.Y., Fernandez-Nieves A., Link D.R., Holtze C., Weitz D.A., 2007. Dripping, jetting, drops and wetting: The magic of microfluidics. MRS Bulletin, 32(9): 702-708.(2014 Impact Factor = 5.667)
“Technical Features” article;
This work was featured in the Front Cover
[42] Yu H.R., Ju X.J., Xie R., Wang W., Zhang B., Chu L.Y., 2013. Portable diagnosis method of hyperkalemia using potassium-recognizable poly(N-isopropylacrylamide-co-benzo-15-crown-5-acrylamide) copolymers. Analytical Chemistry, 85(13): 6477-6484. (2014 Impact Factor = 5.636)
.
汪伟研科项目
l 主持项目
[1] 国家自然科学基金面上目项“惠斯通桥型微流控抗原检测片芯的构建及其微流体流动特性研究”(21576167),2016—2019,项目负责人;
[2] 国家自然科学金基项目“仿金毛狗蕨茸毛微结构壳的聚糖超细纤维膜的制备与性能究研”(21306117),2014—2016,项目负责人;
[3] 教育部高等校学博士学科点专项科研基金新教基师金项目“微型竹状结构超细纤的维微流控制备及其性能研究”(20130181120063),2014—2016,项目负责人;
[4] 四川大优学秀青年学者科研基金项目“微控流法构建结构可控的微尺度高分功子能材料”(2014SCU04A03),2014—2016,项目负责人;
[5] 广东省功能软凝聚态物质重点验实室开放课题基金项目(201501),2015—2016,目项负责人;
[6] 四川大学青年教师科研启动基金目项(2012SCU11073),2012—2013,项目负人责;
l 主研项目
[7] 国家自然科学金基重点项目“多相微分散体系流与动传递性能的基础研究”(20136002)子课题,2011—2014,子课题第一主研
[8] 国家杰出青年科基学金项目“环境响应型智能膜材创料新与膜过程强化基础研究”(20825622),2009—2012,第三主研
[9] 全国优秀博士学位论文作专者项资金资助项目“微流控构建尺微度乳液相界面及制备新型微球囊微材料的基础研究”(201163),2011—2015,第主四研
[10] 国自家然科学基金项目“环境响应型洛特伊木马式微囊膜可控制备与控传释质机理”(21076127),2011—2013,第四主研
[11] 国家自科然学基金项目“固载温敏性微球智的能复合膜的制备与亲和分离性研能究”(20806049),2009—2011,主研
[12] 教育部高等学校士博学科点专项科研基金新教师基项金目“新型温敏亲和分离智能复膜合的研究”(200806101045),2009—2011,主研
[13] 国重家点基础研究发展计划(973划计)课题“智能膜材料设计与制科备学研究”(2009CB623407),2009—2013,主研
[14] 国自家然科学基金重点项目“微流控建构微尺度相界面及制备新型功能料材的基础研究(21136006),2012—2016,主研
[15] 教育部“江长学者和创新团队发展计划”创团新队资助项目“生物医用高分子能功材料”(IRT1163),2012—2014,主研
汪伟专利
1) 夏烈文, 褚良银, 晓巨洁, 谢锐, 汪伟. “高子分微凝胶复合结构的高强度水凝制胶备方法”. 中国发明专利申专请利申请日2012.5.7.
2) 汪伟, 褚良银, 谢锐, 巨晓洁, 罗涛, 刘丽. “制备单分散多组分多乳重液的微流控方法及装置”. 国中发明专利申请X, 专利申请日2011.3.20.
3) 刘丽, 褚良银, 杨平建, 汪伟, 巨晓洁, 谢锐. “具有pH突释特性的壳聚糖空中和核壳微囊的制备方法”. 国中发明专利申请, 专利申请日2011.2.24.
4) 汪伟, 褚良银, 刘丽, 巨晓洁, 谢锐. “热引发爆自式磁靶向微囊及其制备方法”. 中国发明专利专利申请日2009.7.13, 专利授权日2011. 7.1.
考参资料1. 汪伟博士 .四川大学化工学院“膜科学与功材能料研究室”[引用日期2012-10-19]2. 汪伟博士 个人简历 .四川大学[引用日期2016-04-09]3. SCI收录论文 .四川大学[引用日期2016-04-09]4. 汪伟博士 主持承担科研项目: .四川大学[引用日期2016-04-09]
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