基本信息
郑兴华  男  博导  中国科学院工程热物理研究所
电子邮件: zhengxh@iet.cn
通信地址: 海淀区北四环西路11号
邮政编码: 100190

研究领域

微纳材料热电参数表征技术及设备研发、微纳尺度热电输运机理、蓄冷蓄热系统研发

招生信息

招收博士生1名,硕士生1名

招生专业
080701-工程热物理
080702-热能工程
085800-能源动力
招生方向
微纳尺度热电输运机理及特性参数表征技术
微纳尺度热整流
传蓄热系统开发,热电器件,储氢系统

教育背景

2009-09--2012-06   中科院研究生院   博士
2003-09--2005-06   哈尔滨工业大学   硕士学位
1996-09--2000-06   甘肃工业大学   学士
学历
研究生学历

学位
博士学位

工作经历

2015.10至今     中国科学院大学                           岗位教授

2015.3~2016.3    美国加州大学-河滨分校                    访问学者(国家公派)

2005.7至今     中国科学院工程热物理研究所               研实员、助研、副研、项目研究员、研究员


工作简历
2022-05~现在, 中国科学院工程热物理研究所, 研究员
2017-06~2022-05,中国科学院工程热物理研究所, 项目研究员
2015-03~2016-03,University of California - Riverside, 访学
2005-07~2022-05,中科院工程热物理研究所, 助研,副研,项研究员

教授课程

热电能量转换及性能测量技术
材料热电性能测量及柔性热电材料

专利与奖励

   
专利成果
( 1 ) 一种功能纤维的制备装置及方法, 发明专利, 2022, 第 4 作者, 专利号: CN114182369A

( 2 ) 一种直接测量微纳材料热电优值的探测器, 发明专利, 2022, 第 1 作者, 专利号: CN215812545U

( 3 ) 一种基于谐波探测的微纳材料热电性能原位综合测量装置, 发明专利, 2022, 第 1 作者, 专利号: CN215525613U

( 4 ) 一种直接原位综合测量微纳材料热电性能的装置, 发明专利, 2022, 第 1 作者, 专利号: CN215525614U

( 5 ) 一种基于瞬态平面热源的近场热辐射测量装置及方法, 发明专利, 2021, 第 2 作者, 专利号: CN113834851A

( 6 ) 一种近场热辐射独立探测器, 发明专利, 2021, 第 2 作者, 专利号: CN214277970U

( 7 ) 一种基于瞬态平面热源的近场热辐射探测器, 发明专利, 2021, 第 2 作者, 专利号: CN214277971U

( 8 ) 一种直接测量微纳材料热电优值的探测器及制备工艺, 发明专利, 2021, 第 1 作者, 专利号: CN112909155A

( 9 ) 一种直接原位综合测量微纳材料热电性能的方法及装置, 发明专利, 2021, 第 1 作者, 专利号: CN112881464A

( 10 ) 一种基于谐波探测的微纳材料热电性能原位综合测量方法及装置, 发明专利, 2021, 第 1 作者, 专利号: CN112881470A

( 11 ) 一种基于瞬态平面热源的近场热辐射探测器及测量方法, 发明专利, 2021, 第 2 作者, 专利号: CN112595750A

( 12 ) 一种近场热辐射独立探测器、制备方法及测量方法, 发明专利, 2021, 第 2 作者, 专利号: CN112595749A

( 13 ) 一种基于交流法测量低维微纳材料热导率的方法, 专利授权, 2019, 第 1 作者, 专利号: CN109142433A

( 14 ) 基于蓝宝石基底的独立型3ω热物性测量装置和方法, 专利授权, 2018, 第 1 作者, 专利号: CN108051476A

( 15 ) 一种高压气体环境下测量材料导热系数的装置, 专利授权, 2018, 第 3 作者, 专利号: CN107884435A

( 16 ) 一种温控组件热性能测试系统, 实用新型, 2014, 第 4 作者, 专利号: CN204044094U

( 17 ) 抗重力型螺旋盘管式非相变取热装置, 实用新型, 2014, 第 1 作者, 专利号: CN203848729U

( 18 ) 螺旋盘管式非相变取热装置, 发明专利, 2014, 第 1 作者, 专利号: CN103954155A

( 19 ) 双螺旋平面结构谐波法测试材料热物性参数的装置, 发明专利, 2014, 第 2 作者, 专利号: CN203732477U

( 20 ) 双螺旋平面结构谐波法测试材料热物性参数的装置, 实用新型, 2014, 第 2 作者, 专利号: CN103852485A

( 21 ) 测试材料热物性参数的装置, 实用新型, 2013, 第 2 作者, 专利号: CN203178220U

( 22 ) 测试材料热物性参数的装置及方法, 发明专利, 2013, 第 2 作者, 专利号: CN103149233A

( 23 ) 贴面式传感器及吸热系数测量装置, 实用新型, 2013, 第 2 作者, 专利号: CN202735279U

( 24 ) 用于吸热系数测量的贴面式传感器、测量装置及测量方法, 发明专利, 2012, 第 2 作者, 专利号: CN102749353A

( 25 ) 基于独立型传感器的谐波法测量材料蓄热系数装置及方法, 发明专利, 2012, 第 1 作者, 专利号: CN102313758A

( 26 ) 用于各向异性材料导热系数和热扩散率的测定方法, 发明专利, 2011, 第 1 作者, 专利号: CN102279204A

( 27 ) 基于独立型传感器的谐波法测量材料蓄热系数装置, 实用新型, 2011, 第 1 作者, 专利号: CN202057621U

( 28 ) 谐波法微/纳米薄膜热物性测试方法, 发明专利, 2010, 第 1 作者, 专利号: CN101907589A

( 29 ) 谐波探测技术测量液体导热系数和热扩散率的方法及装置, 发明专利, 2010, 第 3 作者, 专利号: CN101266220B

( 30 ) 谐波法单根导电丝状材料热物性测试方法及装置, 发明专利, 2010, 第 1 作者, 专利号: CN101825592A

( 31 ) 具有独立探头的谐波法固体材料热物性测试装置, 实用新型, 2010, 第 1 作者, 专利号: CN201535761U

( 32 ) 具有独立探头的谐波法固体材料热物性测试方法及装置, 发明专利, 2010, 第 1 作者, 专利号: CN101782541A

( 33 ) 谐波探测技术用于微槽道局部对流换热系数测定的方法, 发明专利, 2008, 第 3 作者, 专利号: CN101285786A

( 34 ) 谐波探测技术测量液体导热系数和热扩散率的装置, 发明专利, 2008, 第 3 作者, 专利号: CN201041558Y

出版信息

   
发表论文
[1] Zhao, Haibo, Yang, Xiao, Wang, Chunyang, Lu, Rui, Zhang, Ting, Chen, Haisheng, Zheng, Xinghua. Progress in thermal rectification due to heat conduction in micro/nano solids. MATERIALS TODAY PHYSICS[J]. 2023, 30: http://dx.doi.org/10.1016/j.mtphys.2022.100941.
[2] Shen, Yanan, Han, Xue, Zhang, Pengyu, Chen, Xinyi, Yang, Xiao, Liu, Ding, Yang, Xiaona, Zheng, Xinghua, Chen, Haisheng, Zhang, Kun, Zhang, Ting. Review on Fiber-Based Thermoelectrics: Materials, Devices, and Textiles. ADVANCED FIBER MATERIALSnull. 2023, 5(4): 1105-1140, http://dx.doi.org/10.1007/s42765-023-00267-7.
[3] Dong, Qingxin, Xiang, Junsen, Wang, Zhen, Li, Yunxiu, Lu, Rui, Zhang, Te, Chen, Nan, Huang, Yifei, Wang, Yiyan, Zhu, Wenliang, Li, Guodong, Zhao, Huaizhou, Zheng, Xinghua, Zhang, Shuai, Ren, Zhian, Yang, Jiong, Chen, Genfu, Sun, Peijie. A quasi-one-dimensional bulk thermoelectrics with high performance near room temperature. SCIENCE BULLETIN[J]. 2023, 68(9): 920-927, http://dx.doi.org/10.1016/j.scib.2023.04.017.
[4] Wang, Chunyang, Yang, Xiao, Shen, Yanan, Zhang, Ting, Zheng, Xinghua, Chen, Haisheng. Numerical investigation on cooling performance of multilayer pyramid thermoelectric module. INTERNATIONAL COMMUNICATIONS IN HEAT AND MASS TRANSFER[J]. 2023, 143: http://dx.doi.org/10.1016/j.icheatmasstransfer.2023.106738.
[5] 郑兴华. The effect of binding energy on optimizing the interfacial thermal transport in metal-MoS2-dielectric nanostructures. Materials Today Physics[J]. 2023, 2013(38): 101272-, [6] 左修源, 郑兴华, Zhang, Guolin, 梁福鑫. Organosilica Nanotube for Thermal Insulation. ACS Applied Nano Materials[J]. 2022, [7] Shen, Yanan, Wang, Zhe, Wang, Zhixun, Wang, Jiajia, Yang, Xiao, Zheng, Xinghua, Chen, Haisheng, Li, Kaiwei, Wei, Lei, Zhang, Ting. Thermally drawn multifunctional fibers: Toward the next generation of information technology. INFOMAT[J]. 2022, 4(7): http://apps.webofknowledge.com/CitedFullRecord.do?product=UA&colName=WOS&SID=5CCFccWmJJRAuMzNPjj&search_mode=CitedFullRecord&isickref=WOS:000792566200001.
[8] Shaozhi Wang, Xiao Yang, Lingxiang Hou, Xueping Cui, Xinghua Zheng, Jian Zheng. Organic covalent modification to improve thermoelectric properties of TaS 2. NATURE COMMUNICATIONS[J]. 2022, 13(1): 1-6, http://dx.doi.org/10.1038/s41467-022-32058-w.
[9] 王春阳, 郑兴华, 陈海生. The effect of porosity and the number of cells of a porous medium on applicability of volume averaged and pore scale approaches: single phase and solid/liquid phase change. International Journal of Numerical Methods for Heat & Fluid Flow[J]. 2022, [10] Yang, Xiao, Wang, Chunyang, Lu, Rui, Shen, Yanan, Zhao, Haibo, Li, Jian, Li, Ruiyi, Zhang, Lixin, Chen, Haisheng, Zhang, Ting, Zheng, Xinghua. Progress in measurement of thermoelectric properties of micro/nano thermoelectric materials: A critical review. NANO ENERGY[J]. 2022, 101: [11] Yang, Xiao, Wang, Shaozhi, Wang, Chunyang, Lu, Rui, Zheng, Xinghua, Zhang, Ting, Liu, Ming, Zheng, Jian, Chen, Haisheng. Thermal Rectifier and Thermal Transistor of 1T/2H MoS2 for Heat Flow Management. ACS APPLIED MATERIALS & INTERFACES[J]. 2022, 14(3): 4434-4442, http://dx.doi.org/10.1021/acsami.1c21226.
[12] Ruiyi Li, Xiao Yang, Jian Li, Ding Liu, Lixin Zhang, Haisheng Chen, Xinghua Zheng, Ting Zhang. Pre-Ball-Milled Boron Nitride for the Preparation of Boron Nitride/Polyetherimide Nanocomposite Film with Enhanced Breakdown Strength and Mechanical Properties for Thermal Management. NANOMATERIALS[J]. 2022, 12: https://doaj.org/article/af06b0ce179f4bfb836807bd10fede96.
[13] 卢瑞, 杨啸, 张挺, 郑兴华. Integrated measurement of thermoelectric properties for filamentary materials using a modified hot wire method. Review of Scientific Instruments[J]. 2022, [14] Li, R, Yang, X, Li, J, Shen, Y, Zhang, L, Lu, R, Wang, C, Zheng, X, Chen, H, Zhang, T. Review on polymer composites with high thermal conductivity and low dielectric properties for electronic packaging. MATERIALS TODAY PHYSICS[J]. 2022, 22: http://dx.doi.org/10.1016/j.mtphys.2021.100594.
[15] Zheng, Xinghua, Wang, Xinwei, Zhang, Ting, Zhang, Xiaoliang, Chen, Haisheng. Study on the interfacial thermal conductance between metals and phase change materials. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2021, 168: http://dx.doi.org/10.1016/j.ijheatmasstransfer.2020.120823.
[16] Shen, Yanan, Wang, Chunyang, Yang, Xiao, Li, Jian, Lu, Rui, Li, Ruiyi, Zhang, Lixin, Chen, Haisheng, Zheng, Xinghua, Zhang, Ting. New Progress on Fiber-Based Thermoelectric Materials: Performance, Device Structures and Applications. MATERIALS[J]. 2021, 14(21): http://dx.doi.org/10.3390/ma14216306.
[17] Yang, Xiao, Zheng, Xinghua, Zhang, Ting, Chen, Haisheng, Liu, Ming. Experimental study on thermal conductivity and rectification of monolayer and multilayer MoS2. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2021, 170: http://dx.doi.org/10.1016/j.ijheatmasstransfer.2021.121013.
[18] Yang Zheng, Cheng Xu, Zheng Xinghua, Chen Haisheng. Reynolds-Averaged Navier-Stokes Equations Describing Turbulent Flow and Heat Transfer Behavior for Supercritical Fluid. JOURNAL OF THERMAL SCIENCE[J]. 2021, 30(1): 191-200, http://lib.cqvip.com/Qikan/Article/Detail?id=7104055408.
[19] Yang, Xiao, Zheng, Xinghua, Liu, Qiushi, Zhang, Ting, Bai, Ye, Yang, Zheng, Chen, Haisheng, Liu, Ming. Experimental Study on Thermal Conductivity and Rectification in Suspended Monolayer MoS2. ACS APPLIED MATERIALS & INTERFACES[J]. 2020, 12(25): 28306-28312, https://www.webofscience.com/wos/woscc/full-record/WOS:000543780900046.
[20] 郑兴华. Bamboo-like polymer nanotubes – a new super thermal insulation material. Nanotechnology. 2020, [21] Zheng, Xinghua, Yang, Xiao, Wan, Jiping, Zhang, Ting, Yang, Zheng, Wang, Liang, Chen, Haisheng, Liang, Fuxin, Tang, Dawei. A novel super thermal insulation material: bamboo-like polymer nanotubes. NANOTECHNOLOGY[J]. 2020, 31(34): https://www.webofscience.com/wos/woscc/full-record/WOS:000541896900001.
[22] Yang, Xiao, Zheng, Xinghua, Yang, Zheng, Bai, Ye, Chen, Haisheng. Effects of morphology and internal voids of copper ribs on heat transfer performance in copper foam/paraffin composite phase change materials. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2020, 152: http://dx.doi.org/10.1016/j.ijheatmasstransfer.2020.119526.
[23] Yang, Zheng, Cheng, Xu, Zheng, Xinghua, Chen, Haisheng. Numerical investigation on heat transfer of the supercritical fluid upward in vertical tube with constant wall temperature. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2019, 128: 875-884, http://dx.doi.org/10.1016/j.ijheatmasstransfer.2018.09.049.
[24] Yang Xiao, Zheng Xinghua, Yang Zheng, Wang Liang, Chen Haisheng, ASME. A METHOD FOR MEASURING THERMAL CONDUCTIVITY OF LOW-DIMENSIONAL MATERIALS BASED ON DC HEATING. PROCEEDINGS OF THE ASME 6TH INTERNATIONAL CONFERENCE ON MICRO/NANOSCALE HEAT AND MASS TRANSFER, 2019null. 2019, http://apps.webofknowledge.com/CitedFullRecord.do?product=UA&colName=WOS&SID=5CCFccWmJJRAuMzNPjj&search_mode=CitedFullRecord&isickref=WOS:000502408800046.
[25] 郑兴华. Micro-nano fiber thermal conductivity measurement(Invited Speech). International Conference on Nanochemistry (ICN 2019),19th July 2019 - 21st July 2019. 2019, [26] 郑兴华. Multi -dimensional cross -scale material thermal conductivity measuring instrument(Invited Lecture). The 2nd International Symposium on Measurement Technology in Thermal Science and Engineering Nov. 15-17, 2019, Dalian, China. 2019, [27] 郑兴华. 泡沫金属相变复合材料界面热导研究. 2018年度中国传热年会. 2018, [28] 郑兴华. 3ω INDEPENDENT DETECTOR BASED ON SAPPHIRE SUBSTRATE. Proceedings of the 16th International Heat Transfer Conference, IHTC-16. 2018, [29] Zheng, Xinghua, Yue, Peng, Li, Shen, Wang, Liang, Yang, Xiao, Chen, Haisheng. Stethoscope-type 3 omega independent detector for fast measurement of material thermal conductivity. REVIEW OF SCIENTIFIC INSTRUMENTS[J]. 2018, 89(8): https://www.webofscience.com/wos/woscc/full-record/WOS:000443720400061.
[30] 郑兴华. EXPERIMENT AND ANALYSIS OF EFFECTIVE THERMAL CONDUCTIVITY OF A COPPER FOAM/PARAFFIN COMPOSITE PHASE CHANGE MATERIAL. Proceedings of the 16th International Heat Transfer Conference, IHTC-16. 2018, [31] 郑兴华. The interfacial thermal conductance measurement between three metals and the PCMs solid and liquid by Femto-Second laser pump-probe technique. 10th Inernational Conference on Advanced Nano Materials,University of Surrey,Guildford,England on11-13 September,2017. 2017, [32] Qiu, Lin, Wang, Xiaotian, Tang, Dawei, Zheng, Xinghua, Norris, Pamela M, Wen, Dongsheng, Zhao, Jingna, Zhang, Xiaohua, Li, Qingwen. Functionalization and densification of inter-bundle interfaces for improvement in electrical and thermal transport of carbon nanotube fibers. CARBON[J]. 2016, 105: 248-259, http://dx.doi.org/10.1016/j.carbon.2016.04.043.
[33] Qiu, Lin, Wang, Xiaotian, Su, Guoping, Tang, Dawei, Zheng, Xinghua, Zhu, Jie, Wang, Zhiguo, Norris, Pamela M, Bradford, Philip D, Zhu, Yuntian. Remarkably enhanced thermal transport based on a flexible horizontally-aligned carbon nanotube array film. SCIENTIFIC REPORTS[J]. 2016, 6: http://www.irgrid.ac.cn/handle/1471x/1035658.
[34] Zheng, X H, Qiu, L, Yue, P, Wang, G, Tang, D W. 3 omega slope comparative method for fluid and powder thermal conductivity measurements. MODERN PHYSICS LETTERS B[J]. 2016, 30(25): https://www.webofscience.com/wos/woscc/full-record/WOS:000384456600007.
[35] 曹运涛, 邱琳, 郑兴华, 唐大伟, 朱群志, 裴振洪. 3ω微型探测器用于固体材料热导率的测量. 工程热物理学报[J]. 2016, 37(4): 803-806, http://sciencechina.cn/gw.jsp?action=detail.jsp&internal_id=5678668&detailType=1.
[36] Zou, Fangxin, Yue, Peng, Zheng, Xinghua, Tang, Dawei, Fu, Wenxin, Li, Zhibo. Robust and superhydrophobic thiourethane bridged polysilsesquioxane aerogels as potential thermal insulation materials. JOURNAL OF MATERIALS CHEMISTRY A[J]. 2016, 4(28): 10801-10805, http://ir.etp.ac.cn/handle/311046/112496.
[37] Qiu, L, Zheng, X H, Zhu, J, Tang, D W, Yang, S Y, Hu, A J, Wang, L L, Li, S S. Thermal Transport in High-Strength Polymethacrylimide (PMI) Foam Insulations. INTERNATIONALJOURNALOFTHERMOPHYSICS[J]. 2015, 36(10-11): 2523-2534, http://ir.iccas.ac.cn/handle/121111/29364.
[38] Han, Peng, Zheng, XingHua, Hou, WenShuo, Qiu, Lin, Tang, DaWei. Study on heat-storage and release characteristics of multi-cavity-structured phase-change microcapsules. PHASE TRANSITIONS[J]. 2015, 88(7): 704-715, http://www.irgrid.ac.cn/handle/1471x/993966.
[39] 邱琳, 郑兴华, 岳鹏, 唐大伟, 曹丽莉, 邓元. 碲化铋取向纳米柱状薄膜热导率测量. 工程热物理学报[J]. 2015, 36(4): 816-819, https://d.wanfangdata.com.cn/periodical/gcrwlxb201504025.
[40] 曹运涛, 邱琳, 郑兴华, 唐大伟, 朱群志. 3ω非对称模型用于固体材料热导率的测量. 2015年中国工程热物理学会传热传质学学术年会null. 2015, http://ir.etp.ac.cn/handle/311046/107757.
[41] L. Qiu, X.H. Zheng, P. Yue, J. Zhu, D.W. Tang, Y.J. Dong, Y.L. Peng. Adaptable thermal conductivity characterization of microporous membranes based on freestanding sensor-based 3ω technique. INTERNATIONAL JOURNAL OF THERMAL SCIENCES. 2015, 89: 185-192, http://dx.doi.org/10.1016/j.ijthermalsci.2014.11.005.
[42] 岳鹏, 邱琳, 郑兴华, 唐大伟. 基于蓝宝石基底的独立型3ω探测器. 2015年中国工程热物理学会传热传质学学术年会null. 2015, http://ir.etp.ac.cn/handle/311046/107603.
[43] Qiu, L, Li, Y M, Zheng, X H, Zhu, J, Tang, D W, Wu, J Q, Xu, C H. Thermal-Conductivity Studies of Macro-porous Polymer-Derived SiOC Ceramics. INTERNATIONAL JOURNAL OF THERMOPHYSICS[J]. 2014, 35(1): 76-89, http://ir.iccas.ac.cn/handle/121111/27071.
[44] 邱琳, 郑兴华, 岳鹏, 唐大伟, 曹丽莉, 邓元. 碲化铋取向纳米柱状薄膜热导率测量. 2014年中国工程热物理学会null. 2014, http://ir.etp.ac.cn/handle/311046/89880.
[45] Su, GuoPing, Qiu, Lin, Zheng, XingHua, Xiao, ZhuoHao, Tang, DaWei. Effective Thermal-Conductivity Measurement on Germanate Glass-Ceramics Employing the 3 omega Method at High Temperature. INTERNATIONAL JOURNAL OF THERMOPHYSICS[J]. 2014, 35(2): 336-345, http://www.irgrid.ac.cn/handle/1471x/994121.
[46] Yue, Peng, Qiu, Lin, Zheng, Xinghua, Tang, Dawei, Tang, F. The Effective Thermal Conductivity of Porous Polymethacrylimide Foams. MICRO-NANO TECHNOLOGY XVnull. 2014, 609-610: 196-200, [47] 邱琳, 郑兴华, 唐大伟, 周文斌, 解思深. 碳纳米管纤维及薄膜的热导率和热扩散率研究. 工程热物理学报[J]. 2014, 718-721, http://lib.cqvip.com/Qikan/Article/Detail?id=71678266504849524852485050.
[48] 郑兴华. Effective Thermal-ConductivityMeasurementon Germanate Glass–Ceramics Employing the 3ωMethod at High Temperature. INTERNATIONAL JOURNAL OF THERMOPHYSICS. 2014, [49] Liu, M, Qiu, L, Zheng, X H, Zhu, J, Tang, D W. Study on the thermal resistance in secondary particles chain of silica aerogel by molecular dynamics simulation. JOURNAL OF APPLIED PHYSICS[J]. 2014, 116(9): http://www.irgrid.ac.cn/handle/1471x/994135.
[50] Chen, Wei, Qiu, Lin, Liang, Shiqiang, Zheng, Xinghua, Tang, Dawei. Measurement of thermal conductivities of mmimDMP/CH3OH and mmimDMP/H2O by freestanding sensor-based 3 omega technique. THERMOCHIMICA ACTA[J]. 2013, 560(1): 1-6, http://www.irgrid.ac.cn/handle/1471x/993907.
[51] Qiu, L, Zheng, X H, Su, G P, Tang, D W. Design and Application of a Freestanding Sensor Based on 3 omega Technique for Thermal-Conductivity Measurement of Solids, Liquids, and Nanopowders. INTERNATIONAL JOURNAL OF THERMOPHYSICS[J]. 2013, 34(12): 2261-2275, http://www.irgrid.ac.cn/handle/1471x/993851.
[52] 邱琳, 郑兴华, 唐大伟, 周文斌, 解思深. 碳纳米管纤维及薄膜的热导率和热扩散率研究. 中国工程热物理学会-传热传质null. 2013, http://ir.etp.ac.cn/handle/311046/84645.
[53] Qiu, L, Zheng, X H, Zhu, J, Su, G P, Tang, D W. The effect of grain size on the lattice thermal conductivity of an individual polyacrylonitrile-based carbon fiber. CARBON[J]. 2013, 51(1): 265-273, http://dx.doi.org/10.1016/j.carbon.2012.08.052.
[54] 郑兴华, 邱琳, 李兰兰, 岳鹏, 王刚, 唐大伟. 相变微胶囊的吸热系数测量. 工程热物理学报[J]. 2013, 34(9): 1692-1694, http://sciencechina.cn/gw.jsp?action=detail.jsp&internal_id=4935760&detailType=1.
[55] Zhao, Gangtao, Xu, Xiaohui, Qiu, Lin, Zheng, Xinghua, Tang, Dawei. Study on the Heat Conduction of Phase-Change Material Microcapsules. JOURNAL OF THERMAL SCIENCE[J]. 2013, 22(3): 257-260, http://lib.cqvip.com/Qikan/Article/Detail?id=45620398.
[56] Su, GuoPing, Zheng, XingHua, Qiu, Lin, Tang, DaWei, Zhu, Jie. Measurement of Thermal Conductivity of Anisotropic SiC Crystal. INTERNATIONAL JOURNAL OF THERMOPHYSICS[J]. 2013, 34(12): 2334-2342, http://www.irgrid.ac.cn/handle/1471x/993878.
[57] 岳鹏, 邱琳, 郑兴华, 唐大伟. 多孔聚甲基丙烯酰亚胺泡沫的有效热导率测量. 中国工程热物理学会-传热传质null. 2013, http://ir.etp.ac.cn/handle/311046/84867.
[58] 郑兴华, 邱琳, 祝捷, 苏国萍, 唐大伟. 相变微胶囊的热导率测量. 工程热物理学报[J]. 2012, 33(3): 454-456, http://lib.cqvip.com/Qikan/Article/Detail?id=41014518.
[59] 郑兴华, 邱琳, 唐大伟. 相变微胶囊的吸热系数率测量. 中国工程热物理学会null. 2012, http://ir.etp.ac.cn/handle/311046/59340.
[60] 苏国萍, 郑兴华, 邱琳, 祝捷, 唐大伟. 相变微胶囊的热导率测量. 中国工程热物理学会(传热传质学)null. 2011, http://ir.etp.ac.cn/handle/311046/27685.
[61] 郑兴华. 利用3ω法测量纳米SiO2粉末热导率及热扩散率. 工程热物理学报. 2011, [62] Qiu, L, Zheng, X H, Zhu, J, Tang, D W. Note: Non-destructive measurement of thermal effusivity of a solid and liquid using a freestanding serpentine sensor-based 3 omega technique. REVIEW OF SCIENTIFIC INSTRUMENTS[J]. 2011, 82(8): http://www.irgrid.ac.cn/handle/1471x/994191.
[63] Zheng, Xinghua, Qiu, Lin, Su, Guoping, Tang, Dawei, Liao, Yuchao, Chen, Yunfa. Thermal conductivity and thermal diffusivity of SiO2 nanopowder. JOURNAL OF NANOPARTICLE RESEARCH[J]. 2011, 13(12): 6887-6893, http://www.irgrid.ac.cn/handle/1471x/994637.
[64] 苏国萍, 唐大伟, 郑兴华, 邱琳, 杜景龙. 3ω方法测量各向异性SiC晶体的导热系数. 工程热物理学报[J]. 2011, 32(11): 1885-1888, http://lib.cqvip.com/Qikan/Article/Detail?id=39683098.
[65] 邱琳, 郑兴华, 苏国萍, 唐大伟. 具有独立探头的3ω技术测量固体热导率. 工程热物理学报[J]. 2011, 32(4): 621-624, http://lib.cqvip.com/Qikan/Article/Detail?id=37098149.
[66] Qiu, L, Tang, D W, Zheng, X H, Su, G P. The freestanding sensor-based 3 omega technique for measuring thermal conductivity of solids: Principle and examination. REVIEW OF SCIENTIFIC INSTRUMENTS[J]. 2011, 82(4): http://www.irgrid.ac.cn/handle/1471x/994647.
[67] 李谦, 郑兴华, 祝捷, 唐大伟, 刘云圻, 朱道本. 垂直生长碳纳米管阵列法向导热系数测量. 工程热物理学报[J]. 2010, 84-86, http://lib.cqvip.com/Qikan/Article/Detail?id=32639257.
[68] 邱琳, 郑兴华, 李谦, 唐大伟, 钱杨保, 张伟刚. 陶瓷热障涂层的热导率和热扩散率测量. 功能材料[J]. 2010, 264-267, http://lib.cqvip.com/Qikan/Article/Detail?id=35424082.
[69] 邱琳, 唐大伟, 郑兴华, 苏国萍. 具有独立探头的3ω技术测量固体热导率. 中国工程热物理学会(传热传质学)null. 2010, http://ir.etp.ac.cn/handle/311046/31739.
[70] 郑兴华, 唐大伟, 邱琳, 苏国萍. 3ω法测量SiO2粉体热导率和热扩散率. 中国工程热物理学会(传热传质学)null. 2010, http://ir.etp.ac.cn/handle/311046/31495.
[71] 苏国萍, 唐大伟, 郑兴华, 邱琳, 杜景龙. 3ω方法测量各向异性SiC晶体的导热系数. 中国工程热物理学会(传热传质学)null. 2010, http://ir.etp.ac.cn/handle/311046/31491.
[72] 布文峰, 郑兴华, 唐大伟, 章琪. 光热反射技术测量表面下微尺度热结构. 工程热物理学报[J]. 2009, 118-120, http://lib.cqvip.com/Qikan/Article/Detail?id=29231689.
[73] 张春平, 唐大伟, 曲伟, 郑兴华. 粗糙度对微细通道内流动特性影响的实验研究. 上海理工大学学报[J]. 2008, 30(1): 55-58, http://lib.cqvip.com/Qikan/Article/Detail?id=26651177.
[74] 布文峰, 郑兴华, 唐大伟, 王照亮, 程光华. 光热反射实验中微弱信号的测量. 上海理工大学学报[J]. 2008, 30(1): 71-74, http://lib.cqvip.com/Qikan/Article/Detail?id=26651181.
[75] 王照亮, 唐大伟, 郑兴华, 布文峰, 张伟刚. 3ω法测量单根碳纤维导热系数和热容. 工程热物理学报[J]. 2007, 28(3): 490-492, http://lib.cqvip.com/Qikan/Article/Detail?id=24275677.
[76] Wang, Zhao Liang, Tang, Da Wei, Zheng, Xing Hua. Simultaneous determination of thermal conductivities of thin film and substrate by extending 3 omega-method to wide-frequency range. APPLIED SURFACE SCIENCE[J]. 2007, 253(22): 9024-9029, http://ir.etp.ac.cn/handle/311046/106275.
[77] 王照亮, 唐大伟, 郑兴华, 周乐平, 刘石. 利用3ω法同时测量纳米流体热导率和热扩散系数. 化工学报[J]. 2007, 58(10): 2462-2468, http://lib.cqvip.com/Qikan/Article/Detail?id=25622393.
[78] 胡振江, 郑兴华, 张英华, 孙涛, 董申. 基于原子力显微镜的纳米三维刻划加工控制系统. 计算机测量与控制[J]. 2006, 14(10): 1358-1360, https://d.wanfangdata.com.cn/periodical/jsjzdclykz200610028.
发表著作
(1) 热能调控微纳结构材料-第三章, 科学技术出版社, 2014-06, 第 1 作者
(2) Green Building and Phase Change Materials: Characteristics, Energy Implications and Environmental Impacts(Chapter Heat Conduction and Heat Storage Characterizations of Phase-Change Microcapsules), Nova Science Publisher, 2015-08, 第 2 作者
(3) Advanced Fiber Sensing technologies-Thermoelectric Fibers, pringer Nature Singapore Ltd., 2020-10, 第 3 作者

科研活动

   
参与会议
(1)单层多层二硫化钼薄膜的热导率和整流效应的实验研究   传热年会   杨啸,郑兴华,杨征,张挺,陈海生,周学志   2020-11-27
(2)A Method for Measuring Thermal Conductivity of Low-dimensional Materials Based on AC Heating Method   Xiao Yang, Xinghua Zheng, Zheng Yang,Liang Wang, Haisheng Chen    2018-12-12
(3)Thermal conductivity measurement of single organic polymer nano-bamboo fiber   Xinghua Zheng, Xiao Yang, Zheng Yang,Liang Wang, Haisheng Chen   2018-12-12
(4)泡沫金属相变复合材料界面热导研究   传热年会   郑兴华,王新伟,杨啸,孙方远,陈海生   2018-10-12
(5)EXPERIMENT AND ANALYSIS OF EFFECTIVE THERMAL CONDUCTIVITY OF A COPPER FOAM/PARAFFIN COMPOSITE PHASE CHANGE MATERIAL   xiao yang, xinghau zheng,shen li, haisheng chen   2018-08-10
(6)3ω INDEPENDENT DETECTOR BASED ON SAPPHIRE SUBSTRATE    zhengxinghua,yuepeng,lishen, yangxiao,chenhaisheng   2018-08-10
(7)The interfacial thermal conductance measurement between three metals and the PCMs solid and liquid by Femto-Second laser pump-probe technique   Xinghua Zheng, Xinwei Wang, Fangyuan Sun, Haisheng Cheng   2017-09-11
(8)The interfacial thermal conductance measurement between metals and the PCMs by femto-second laser pump-probe technique   2017-03-27
(9)A Stethoscope-like 3ω Technique for On-Site Thermophysical Properties Measurement   第19届国际热物性研讨会   P. Yue, X.H. Zheng *, L. Qiu, D.W. Tang   2015-06-21
(10)Theoretical Investigation on Thermal Conductivity of Silica Aerogel Powder   Xinghua Zheng, Meng Liu, Lin Qiu*, Yuhua Li*, Gang Wang, Dawei Tang   2015-03-12
(11)3ω Slope Comparative Method for Fluid and Powder Thermal Properties Measurements   Xinghua Zheng,Lin Qiu*,Peng Yue,Gang Wang,Dawei Tang*   2013-10-18

指导学生

已指导学生

杨啸  博士研究生  080701-工程热物理  

现指导学生

卢瑞  硕士研究生  085206-动力工程  

赵海波  硕士研究生  080701-工程热物理  

郑辉  硕士研究生  085800-能源动力  

硕士

指导在读硕士2名:卢瑞(2019级),赵海波(2021级)

协助指导硕士4名:李谦(2008级)、岳鹏(2012级)、刘蒙(2012级)、曹运涛(2013级)

博士
协助指导博士2名:邱琳(2012届)、苏国萍(2012届)