陈相仲

青年研究员

通信地址:上海市淞沪路2005号复旦大学江湾校区交叉一号楼;邮编:200438

电子xzchen@fudan.edu.cn

更多信息请访问个人网站:https://faculty.fudan.edu.cn/xzchen/zh_CN/zhym/676121/list/index.htm  


教育和工作经历:

20233月至今:复旦大学光电研究院,青年研究员

201911-202302月:瑞士联邦理工学院(苏黎世),高级研究员

201311-201910月:瑞士联邦理工学院(苏黎世),博士后,合作导师:Bradley NelsonSalvador Pané

201307-201310月:南京大学, 研究助理

201110-201304月:美国宾夕法尼亚州立大学,访问学生,导师:Qiming Zhang

200709-201306月:南京大学, 化学, 理学博士,导师:沈群东教授

200309-200706月:南京林业大学, 高分子材料与工程, 工学学士

  

研究兴趣与领域:

1. 铁电压电材料

2. 磁性纳米材料

3. 铁性材料的生物医学应用

4.基于铁性材料的新型医用器械与器件(如微机器人、传感器与执行器、软机器人等)

欢迎材料、物理、化学、药学、化工、生医、机械、电子等相关专业背景的博士加盟本课题组进行博士后合作研究;欢迎相关专业背景的学生报考本课题组硕士或博士研究生。(长期有效)


获资助的科研项目:

上海市海外高层次引进人才(2021

  

瑞士国家科学基金会,Project Funding69万瑞法,约合520万人民币),2023,共同主持(已退出)

瑞士国家科学基金会,Sino-Swiss 合作项目(35万瑞法,约合240万人民币), 2022,共同主持(已退出)

瑞士国家科学基金会,SPARK项目(10万瑞法,约合70万人民币), 2020,主持(已结题)

瑞士联邦理工学院,职业生涯种子基金(5万瑞法,约合35万人民币), 2016,主持(已结题)

  

近年代表性成果:

围绕着多场耦合材料(主要是磁--电)的生物学效应及其在新型医疗器件(如微机器人)中的应用展开研究工作,迄今在Nat. Commun.Adv. Mater.Angew. Chem. Int. Ed.等知名期刊共发SCI论文80余篇其中以第一或通讯作者发表SCI论文30余篇。研究成果他引4500余次H指数38。受邀担任国际会议分会主席7次、国际、国内会议邀请报告十余次。担任ScienceNat. Commun.Adv. Mater.Chem. Rev.50余种期刊审稿人。

  

[1] Ye, H.; Wang, K.; Zhao, J.; Lu, Q.; Wang, M.; Sun, B.; Shen, Y.; Liu, H. *; Chen, X. Z.*; Pané, S.; He, Z.*; Sun, J. *; In situ sprayed nanovaccine suppressing exosomal PD-L1 by Golgi apparatus destruction for post-surgical melanoma immunotherapy, ACSNano, Accepted, DOI: 10.1021/acsnano.3c01733

[2] Llacer-Wintle, J.;  Renz, J.;  Hertle, L.;  Veciana, A.;  Arx, D. v.;  Wu, J.;  Vukomanovic, M.;  Puigmartí-Luis, J.;  Nelson, B. J.;  Chen, X. Z.*; Pané, S.*, The magnetopyroelectric effect: Heat-mediated magnetoelectricity in magnetic nanoparticle-ferroelectric polymer composites. Materials Horizons 2023, Accepted. DOI: 10.1039/d2mh01361d.

[3] Kim, D.;  Kim, M.;  Reidt, S.;  Han, H.;  Baghizadeh, A.; Zeng, P.; Choi, H.;  Puigmartí-Luis, J.;  Trassin, M.;  Nelson, B. J.;  Chen, X. Z.*; Pané, S.*, Shape-memory effect in twisted ferroic nanocomposites. Nature Communications 2023, 14, 750.

[4] Sanchis‐Gual, R.;  Ye, H.;  Ueno, T.;  Landers, F. C.;  Hertle, L.;  Deng, S.;  Veciana, A.;  Xia, Y.;  Franco, C.;  Choi, H.;  Puigmartí‐Luis, J.;  Nelson, B. J.;  Chen, X. Z.*; Pané, S.*, 3D Printed Template‐Assisted Casting of Biocompatible Polyvinyl Alcohol‐Based Soft Microswimmers with Tunable Stability. Advanced Functional Materials 2023, 2212952.

[5] Kim, D.; Efe, I.; Torlakcik, H.; Terzopoulou, A.; Picazo, A. V.; Siringil, E.; Mushtaq, F.; Franco, C.; von Arx, D.; Sevim, S.; Puigmartí-Luis, J.; Nelson, B.; Spaldin, N. A.; Gattinoni, C.*; Chen, X.-Z.*; Pané, S.*, Magnetoelectric effect in hydrogen harvesting: magnetic field as a trigger of catalytic reactions. Advanced Materials 2022, 2110612.

[6] Llacer Wintle, J.; Rivas-Dapena, A.; Chen, X. Z.*; Pellicer, E.; Nelson, B.; Puigmartí-Luis, J.; Pané, S.; Biodegradable Small-Scale Swimmers for Biomedical Applications. Advanced Materials 2021, 2102049.

[7] Gervasoni, S.; Terzopoulou, A.; Franco, C.; Veciana, A.; Pedrini, N.; Burri, J.; de Marco, C.; Siringil, E. C.; Chen, X. Z.*; Nelson, B. J.;  Puigmartí-Luis, J.; S. Pané., CANDYBOTS: A New Generation of 3D-Printed Sugar-based Transient Small-Scale Robots. Advanced Materials,2020, 32 (52), e2005652.

[8] Dong, M.; Wang, X.; Chen, X. Z.*; Mushtaq, F.; Deng, S.; Zhu, C.; Torlakcik, H.; Terzopoulou, A.; Qin, X.-H.; Xiao, X.; Puigmarti-Luis, J.; Choi, H.; Pêgo A. P.; Shen, Q.-D.*; Nelson, B. J.; Pané, S.*, 3D-printed Biodegradable Soft Magnetoelectric Microswimmers for Delivery and Differentiation of Neuron-like Cells. Advanced Functional Materials,2020, 1910323.

[9] Terzopoulou, A.; Hoop, M.; Chen, X. Z.*; Hirt, A. M.; Charilaou, M.; Shen, Y.; Mushtaq, F.; Pérez del Pino, A.; Logofatu, C.; Simonelli, L.; deMello, A. J.; Doonan, C. J.; Sort. J., Nelson, B. J.; Pané, S.*; Puigmartí-Luis, J.*, Mineralization-inspired synthesis of magnetic zeolitic imidazole frameworks. Angewandte Chemie International Edition, 2019, 58, 13550-13555.

[10] Mushtaq, F.; Chen, X. Z.*; Torlakcik, H.; Steuer, C.; Hoop, M.; Siringil, E. C.; Marti, X.; Limburg, G.; Stipp, P.; Nelson, B. J.; Pané, S.*, Magnetoelectrically driven catalytic degradation of organics. Advanced Materials, 2019, 31, 1901378.

[11] Mushtaq, F.; Torlakcik, H.; Hoop, M.; Jang, B.; Carlson, F.; Grunow, T.; Läubli, N.; Ferreira, A.; Chen, X. Z.*; Nelson, B. J.; Pané, S., Motile Piezoelectric Nanoeels for Targeted Drug Delivery. Advanced Functional Materials, 2019, 29, 1808135.

[12] Chen, X. Z.; Hoop, M.; Shamsudhin, N.; Huang, T.; Özkale, B.; Li, Q.; Siringil, E.; Mushtaq, F.; Tizio, L. D.; Nelson, B. J.; Pané, S., Hybrid magnetoelectric nanowires for nanorobotic applications: fabrication, magnetoelectric coupling and magnetically-assisted targeted drug delivery.Advanced Materials 2017, 29, 1605458

[13] Chen, X. Z.; Shamsudhin, N.; Hoop, M.; Pieters, R.; Siringil, E.; Sakar, M. S.; Nelson, B. J.; Pané, S., Magnetoelectric micromachines with wirelessly controlled navigation and functionality. Materials Horizons, 2016, 3 (2), 113-118.

[14] Mushtaq, F.; Asani, A.; Hoop, M.; Chen, X. Z.*; Ahmed D., Nelson, B. J.; Pané, S.*, Highly efficient coaxial tio2-ptpd tubular nanomachines for photocatalytic water purification with multiple locomotion strategies. Advanced Functional Materials, 2016, 26 (38), 6995-7002.

[15] Hoop, M.; Shen, Y.; Chen, X. Z.*; Mushtaq, F.; Sakar, M. S.; Petruska, A.; Loessner, M. J.; Nelson, B. J.; Pané, S.*, Magnetically driven silver-coated helical nanorobots for efficient bacterial contact killing. Advanced Functional Materials, 2016, 26 (7), 1063-1069.