史志成

发布时间:2021-10-05信息来源:材料科学与工程学院浏览次数:8528



史志成,男,博士,教授,硕/博士生导师

山东省泰山学者青年专家

山东省优秀青年基金获得者

山东省高等学校青创团队负责人

联系方式zcshi@ouc.edu.cn


教育与工作经历

2013.07-至今.    中国海洋大学    讲师、副教授、教授

2017.10-2018.10  佐治亚理工学院  访问学者(合作导师:Gleb Yushin教授)

2008.09-2013.06  山东大学        博士(导师:范润华教授)

2004.09-2008.07  青岛科技大学    材料科学与工程学院  学士


研究领域

长期从事电子信息功能材料研究,发表学术论文120余篇,其中以第一/通讯作者在Adv. Mater.、Mater. Today、Mater. Horiz.、Adv. Funct. Mater.等期刊发表论文60余篇,ESI高被引论文10余篇,论文被引5000余次,H指数42,撰写英文专著1章节,作为第一发明人授权国家发明专利7件。担任Nature Energy、Adv. Mater.、Mater. Horiz.、Adv. Funct. Mater.等学术期刊审稿人。


研究方向

1. 介电功能材料

2. 电磁超构材料

3. 电磁屏蔽材料


荣誉/奖励

教育部高等学校科学研究优秀成果二等奖(2023)

全球前2%顶尖科学家(2021、2022)

中国海洋大学优秀研究生学位论文指导教师(2022)

英国皇家化学学会TOP 1%高被引作者(2021)

中国海洋大学优秀教师(2020)

山东省自然科学二等奖(2018)

中国材料研究学会科学技术奖(2018)

山东省优秀博士学位论文(2014)

教育部博士生学术新人奖(2012)


学术兼职

中国复合材料学会介电高分子复合材料与应用专委会委员(2023)

Nano-Micro Letters (IF: 23.655)期刊青年编委(2023)

中国材料研究学会超材料分会青年理事(2018)

中国仪表功能材料学会电子元器件关键材料与技术专委会委员(2017)


主持科研项目

国家自然科学基金(51773187)

国家自然科学基金(51402271)

山东省自然科学基金(ZR2021YQ39)

山东省自然科学基金(BS2014CL003)

青岛市应用基础研究计划项目(14-2-4-118-jch)

中国海洋大学优秀青年科技人才培育项目(202241004)


授权发明专利

1. 史志成,夏水苗,杜厚猛,李鑫帅一种协同提升聚合物电介质击穿强度和介电常数的方法,专利号:ZL202210034372.0,授权时间:2023-02-16

2. 史志成,张文强,殷鹏,孙良一种钛酸钡/聚醚酰亚胺介电复合材料及其制备方法,专利号:ZL202011152571.9授权时间: 2021-12-28

3. 史志成,孙良,张文强,殷鹏.一种非对称三层结构全聚合物介电复合材料及其制备方法,专利号:ZL202011476097.5.,授权时间:2021-09-28

4史志成,朱晓彤,杨洁,左衡基于核壳结构三维骨架的聚合物基高介电复合材料的制备方法专利号:ZL201910057398.5,授权时间: 2020-03-06

5. 史志成,王婧,毛凡具有叠层结构的高介电、低损耗复合材料的制备方法,专利号:ZL201610596950.4,授权时间:2018-09-28

6. 史志成,王婧,毛凡一种高介电复合材料的低温制备方法,专利号:ZL201510818328.9,授权时间:2017-11-14

7. 史志成,杨玉洁,唐清杨,别晓涵. 一种基于金/玻璃纤维布的聚偏氟乙烯介电复合材料. 专利号:ZL202310258763.5,授权时间:2023-09-28


代表性学术论文*标注为通讯作者)

(1) Qifa He, Zhicheng Shi*, et al. Polymer dielectrics for capacitive energy storage: From theories, materials to industrial capacitors. Materials Today, 2023, 68, 298-333.

(2) Shuimiao Xia, Zhicheng Shi*, et al. Achieving remarkable energy storage enhancement in polymer dielectrics via constructing an ultrathin Coulomb blockade layer of gold nanoparticles. Materials Horizons, 2023, 10, 2476.

(3) Liang Sun, Zhicheng Shi*, et al. Asymmetric Trilayer All-Polymer Dielectric Composites with Simultaneous High Efficiency and High Energy Density: A Novel Design Targeting Advanced Energy Storage Capacitors. Advanced Functional Materials, 2021, 31, 2100280.

(4) Zhicheng Shi, Runhua Fan*, et al. Random Composites of Nickel Networks Supported by Porous Alumina Toward Double Negative Materials. Advanced Materials, 2012, 24, 2349-2352.

(5) Zhicheng Shi, Runhua Fan*, et al. Preparation of Iron Networks Hosted in Porous Alumina with Tunable Negative Permittivity and Permeability. Advanced Functional Materials, 2013, 23, 4123-4132.

(6) Jing Wang, Zhicheng Shi*, et al. Bilayer Polymer Metacomposites Containing Negative Permittivity Layer for New High-k Materials. ACS Applied Materials & Interfaces, 2017, 9, 1793-1800.

(7) Chao Zhang, Zhicheng Shi*, et al. Flexible Polyimide Nanocomposites with dc Bias Induced Excellent Dielectric Tunability and Unique Nonpercolative Negative-k toward Intrinsic Metamaterials. ACS Applied Materials & Interfaces, 2018, 10(31), 26713-26722.

(8) Shengbiao Sun, Zhicheng Shi*, et al. Achieving Concurrent High Energy Density and Efficiency in All Polymer Layered Paraelectric/Ferroelectric Composites via Introducing a Moderate Layer. ACS Applied Materials & Interfaces, 2021, 13, 27522-27532.

(9) Liang Sun, Zhicheng Shi*, et al. Concurrently Achieving High Discharged Energy Density and Efficiency in Composites by Introducing Ultralow Loadings of Core-Shell Structured Graphene@ TiO2 Nanoboxes. ACS Applied Materials & Interfaces, 2022, 14(25), 29292-29301.

(10) Houmeng Du, Zhicheng Shi*, et al. Gold Sputtering at the Interfaces: An Easily Operated Strategy for Enhancing the Energy Storage Capability of Laminated Polymer Dielectrics. ACS Applied Materials & Interfaces, 2023, 15, 17103-17112.

(11) Liang Sun, Zhicheng Shi*, et al. Ultrahigh discharge efficiency and improved energy density in rationally designed bilayer polyetherimide-BaTiO3/P(VDF-HFP) composites. Journal of Materials Chemistry A, 2020, 8 (11), 5750-5757. 

(12) Zhicheng Shi*, et al. Significantly improved dielectric performances of sandwich-structured polymer composites induced by alternating positive-k and negative-k layers. Journal of Materials Chemistry A, 2017, 5 (28), 14575-14582. 

(13) Peitao Xie, Zhicheng Shi*, et al. Recent advances in radio‑frequency negative dielectric metamaterials by designing heterogeneous composites. Advanced Composites and Hybrid Materials, 2022, 5, 679–695.

(14) Fan Mao, Zhicheng Shi*, et al. Improved dielectric permittivity and retained low loss in layer-structured films via controlling interfaces. Advanced Composites and Hybrid Materials, 2018, 1(5), 548-557.

(15) Xiaotong Zhu, Zhicheng Shi*, et al. Fabrication of core-shell structured Ni@BaTiO3 scaffolds for polymer composites with ultrahigh dielectric constant and low loss. Composites Part A, 2019, 125,105521.

(16) Jie Yang, Zhicheng Shi*, et al. Achieving excellent dielectric performance in polymer composites with ultralow filler loadings via constructing hollow-structured filler frameworks. Composites Part A, 2020, 131, 105814.

(17) Mingli Han, Zhicheng Shi*, et al. Significantly enhanced high permittivity and negative permittivity in Ag/Al2O3/3D-BaTiO3/epoxy metacomposites with unique hierarchical heterogeneous microstructures. Composites Part A, 2021, 149, 106559.

(18) Xinshuai Li, Zhicheng Shi*, et al. All-polymeric multilayer para/ferroelectric dielectric films utilizing a gradient structure toward concurrent high discharge efficiency and energy density. Materials Today Energy, 2022, 29, 101119.

(19) Shuang Wei, Zhicheng Shi*, et al. Metal-organic framework derived hollow CoFe@C composites by the tunable chemical composition for efficient microwave absorption. Journal of Colloid and Interface Science, 2021, 593, 370–379.

(20) Shuang Wei, Zhicheng Shi*, et al. Preparation of CoFe@N-doped C/rGO composites derived from CoFe Prussian blue analogues for efficient microwave absorption. Journal of Colloid and Interface Science, 2022, 610, 395–406.



招生信息

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