于淑会 教授
教育背景: 博士
研究领域: 材料物理
研究方向: 功能电介质材料、集成电路材料
电子邮箱: yush105709@gzhu.edu.cn
所在系所: 材料科学与工程系
▍个人简介
2006年毕业于新加坡国立大学,获得哲学博士学位,专业方向为电介质薄膜与元器件。2006年2月至2007年6月在香港理工大学从事介电陶瓷材料研究,2007年6月至2025年6月在中国科学院深圳先进技术研究院从事电子封装材料的研究和开发工作,入选深圳市引进海外高层次人才孔雀计划B类。于2025年7月通过广州大学百人计划加入物理与材料科学学院。主要从事聚合物基纳米复合材料的电学、热学和力学性能调控,及其在电子封装领域的应用研究。主持和参与多项国家自然科学基金、科技部重大专项/重点研发计划等课题。发表学术论文200余篇,其中Sci收录逾100篇,包括Energy Environ. Sci.,Adv. Energy Mater., Adv. Funct. Mater.,《中国科学》等,他引逾6400次,多篇入选高被引论文,H影响因子41;受邀参与编写专著4部。获得广东省科技进步一等奖、深圳市科技进步一等奖、电子元器件专委会产学研合作奖等奖项。
▍担任主要课程
本科生课程:大学物理
研究生课程:材料分析方法原理
▍代表性课题
1.“5G通信用高频低介电低损耗本征型聚酰亚胺的设计合成及其构效关系研究”, 国家自然科学基金-广东省联合基金重点项目, 2021-2024,合作单位课题负责人。
2.“智能自修复纳米复合材料的构建及其自愈合与介电储能行为研究”,国家自然科学基金面上项目,2018-2021,主持。
3.“钛酸钡负载纳米银微粒填充的聚合物基复合材料介电性能研究”, 国家自然科学基金面上项目,2014-2017,主持。
4.“可反应性Ag@SiO2纳米粒子填充的聚合物基复合材料微观结构与介电性能研究”, 国家自然科学基金青年基金,2010-2012,主持。
5.“用于毫米波器件的低损耗低温共烧陶瓷介质材料应用研究”,科技部重点研发计划(2020YFB0408800),2020-2022,合作单位课题负责人。
6. “三维高密度基板及高性能 CPU 封装技术研发与产业化”, 国家科技部02重大专项,200.0万元,2011-2013,子任务“高散热基板技术”负责人。
7. “高性能电磁介质及元器件开发-课题3-无源集成关键材料、工艺及器件开发”, 科技部重点研发计划,2017-2021,子任务负责人。
▍近期论文
1.Luo S, Yu J, Ma P, Yu S*, et al. Strong Adhesion of Electroless Plated Copper by Optimizing Lamination Temperature of Epoxy Composite F
m for Advanced Chip Packaging Substrates[J]. Advanced Engineering Materials, 2024, 26(16): 2400736.
2.Hussain A, Liu J, Zhao C, Yu S*, et al. Low voltage tunability of PVDF-based nanocomposites by interface polarization induced by TiO2-coat
ed BST core-shell nanoparticle[J]. Composites Communications, 2024, 49: 101984.
3.Liu J, Ji L, Yu J, Yu S*, et al. Enhanced breakdown strength and electrostatic energy density of polymer nanocomposite films realized by heter
ostructure ZnO-ZnS nanoparticles[J]. Chemical Engineering Journal, 2023, 456: 140950.
4.Li P, Luo S, Yu S*, et al. Cu deposition technologies for build-up film substrates towards FC-BGA. Sci Sin Chim, 2023, 53(10), 1866-187
9. 中国科学:化学。
5.Li T, Li P, Yu S*, et al. Polymer‐based nanocomposites in semiconductor packaging[J]. IET Nanodielectrics, 2023, 6(3): 147-158.
6.Yu J, Wang L, Liang Z, Yu S*, et al. Elaborately designed polymer dielectric films with low coefficient of thermal expansion demonstrating hi
gh and stable electrostatic energy density over a wide temperature range[J]. Materials Today Energy, 2022, 30: 101177.
7.Min Y, Yu J, Xu P, Yu S*, et al. Polyimide films impregnated with epoxy resin demonstrating superior self-healing properties for thermally sta
ble energy storage capacitors[J]. ACS Applied Materials & Interfaces, 2022, 14(45): 51265-51274.
8.Ye J, Zheng C, Liu J, Yu S*, et al. In situ grown tungsten trioxide nanoparticles on graphene oxide nanosheet to regulate ion selectivity of me
mbrane for high performance vanadium redox flow battery[J]. Advanced Functional Materials, 2022, 32(8): 2109427.
9.Luo S, Ansari T Q, Yu J, Yu S*, et al. Enhancement of dielectric breakdown strength and energy storage of all-polymer films by surface flatten
ing[J]. Chemical Engineering Journal, 2021, 412: 128476.
10.Yu J, Ding S, Yu S*, et al. Nanoparticles with rationally designed isoelectronic traps as fillers significantly enhance breakdown strength and e
lectrostatic energy density of polymer composites[J]. Composites Science and Technology, 2020, 195: 108201.
11.Liang X, Yu X, Yu S*, Lv L, et al. BaTiO3 internally decorated hollow porous carbon hybrids as fillers enhancing dielectric and energy storag
e performance of sandwich-structured polymer composite[J]. Nano Energy, 2020, 68: 104351.
12.Luo S, Yu J, Ansari T Q, Yu S*, et al. Elaborately fabricated polytetrafluoroethylene film exhibiting superior high-temperature energy storag
e performance[J]. Applied Materials Today, 2020, 21: 100882.
13.Liu J, Zhang Y, Yu S*, et al. Optimizing electric field distribution via tuning cross-linked point size for improving the dielectric properties of
polymer nanocomposites[J]. Nanoscale, 2020, 12, 12416–12425. 5.8/Q1
14.李鸿韬,于淑会*,等. 重复单元结构对聚酰亚胺薄膜力学和介电性能的影响[J]. 绝缘材料, 2020, 53(7): 23-28.
15.Lu Y C, Yu J, Huang J, Yu S*, et al. Enhanced electrocaloric effect for refrigeration in lead-free polymer composite films with an optimal fille
r loading[J]. Applied Physics Letters, 2019, 114(23). 3.5/Q2
16.Luo S, Yu J, Yu S*, et al. Significantly enhanced electrostatic energy storage performance of flexible polymer composites by introducing high
ly insulating‐ferroelectric microhybrids as fillers[J]. Advanced Energy Materials, 2019, 9(5): 1803204.
17.Wei M, Wu X, Yao Y, Yu S*, et al. Toward High Micro-Supercapacitive Performance by Constructing Graphene-Supported NiMoS4 Hybrid
Materials on 3D Current Collectors, ACS Sustainable Chemistry & Engineering, 2019, 7, 24, 19779-19786.
18.Wei M, Wang C, Yu S*, Yao Y, et al. Toward high-performance all-solid-state supercapacitors using facilely fabricated graphite nanosheet-su
pported CoMoS4 as electrode material[J]. Chemical Engineering Journal, 2019, 355: 891-900.
19.Xu P, Luo S, Yu S*, et al. Simultaneously enhanced permittivity and electric breakdown strength of polyacrylonitrile composites by introduci
ng ultralow content BaSrTiO3 nanofibers[J]. Advanced Engineering Materials, 2019, 21(12): 1900817. 4.1/Q2
20.Wang C, Guan Z, Yu S*, Shen Y, et al. Shape-controlled synthesis of CoMoO4@ Co1.5Ni1.5S4 hybrids with rambutan-like structure for high-
performance all-solid-state supercapacitors[J]. Chemical Engineering Journal, 2018, 346: 193-202. IF13.3/Q1.
21.Lu Y, Yu S*, Zeng X, et al. High energy density polymer nanocomposites with Y‐doped barium strontium titanate nanoparticles as fillers[J]. I
ET Nanodielectrics, 2018, 1(4): 137-142. 3.8/Q3
22.Zhang Z, Luo S, Yu S*, et al. Significantly enhanced dielectric and energy storage performance of blend polymer-based composites containin
g inorganic 3D–network[J]. Materials & Design, 2018, 142: 106-113. 7.6/Q1
23.Luo S, Shen Y, Yu S*, et al. Construction of a 3D-BaTiO3 network leading to significantly enhanced dielectric permittivity and energy storag
e density of polymer composites[J]. Energy & Environmental Science, 2017, 10(1): 137-144.
24.Ding S, Yu S*, Zhu X, et al. Enhanced breakdown strength of polymer composites by low filler loading and its mechanisms[J]. Applied Phys
ics Letters, 2017, 111(15).
25.Yang W, Wang J, Luo S, Yu S*, et al. ZnO-decorated carbon nanotube hybrids as fillers leading to reversible nonlinear I–V behavior of polym
er composites for device protection[J]. ACS Applied Materials & Interfaces, 2016, 8(51): 35545-35551.
26.Yang W, Wang J, Yu S*, et al. ZnO-decorated carbon nanotube hybrids as fillers leading to reversible nonlinear I–V behavior of polymer com
posites for device protection[J]. ACS Applied Materials & Interfaces, 2016, 8(51): 35545-35551. 8.3/Q1
▍社会服务
参与成立介电高分子复合材料专委会并任常务副主任委员;
参与创办IET Nanodielectrics并任编委;
兼任电子元器件关键材料与技术专业委员会常务委员。
