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贺竞辉 教授

材料与化学化工学部

导航

  • 个人资料
  • 个人概况
  • 研究领域
  • 开授课程
  • 科研项目
  • 论文
  • 科技成果
  • 荣誉及奖励
  • 招生信息

个人资料

  • 直属机构:材料与化学化工学部
  • 联系电话:
  • 性别:
  • 电子邮箱:jinghhe@suda.edu.cn
  • 专业技术职务:
  • 办公地址:苏州大学独墅湖校区一期701-B405
  • 毕业院校:新加坡国立大学
  • 通讯地址:苏州大学独墅湖校区一期701-B405
  • 学位:博士
  • 邮编:215123
  • 学历:博士研究生
  • 传真:

教育经历

教育经历:
  • 2001-2005,南京大学化学化工学院,学士学位
  • 2005-2008,南京大学化学化工学院,硕士学位
  • 2008-2013,新加坡国立大学化学系,博士学位

工作经历

工作经历:
  • 2013-2014,新加坡国立大学化学系,博士后
  • 2014-2019,苏州大学材化部,特聘副教授,硕士生导师
  • 2019-至今,苏州大学材化部,教授,博导

个人简历

个人简介:

个人简历

   名:贺竞辉           出生年月:198210

婚姻状况:已婚育           政治面貌:群众

   称:教授、博导
工作单位:苏州大学材料与化学化工学部应用化学系

联系方式:13405068939

Email: jinghhe@suda.edu.cn


教育与工作经历:

2001-2005     南京大学化学化工学院,获学士学位

2005-2008     南京大学化学化工学院,获硕士学位,导师:徐正

2018-2013     新加坡国立大学化学系,获博士学位,导师:许国勤院士

2013-2014     新加坡国立大学化学系,博士后

2014-2019     苏州大学材化部,特聘副教授、硕士生导师

2019-至今    苏州大学材化部,教授、博导

论文与专利

以第一或通讯作者身份在Nat. Commun. (1)Adv. Mater. (2)Angew. Chem.   Int. Ed. (2)Adv. Funct.   Mater. (1)Adv. Eng.   Mater.(1)Chem. Sci. (2)InfoMat (1)Mater. Horiz.   (1)Small (8) J. Mater. Chem.   A (3)ACS Sens.(3)等期刊等发表SCI论文50余篇。授权发明专利中国18项,美国5项。

项目

1.          基于离子共轭有机材料的通用气体传感模型的创建及器件开发,自然科学基金面上项目66万,在研、主持

2.          复杂组分VOCs传感材料与器件的应用基础研究,苏州市前瞻性应用研究项目10万,在研、主持

3.          传感器表界面工程实现水体持久性有机污染物高效检测,江苏省高校自然科学研究重大项目30万,完成,主持

4.          有机材料的多进制电存储机理研究与性能优化,自然科学基金青年项目25万,完成,主持

5.          基于宽带隙共轭有机材料的新型气体传感器研制,苏州市前瞻性应用研究项目10万,完成,主持

6.          铝铁分离材料的开发,横向,主持,30万。

学术任职

1.          InfoMat》期刊(影响因子:25.405),青年编委

2.          Chinese Chemistry Letters》期刊青年编委

3.          Coatings》期刊,栏目编委

奖励

2019  国家技术发明奖二等奖(排名4

2017  江苏省政府科学技术一等奖(排名5

2017  教育部自然科学一等奖(排名6

2016  江苏省双创博士

2017  苏州市紧缺人才

教学

主讲《无机化学实验》、《物理化学》、《材料表面科学基础》课程。

研究领域与特色

传统技术难以满足低浓度污染物高效检测和净化需求,低浓度污染物的传质效率、定向捕捉和转化是解决低浓度污染物高效检测和净化的关键科学问题。本课题组围绕水体和大气中低浓度环境污染物的高效精准检测与转化,提出了内建电场强化吸附环境功能材料的概念,即通过外电压诱导离子迁移、共轭骨架引入离子位点、二维表面限域离子注入三种策略,提出了离子共轭(ion-in-conjugation)材料的概念,使气体污染物检测下限改进为当时报道1/100,打破并长期保持3种气体检测国际纪录,实现硝酸根和二氧化碳的转化的催化剂活性均为目前报道最高,净化效果达商业铂碳75倍,提升污染物的检测和净化精准度和效率。

本课题组招生化学和材料研究生,也欢迎有交叉学科背景的学生加入本课题组。

研究领域

研究领域:






1. 离子共轭的定义,种类与应用及扩展。


有机共轭材料国内外研究多年,可靠性成为其走向应用的最大挑战。课题组在2016年比较有机共轭材料和传统无机离子材料的优缺点,深入思考分子间相互作用类型的科学问题后(图1a),提出了离子共轭(Ion-In-Conjugation)材料概念:即在基态时共轭骨架包含化学计量离子态的材料。

本人围绕该概念的定义、性质与应用开展了系列工作,以解决有机共轭材料的性能与可靠性的矛盾:1创制共振双离子、分子离子、d-π共轭配位、非本征鳌合配位四类离子共轭材料(图1b),从结构、性质上论证了离子共轭材料与教科书相关概念区别(图1c);2强化气体分子吸附能和电荷转移,使有机气体和湿度传感器兼顾灵敏度和环境稳定性,突破并保持多项气湿敏检测限报道最低记录(图1d3)提升活性层分子间作用力,有机忆阻、忆容信息存储器件良率达报道最高86%,抗高温、火焰、辐射的环境稳定性超越传统闪存(图1d)。

拟将该概念进一步进行种类、应用扩展,与催化、能源、医学等领域交叉,形成具有影响力的原创特色研究。

开授课程

开授课程:
  • 1、物理化学,2017.01.12-,26,72
课程教学:

科研项目

科研项目:
  • 1、有机材料的多进制电存储机理研究与性能优化,,2017-2019,2017,贺竞辉,国家自然科学基金委,青年项目,,苏州大学,物理化学,25万,21603158,纵向,1
  • 2、基于离子共轭有机材料的通用气体传感模型的创建及器件开发, ,2020-2023,2020,贺竞辉,国家自然科学基金委,面上项目,苏州大学,化工,66万,21978185,纵向,1
  • 3、“强化富集/催化降解”双功能一体化材料的创建及其对低浓度VOCs的深度治理研究,,2020-2023,2020,路建美,国家自然科学基金委,重点项目,苏州大学,功能材料,100万,21938006,纵向,5
  • 4、传感器表界面工程实现水体持久性有机污染物高效检测,2017-2020,2017,贺竞辉,江苏省教育厅,江苏省高校自然科学研究项目重大项目,苏州大学,环境检测,30万,17KJA150010,纵向,1
  • 5、复杂组分VOCs传感材料与器件的应用基础研究,2020-2023,2020,贺竞辉,苏州市科技局,前瞻性应用研究项目,苏州大学,环境检测,10万,SYG201935,纵向,1
  • 6、基于宽带隙共轭有机材料的新型气体传感器研制,2016-2019,2016,贺竞辉,苏州市科技局,前瞻性应用研究项目,苏州大学,环境检测,10万,SYG201524,纵向,1
  • 7、铝铁分离材料的开发,2023-2024,2023,贺竞辉,横向,苏州大学额,功能材料,30万,横向,1

论文

论文:
  • 1、Tuning memory performances from WORM to flash or DRAM by structural tailoring with different donor moieties,ZHOU F, HE J H, LIU Q, et al.,2014,2(36)
  • 2、The substituent group effect on the morphology and memory performance of phenazine derivatives,GU P Y, MA Y, HE J H, et al.,2015,3(13)
  • 3、Synthesis, Physical Properties, and Light-Emitting Diode Performance of Phenazine-Based Derivatives with Three, Five, and Nine Fused Six-Membered Rings,GU P Y, ZHAO Y B, HE J H, et al.,2015,80(6)
  • 4、Multilevel Conductance Switching of a Memory Device Induced by Enhanced Intermolecular Charge Transfer,GU Q F, HE J H, CHEN D Y, et al.,2015,27(39)
  • 5、Triggering DRAM/SRAM memory behaviors by single atom substitution to alter the molecular planarity,HU H Y, HE J H, ZHUANG H, et al.,2015,3(33)
  • 6、Controlling Crystallite Orientation of Diketopyrrolopyrrole-Based Small Molecules in Thin Films for Highly Reproducible Multilevel Memory Device: Role of Furan Substitution,LI Y, LI H, CHEN H F, et al.,2015,25(27)
  • 7、Effect of single atom substitution in benzochalcogendiazole acceptors on the performance of ternary memory devices,LIU Z J, HE J H, ZHUANG H, et al.,2015,3(35)
  • 8、Two quinoxaline derivatives designed from isomer chemistry for nonvolatile ternary memory device applications,SHI E B, ZHUANG H, LIU Z J, et al.,2015,12266-73
  • 9、Changing the stability of polymer-based memory devices in high conductivity state via tuning the red-ox property of Hemin,ZHANG C Y, HE J H, LU C J, et al.,2015,70343-50
  • 10、Improved ternary memory performance of donor-acceptor structured molecules through cyano substitution,ZHANG Q J, ZHUANG H, HE J H, et al.,2015,3(26)
  • 11、Altering the Position of Phenyl Substitution to Adjust Film Morphology and Memory Device Performance,ZHOU Q H, BO R C, HE J H, et al.,2015,10(7)
  • 12、A Robust and Cost-Effective Superhydrophobic Graphene Foam for Efficient Oil and Organic Solvent Recovery,ZHU H G, CHEN D Y, AN W, et al.,2015,11(39)
  • 13、Graphene Foam with Switchable Oil Wettability for Oil and Organic Solvents Recovery,ZHU H G, CHEN D Y, LI N J, et al.,2015,25(4)
  • 14、Comparison of two strategies to improve organic ternary memory performance: 3-Hexylthiophene linkage and fluorine substitution,BAO Q, LI H, LI Y, et al.,2016,130306-13
  • 15、Comparison of two strategies to improve organic ternary memory performance: 3-Hexylthiophene linkage and fluorine substitution,BAO Q, LI H, LI Y, et al.,2016,130306-13
  • 16、Insertion of conjugated bridges in organic backbone for better multilevel memory performance: The role of alkynyl group,BAO Q, ZHANG Q J, LI Y, et al.,2016,28155-62
  • 17、A facile method to fabricate a double-layer stainless steel mesh for effective separation of water-in-oil emulsions with high flux,CAI Y H, CHEN D Y, LI N J, et al.,2016,4(48)
  • 18、Micro-Nanocomposites in Environmental Management,CHEN D Y, ZHU H G, YANG S, et al.,2016,28(47)
  • 19、Towards Highly-Efficient Phototriggered Data Storage by Utilizing a Diketopyrrolopyrrole-Based Photoelectronic Small Molecule,LI Y, LI H, HE J H, et al.,2016,11(14)
  • 20、Inserting Thienyl Linkers into Conjugated Molecules for Efficient Multilevel Electronic Memory: A New Understanding of Charge-Trapping in Organic Materials,LI Y, LI H, HE J H, et al.,2016,11(6)
  • 21、Organic Multilevel Memory Devices of Long-Term Environmental Stability via Incorporation of Fluorine,LIU Z J, HE J H, LI H, et al.,2016,2(5)
  • 22、Improving organic memory performance through mounting conjugated branches on a triphenylamine core,SHI E B, HE J H, ZHUANG H, et al.,2016,4(13)
  • 23、Hollow porous carbon nitride immobilized on carbonized nanofibers for highly efficient visible light photocatalytic removal of NO,WU H X, CHEN D Y, LI N J, et al.,2016,8(23)
  • 24、Adjusting the Proportion of Electron-Withdrawing Groups in a Graft Functional Polymer for Multilevel Memory Performance,WU L X, WANG P, ZHANG C Y, et al.,2016,11(1)
  • 25、Negative effect on molecular planarity to achieve organic ternary memory: triphenylamine as the spacer,XIA S G, HE J H, LI H, et al.,2016,59(6)
  • 26、Surface-Nanoengineered Bacteria for Efficient Local Enrichment and Biodegradation of Aqueous Organic Wastes: Using Phenol as a Model Compound,YANG S, CHEN D Y, LI N J, et al.,2016,28(15)
  • 27、Ternary Flexible Electro-resistive Memory Device based on Small Molecules,ZHANG Q J, HE J H, ZHUANG H, et al.,2016,11(10)
  • 28、Rational Design of Small Molecules to Implement Organic Quaternary Memory Devices,ZHANG Q J, HE J H, ZHUANG H, et al.,2016,26(1)
  • 29、Efficient simultaneous adsorption-biodegradation of high-concentrated N, N-dimethylformamide from water by Paracoccus denitrificans-graphene oxide microcomposites,ZHENG Y, CHEN D Y, LI N J, et al.,2016,6
  • 30、Flexible Electrospun Carbon Nanofiber/Tin(IV) Sulfide Core/Sheath Membranes for Photocatalytically Treating Chromium(VI)-Containing Wastewater,ZHONG Y L, QIU X, CHEN D Y, et al.,2016,8(42)
  • 31、Fabrication of Unique Magnetic Bionanocomposite for Highly Efficient Removal of Hexavalent Chromium from Water,ZHONG Y L, QIU X, CHEN D Y, et al.,2016,6
  • 32、A versatile and cost-effective reduced graphene oxide-crosslinked polyurethane sponge for highly effective wastewater treatment,ZHU H G, CHEN D Y, YANG S, et al.,2016,6(44)
  • 33、A Robust Absorbent Material Based on Light-Responsive Superhydrophobic Melamine Sponge for Oil Recovery,ZHU H G, YANG S, CHEN D Y, et al.,2016,3(5)
  • 34、Nanofibrous metal-organic framework composite membrane for selective efficient oil/water emulsion separation,CAI Y H, CHEN D Y, LI N J, et al.,2017,54310-7
  • 35、A novel strategy to immobilize bacteria on polymer particles for efficient adsorption and biodegradation of soluble organics,CAI Y H, YANG S, CHEN D Y, et al.,2017,9(32)
  • 36、Poly(3,4-ethylenedioxythiophene)-Poly(styrenesulfonate) Interlayer Insertion Enables Organic Quaternary Memory,CHENG X F, HOU X, QIAN W H, et al.,2017,9(33)
  • 37、1D pi-d Conjugated Coordination Polymers for Multilevel Memory of Long-Term and High-Temperature Stability,CHENG X F, SHI E B, HOU X, et al.,2017,3(8)
  • 38、Upgrading Electroresistive Memory from Binary to Ternary Through Single-Atom Substitution in the Molecular Design,CHENG X F, SHI E B, HOU X, et al.,2017,12(1)
  • 39、Racemic Effect on the Performance of Organic Multilevel Memory: Beyond Molecular Design,CHENG X F, XIA S G, HOU X, et al.,2017,2(11)
  • 40、Bio-Engineered Graphene-Based Cage for Efficient Local Enrichment and Biodegradation of Aqueous Organic Wastes,FAN J X, CHEN D Y, LI N J, et al.,2017,7
  • 41、Surface Engineering of ITO Substrates to Improve the Memory Performance of an Asymmetric Conjugated Molecule with a Side Chain,HOU X, CHENG X F, XIAO X, et al.,2017,12(17)
  • 42、Better Organic Ternary Memory Performance through Self-Assembled Alkyltrichlorosilane Monolayers on Indium Tin Oxide (ITO) Surfaces,HOU X, CHENG X F, ZHOU J, et al.,2017,23(64)
  • 43、Surface engineering to achieve organic ternary memory with a high device yield and improved performance,HOU X, XIAO X, ZHOU Q H, et al.,2017,8(3)
  • 44、In situ fabrication of Bi2O2CO3/MoS2 on carbon nanofibers for efficient photocatalytic removal of NO under visible-light irradiation,HU J D, CHEN D Y, LI N J, et al.,2017,217224-31
  • 45、Molecularly imprinted magnetic microparticles for the simultaneous detection and extraction of Rhodamine B,LI H Y, LI N J, JIANG J, et al.,2017,246286-92
  • 46、Fluorine-Induced Highly Reproducible Resistive Switching Performance: Facile Morphology Control through the Transition between J- and H-Aggregation,LI Y, LIU Z J, LI H, et al.,2017,9(11)
  • 47、Rewritable ternary data storage devices based on polymethacrylate containing pendent azobenzene-naphthalene with the combined effects of conformation change and charge traps,LI Z, WANG M, LI H, et al.,2017,5(33)
  • 48、Coral-inspired nanoscale design of porous SnS2 for photocatalytic reduction and removal of aqueous Cr (VI),QU J F, CHEN D Y, LI N J, et al.,2017,207404-11
  • 49、Urchin-Inspired TiO2@MIL-101 Double-Shell Hollow Particles: Adsorption and Highly Efficient Photocatalytic Degradation of Hydrogen Sulfide,SHENG H B, CHEN D Y, LI N J, et al.,2017,29(13)
  • 50、Different Steric-Twist-Induced Ternary Memory Characteristics in Nonconjugated Copolymers with Pendant Naphthalene and 1,8-Naphthalimide Moieties,WANG M, LI Z, LI H, et al.,2017,12(20)
  • 51、Thermoresponsive Memory Behavior in Metallosupramolecular Polymer-Based Ternary Memory Devices,WANG P, WANG H L, FANG Y, et al.,2017,9(38)
  • 52、Ion-in-Conjugation: Squaraine as an Ultrasensitive Ammonia Sensor Material,XIAO X, CHENG X F, HOU X, et al.,2017,13(2)
  • 53、A novel ternary memory property achieved through rational introduction of end-capping naphthalimide acceptors,ZHANG Q J, HE J H, LI H, et al.,2017,5(31)
  • 54、A Novel Bat-Shaped Dicyanomethylene-4H-pyran-Functionalized Naphthalimide for Highly Efficient Solution-Processed Multilevel Memory Devices,ZHANG Q J, MIAO S F, LI H, et al.,2017,12(12)
  • 55、Highly efficient simultaneous adsorption and biodegradation of a highly-concentrated anionic dye by a high-surface-area carbon-based biocomposite,ZHENG Y, CHEN D Y, LI N J, et al.,2017,179139-47
  • 56、The Application of a Small-Molecule-Based Ternary Memory Device in Transient Thermal-Probing Electronics,ZHOU F, WU B, DONG H L, et al.,2017,29(5)
  • 57、Fabrication of Photocontrolled Surfaces for Oil/Water Separation through Sulfur(VI) Fluoride Exchange,ZHU H G, CHEN D Y, LI N J, et al.,2017,23(59)
  • 58、Dual-layer copper mesh for integrated oil-Water separation and water purification,ZHU H Y, CHEN D Y, LI N J, et al.,2017,200594-600
  • 59、A smart membrane with antifouling capability and switchable oil wettability for high-efficiency oil/water emulsions separation,CAI Y H, CHEN D Y, LI N J, et al.,2018,55569-77
  • 60、Pseudohalide-Induced 2D (CH3 NH3 )2 PbI2 (SCN)2 Perovskite for Ternary Resistive Memory with High Performance,CHENG X F, HOU X, ZHOU J, et al.,2018,14(12)
  • 61、Adsorption and biodegradation of dye in wastewater with Fe3O4@MIL-100 (Fe) core-shell bio-nanocomposites,FAN J X, CHEN D Y, LI N J, et al.,2018,191315-23
  • 62、Fabrication of graphitic-C3N4 quantum dots/graphene-InVO4 aerogel hybrids with enhanced photocatalytic NO removal under visible-light irradiation,HU J D, CHEN D Y, LI N J, et al.,2018,23645-52
  • 63、3D Aerogel of Graphitic Carbon Nitride Modified with Perylene Imide and Graphene Oxide for Highly Efficient Nitric Oxide Removal under Visible Light,HU J D, CHEN D Y, LI N J, et al.,2018,14(19)
  • 64、Recyclable Carbon Nanofibers@Hierarchical I-Doped Bi2O2CO3-MoS2 Membranes for Highly Efficient Water Remediation under Visible-Light Irradiation,HU J D, CHEN D Y, LI N J, et al.,2018,6(2)
  • 65、AgBr-loaded hollow porous carbon nitride with ultrahigh activity as visible light photocatalysts for water remediation,LI X W, CHEN D Y, LI N J, et al.,2018,229155-62
  • 66、One-Step Synthesis of Honeycomb-Like Carbon Nitride Isotype Heterojunction as Low-Cost, High-Performance Photocatalyst for Removal of NO,LI X W, CHEN D Y, LI N J, et al.,2018,6(8)
  • 67、TiO2/sulfonated graphene oxide/Ag nanoparticle membrane: In situ separation and photodegradation of oil/water emulsions,QIAN D L, CHEN D Y, LI N J, et al.,2018,55416-25
  • 68、Engineering 3D Ru/Graphene Aerogel Using Metal-Organic Frameworks: Capture and Highly Efficient Catalytic CO Oxidation at Room Temperature,QU J F, CHEN D Y, LI N J, et al.,2018,14(16)
  • 69、Hollow Porous Carbon with in situ Generated Monodisperse Gold Nanoclusters for Efficient CO Oxidation,QU J F, ZHU H G, CHEN D Y, et al.,2018,10(4)
  • 70、3D ordered MoP inverse opals deposited with CdS quantum dots for enhanced visible light photocatalytic activity,SONG Y, LI N J, CHEN D Y, et al.,2018,238255-62
  • 71、N-Doped and CdSe-Sensitized 3D-Ordered TiO2 Inverse Opal Films for Synergistically Enhanced Photocatalytic Performance,SONG Y, LI N J, CHEN D Y, et al.,2018,6(3)
  • 72、Fluorene, pyrene, and thiophene-based donor-acceptor asymmetric small molecules for solution-processable memory performance,WANG H L, GU P Y, LI H, et al.,2018,15128-34
  • 73、Polysquaraines: Novel humidity sensor materials with ultra-high sensitivity and good reversibility,XIAO X, ZHANG Q J, HE J H, et al.,2018,2551147-52
  • 74、Effects of Single Atom N-Substitution in the Molecular Skeleton on Fabricated Film Quality and Memory Device Performance,ZHANG C, LI Y, ZHANG Q J, et al.,2018,18(3)
  • 75、Preparation of ZnIn2S4 nanosheet-coated CdS nanorod heterostructures for efficient photocatalytic reduction of Cr(VI),ZHANG G P, CHEN D Y, LI N J, et al.,2018,232164-74
  • 76、SnS2/SnO2 heterostructured nanosheet arrays grown on carbon cloth for efficient photocatalytic reduction of Cr(VI),ZHANG G P, CHEN D Y, LI N J, et al.,2018,514306-15
  • 77、The Effect of Random and Block Copolymerization with Pendent Carbozole Donors and Naphthalimide Acceptors on Multilevel Memory Performance,ZHANG Q J, ZHOU J H, LI H, et al.,2018,13(7)
  • 78、Mussel-Inspired Polydopamine Coating for Flexible Ternary Resistive Memory,ZHAO Y Y, CHENG X F, QIAN W H, et al.,2018,13(13)
  • 79、Surface modification of polysquaraines to sense humidity within a second for breath monitoring,ZHOU J, XIAO X, CHENG X F, et al.,2018,271137-46
  • 80、Cyclodextrin-functionalized Ag/AgCl foam with enhanced photocatalytic performance for water purification,ZHU H G, CHEN D Y, LI N J, et al.,2018,53111-7
  • 81、Zeolitic Imidazolate Framework 8-Derived Au@ZnO for Efficient and Robust Photocatalytic Degradation of Tetracycline,GAO B J, ZHOU J, WANG H L, et al.,2019,37(2)
  • 82、Detection of NO2 Down to One ppb Using Ion-in-Conjugation-Inspired Polymer,ZHOU J, CHENG X F, GAO B J, et al.,2019,15(2)
  • 83、Surfactant-Free, One-Step Synthesis of Lead-Free Perovskite Hollow Nanospheres for Trace CO Detection,YE W, HE J H, CAO Q, et al.,2021,33(24)
  • 84、An Ion-In-Conjugation-Boosted Organic Semiconductor Gas Sensor Operating at High Temperature and Immune to Moisture,YU C, HE J H, CHENG X F, et al.,2021,60(28)

科技成果

软件著作 软件著作: 专利 专利:
  • 1、悬浮聚合羟基磷酸钙除氟吸附剂及其制备方法和应用,CN202211632950.7,江苏海普功能材料有限公司,蔡建国; 石洪雁; 贺竞辉; 陶润萍
  • 2、一种显影骨水泥及制备方法和用途,CN202211546563.1,苏州大学,贺竞辉; 张峰
  • 3、一种基于方酸衍生物的氨气传感器及其制备方法和用途,201610024126,路建美,贺竞辉
  • 4、一种基于方酸菁聚合物的湿敏传感器及其制备方法和用途,201610378962.X,路建美,贺竞辉
  • 5、一种基于一维有机无机杂化聚合物链的电存储器件及其制备方法,201611219320,路建美,贺竞辉
  • 6、基于经膦酸或三氯硅烷修饰的ITO玻璃基底的有机电存储器件及其制备方法,201610284076,路建美,贺竞辉
  • 7、一种基于偶氮苯类化合物的醋酸气体传感器及其制备方法和用途,201610024207,路建美,贺竞辉
  • 8、一种基于外消旋体的有机薄膜电子器件及其制备方法,201610940555,路建美,贺竞辉
  • 9、一种基于拟卤素诱导的二维钙钛矿电存储器件及其制备方法,201710345324,路建美,贺竞辉
  • 10、基于金掺杂方酸菁聚合物的湿敏传感器及其制备和用途,201710365212,路建美,贺竞辉
  • 11、一种四进制电存储器及其制备方法与四进制存储材料,201710125092.X,路建美,贺竞辉
  • 12、Ammonia gas sensor based on squaric acid derivative, preparation method and application thereof,US9841411 B2,路建美,贺竞辉
  • 13、Acetic acid gas sensor based on azobenzene compound, preparation method and application thereof,US10222345 B2,路建美,贺竞辉
  • 14、Humidity sensor based on squaraine polymer, preparation method and use thereof,US10302583 B2,路建美,贺竞辉
  • 15、Auto-polymerization electric storage material based on dopamine, preparation method thereof and application to electric storage device thereof ,US10714690 B2,路建美,贺竞辉
  • 16、Organic electric memory device based on phosphonic acid or trichlorosilane-modified ITO glass substrate and preparation method thereof, US9818963 B1,路建美,贺竞辉
  • 17、稠环方酰胺聚合物二氧化氮传感器及其制备方法和用途,2020100113151,苏州大学,路建美,贺竞辉
  • 18、二氨基蒽醌方酰胺聚合物、基于该方酰胺聚合物的湿敏传感器及其制备方法,2019110337635,苏州大学,路建美,贺竞辉
  • 19、稠环方酰胺聚合物、基于稠环方酰胺聚合物的湿敏传感器及其制备方法,2019110337550,苏州大学,路建美,贺竞辉
  • 20、方酰胺聚合物、基于方酰胺聚合物的VOC传感器及其制备方法,2019105077303,苏州大学,路建美,贺竞辉
  • 21、可用于低浓度二氧化氮的方酸菁聚合物传感器及其应用,2019105030398,苏州大学,路建美,贺竞辉
  • 22、良柔性三明治型PN结电存储器件,2019104367046,苏州大学,路建美,贺竞辉
  • 23、基于方酰胺聚合物的二氧化氮传感器及其制备方法和用途,2018106398896,苏州大学,路建美,贺竞辉
  • 24、基于一维有机无机杂化聚合物链的电存储器件及其制备方法,2018103562511,苏州大学,路建美,贺竞辉
  • 25、基于多巴胺的自聚电存储材料及其制备方法与在电存储器件中的应用,2018103230376,苏州大学,路建美,贺竞辉
  • 26、金掺杂纳米氧化锌复合材料及其制备方法与在光催化降解四环素中的应用,2018103174605,苏州大学,路建美,贺竞辉
  • 27、基于方酸菁聚合物的氨气/一氧化氮双组份传感器及其制备方法和应用,2018101085965,苏州大学,路建美,贺竞辉
  • 28、全无机钙碳矿量子点CsPbBr3电存储器件及其制备方法,2017111989209,苏州大学,路建美,贺竞辉
  • 29、基于金掺杂方酸菁聚合物的湿敏传感器及其制备方法和用途,2017103652123,苏州大学,路建美,贺竞辉
  • 30、一种基于拟卤素诱导的二维钙钛矿电存储器件及其制备方法,2017103453242,苏州大学,路建美,贺竞辉
  • 31、一种基于外消旋体的有机薄膜电子器件及其制备方法,2016109405549,苏州大学,路建美,贺竞辉
  • 32、一种基于方酸衍生物的氨气传感器的制备方法,2018100459078,苏州大学,路建美,贺竞辉,肖昕
  • 33、一种基于偶氮苯类化合物的醋酸气体传感器及其制备方法和用途,2016100242067,苏州大学,路建美,贺竞辉
  • 34、一种基于方酸衍生物的氨气传感器及其制备方法和用途,2016100241261,苏州大学,路建美,贺竞辉

荣誉及奖励

荣誉及奖励:
  • 1、江苏省双创博士,2016年
  • 2、苏州市紧缺人才,2017年
  • 3、教育部自然科学一等奖,2017年
  • 4、江苏省政府科学技术一等奖,2017年
  • 5、国家技术发明奖二等奖,2019年

招生信息

招生信息:招生信息1:

学位:博士

毕业院校:新加坡国立大学

电子邮箱:jinghhe@suda.edu.cn

办公地址:苏州大学独墅湖校区一期701-B405

联系电话:

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