基本信息
张之 男 中国科学院大学
电子邮件: zhangzhi@binn.cas.cn
通信地址: 北京市杨雁东一路8号院
邮政编码: 101400
电子邮件: zhangzhi@binn.cas.cn
通信地址: 北京市杨雁东一路8号院
邮政编码: 101400
招生信息
招生专业
080502-材料学
0805J1-纳米科学与技术
0805J1-纳米科学与技术
招生方向
微纳能源与传感
半导体界面的摩擦伏特效应及新型摩擦电子器件
半导体多物理场耦合效应及多源能量采集器件
半导体界面的摩擦伏特效应及新型摩擦电子器件
半导体多物理场耦合效应及多源能量采集器件
教育背景
2013-09--2018-06 华中科技大学 工学博士
2009-09--2013-06 华中科技大学 工学学士
2009-09--2013-06 华中科技大学 工学学士
工作经历
工作简历
2022-12~现在, 中国科学院北京纳米能源与系统研究所, 副研究员
2020-11~2022-11,中国科学院北京纳米能源与系统研究所, 助理研究员
2018-07~2020-12,国家纳米科学中心, 博士后
2020-11~2022-11,中国科学院北京纳米能源与系统研究所, 助理研究员
2018-07~2020-12,国家纳米科学中心, 博士后
专利与奖励
奖励信息
(1) 年度优秀职工, 一等奖, 研究所(学校), 2022
(2) ICANX科学大会优秀论文奖, 一等奖, 其他, 2022
(2) ICANX科学大会优秀论文奖, 一等奖, 其他, 2022
专利成果
[1] 张之, 方海生, 蒋志敏, 郑江, 刘胜, 甘志银. 一种用于MOCVD设备的喷淋头. CN: CN104498904B, 2017-04-26.
[2] 方海生, 王森, 赵超杰, 田俊, 张之. 一种多晶硅铸锭炉热场结构. 中国: CN204265887U, 2015-04-15.
[3] 黄荣华, 陈琳, 王恒超, 张之, 金晓强, 尹涛, 向柳, 周涛. 风力发电机叶轮方向控制装置. CN: CN103266991B, 2014-12-31.
[4] 方海生, 金泽林, 王森, 赵超杰, 张梦洁, 张之. 一种提拉法晶体生长炉. CN: CN203653745U, 2014-06-18.
[2] 方海生, 王森, 赵超杰, 田俊, 张之. 一种多晶硅铸锭炉热场结构. 中国: CN204265887U, 2015-04-15.
[3] 黄荣华, 陈琳, 王恒超, 张之, 金晓强, 尹涛, 向柳, 周涛. 风力发电机叶轮方向控制装置. CN: CN103266991B, 2014-12-31.
[4] 方海生, 金泽林, 王森, 赵超杰, 张梦洁, 张之. 一种提拉法晶体生长炉. CN: CN203653745U, 2014-06-18.
出版信息
发表论文
[1] Fu, Xianpeng, Qin, Yuhan, Zhang, Zhi, Liu, Guoxu, Cao, Jie, Fan, Beibei, Wang, Zhaozheng, Wang, Zheng, Zhang, Chi. Ultra-Robust and High-Performance Rotational Triboelectric Nanogenerator by Bearing Charge Pumping. ENERGY & ENVIRONMENTAL MATERIALS. 2023, http://dx.doi.org/10.1002/eem2.12566.
[2] Cao, Jie, Lin, Yuan, Fu, Xianpeng, Wang, Zheng, Liu, Guoxu, Zhang, Zhi, Qin, Yuhan, Zhou, Han, Dong, Sicheng, Cheng, Guanggui, Zhang, Chi, Ding, Jianning. Self-powered overspeed wake-up alarm system based on triboelectric nanogenerators for intelligent transportation. NANO ENERGY[J]. 2023, 107: http://dx.doi.org/10.1016/j.nanoen.2022.108150.
[3] Dong, Sicheng, Bu, Tianzhao, Wang Zhaozheng, Feng Yuan, Liu Guoxu, Zeng Jianhua, Wang Zhihao, Cao Jie, Zhang Zhi, Liu Feng, Zhang Chi. Freestanding-Mode Tribovoltaic Nanogenerator for Harvesting Sliding and Rotational Mechanical Energy. Advanced Energy Materials[J]. 2023, 13(16): https://onlinelibrary.wiley.com/doi/abs/10.1002/aenm.202300079.
[4] Beibei Fan, Guoxu Liu, Xianpeng Fu, Zhaozheng Wang, Zhi Zhang, Chi Zhang. Composite film with hollow hierarchical silica/perfluoropolyether filler and surface etching for performance enhanced triboelectric nanogenerators. CHEMICAL ENGINEERING JOURNAL. 2022, 446: http://dx.doi.org/10.1016/j.cej.2022.137263.
[5] Yuan Lin, Youchao Qi, Jiaqi Wang, Guoxu Liu, Zhaozheng Wang, Junqing Zhao, Yi Lv, Zhi Zhang, Ning Tian, Mengbi Wang, Yuanfen Chen, Chi Zhang, Stefano Lenci. Self-Powered and Autonomous Vibrational Wake-Up System Based on Triboelectric Nanogenerators and MEMS Switch. SENSORS (BASEL, SWITZERLAND). 2022, 22(10): https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9145876/.
[6] Wang, Zhaozheng, Zhang, Zhi, Chen, Yunkang, Gong, Likun, Dong, Sicheng, Zhou, Han, Lin, Yuan, Lv, Yi, Liu, Guoxu, Zhang, Chi. Achieving an ultrahigh direct-current voltage of 130 V by semiconductor heterojunction power generation based on the tribovoltaic effect. ENERGY & ENVIRONMENTAL SCIENCE[J]. 2022, 15(6): 2366-2373, http://dx.doi.org/10.1039/d2ee00180b.
[7] Chen, Yunkang, Zhang, Zhi, Wang, Zhaozheng, Bu, Tianzhao, Dong, Sicheng, Wei, Wenwang, Chen, Zhiqiang, Lin, Yuan, Lv, Yi, Zhou, Han, Sun, Wenhong, Zhang, Chi. Friction-Dominated Carrier Excitation and Transport Mechanism for GaN-Based Direct-Current Triboelectric Nanogenerators. ACS APPLIED MATERIALS & INTERFACES[J]. 2022, 14(20): 24020-24027, http://dx.doi.org/10.1021/acsami.2c03853.
[8] Cao, Jie, Fu, Xianpeng, Zhu, Hao, Qu, Zhaoqi, Qi, Youchao, Zhang, Zhi, Zhang, Zhongqiang, Cheng, Guanggui, Zhang, Chi, Ding, Jianning. Self-Powered Non-Contact Motion Vector Sensor for Multifunctional Human-Machine Interface. SMALL METHODS[J]. 2022, 6(8): http://dx.doi.org/10.1002/smtd.202200588.
[9] Qi, Youchao, Liu, Guoxu, Bu, Tianzhao, Zeng, Jianhua, Zhang, Zhi, Zhang, Chi. Ferromagnetic-Based Charge-Accumulation Triboelectric Nanogenerator With Ultrahigh Surface Charge Density. SMALL[J]. 2022, 18(31): http://dx.doi.org/10.1002/smll.202201754.
[10] Zhang, Zhi, Wang, Zhaozheng, Chen, Yunkang, Feng, Yuan, Dong, Sicheng, Zhou, Han, Wang, Zhong Lin, Zhang, Chi. Semiconductor Contact-Electrification-Dominated Tribovoltaic Effect for Ultrahigh Power Generation. ADVANCED MATERIALS[J]. 2022, 34(20): http://dx.doi.org/10.1002/adma.202200146.
[11] Wang, Zhaozheng, Gong, Likun, Dong, Sicheng, Fan, Beibei, Feng, Yuan, Zhang, Zhi, Zhang, Chi. A humidity-enhanced silicon-based semiconductor tribovoltaic direct-current nanogenerator. JOURNAL OF MATERIALS CHEMISTRY A[J]. 2022, 10(47): 25230-25237, [12] Xie, Yuanyuan, Zhang, Zhi, Zhou, Han, Wang, Zhaozheng, Lin, Yuan, Chen, Yunkang, Lv, Yi, Chen, Yuanfen, Zhang, Chi. Multisource Energy Harvester with Coupling Structure and Multiplexing Mechanism. ADVANCED MATERIALS INTERFACES[J]. 2022, 9(16): http://dx.doi.org/10.1002/admi.202200468.
[13] Zhang, Zhi, He, T, Zhao, J, Liu, G, Wang, Z L, Zhang, C. Tribo-thermoelectric and tribovoltaic coupling effect at metal-semiconductor interface. MATERIALS TODAY PHYSICS[J]. 2021, 16: http://dx.doi.org/10.1016/j.mtphys.2020.100295.
[14] Zhang, Zhi, Jiang, Dongdong, Zhao, Junqing, Liu, Guoxu, Bu, Tianzhao, Zhang, Chi, Wang, Zhong Lin. Tribovoltaic Effect on Metal-Semiconductor Interface for Direct-Current Low-Impedance Triboelectric Nanogenerators. ADVANCED ENERGY MATERIALS[J]. 2020, 10(9): https://www.webofscience.com/wos/woscc/full-record/WOS:000510060400001.
[15] Jiang, Dongdong, Liu, Guoxu, Li, Wenjian, Bu, Tiaozhao, Wang, Yipu, Zhang, Zhi, Pang, Yaokun, Xu, Shaohang, Yang, Hang, Zhang, Chi. A Leaf-Shaped Triboelectric Nanogenerator for Multiple Ambient Mechanical Energy Harvesting. IEEE TRANSACTIONS ON POWER ELECTRONICS[J]. 2020, 35(1): 25-32, https://www.webofscience.com/wos/woscc/full-record/WOS:000506165200006.
[16] Zhao, Junqing, Bu, Tianzhao, Zhang, Xiaohan, Pang, Yaokun, Li, Wenjian, Zhang, Zhi, Liu, Guoxu, Wang, Zhong Lin, Zhang, Chi. Intrinsically Stretchable Organic-Tribotronic-Transistor for Tactile Sensing. RESEARCH[J]. 2020, 2020(1): 60-69, http://dx.doi.org/10.34133/2020/1398903.
[17] Zhang, Zhi, Liu, Zhongyi, Fang, Haisheng. Influences of growth parameters on the reaction pathway during GaN synthesis. JOURNAL OF CRYSTAL GROWTH[J]. 2018, 482: 44-55, http://dx.doi.org/10.1016/j.jcrysgro.2017.11.002.
[18] Zhang, Zhi, Pan, Yang, Yang, Jiuzhong, Jiang, Zhiming, Fang, Haisheng. Experimental study of trimethyl aluminum decomposition. JOURNAL OF CRYSTAL GROWTH[J]. 2017, 473: 6-10, http://dx.doi.org/10.1016/j.jcrysgro.2017.05.020.
[19] Zheng, Jiang, Fang, Haisheng, Zhang, Zhi, Yang, Jinzhe, Gan, Zhiyin, Yan, Han. Uniformity analysis of temperature distribution in an industrial MOCVD reactor. CRYSTAL RESEARCH AND TECHNOLOGY[J]. 2016, 51(10): 617-626, https://www.webofscience.com/wos/woscc/full-record/WOS:000388510800010.
[20] Zhang, Zhi, Fang, Haisheng, Yao, Qingxia, Yan, Han, Gan, Zhiyin. Species transport and chemical reaction in a MOCVD reactor and their influence on the GaN growth uniformity. JOURNAL OF CRYSTAL GROWTH[J]. 2016, 454: 87-95, http://dx.doi.org/10.1016/j.jcrysgro.2016.09.010.
[21] Jiang, Zhimin, Yan, Han, Liu, Sheng, Zhang, Zhi, Gan, Zhiyin, Fang, Haisheng. Uniformity investigation of MOCVD-grown LED layers. CRYSTAL RESEARCH AND TECHNOLOGY[J]. 2016, 51(1): 30-40, https://www.webofscience.com/wos/woscc/full-record/WOS:000368703100005.
[22] Wang, S, Fang, H S, Zhao, C J, Zhang, Z, Zhang, M J, Xu, J F. Gas flow optimization during the cooling of multicrystalline silicon ingot. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2015, 84: 370-375, http://dx.doi.org/10.1016/j.ijheatmasstransfer.2015.01.035.
[23] Hu, Shaolin, Liu, Sheng, Zhang, Zhi, Yan, Han, Gan, Zhiyin, Fang, Haisheng. A novel MOCVD reactor for growth of high-quality GaN-related LED layers. JOURNAL OF CRYSTAL GROWTH[J]. 2015, 415: 72-77, http://dx.doi.org/10.1016/j.jcrysgro.2014.12.038.
[24] Zhang, Zhi, Fang, Haisheng, Yan, Han, Jiang, Zhimin, Zheng, Jiang, Gan, Zhiyin. Influencing factors of GaN growth uniformity through orthogonal test analysis. APPLIED THERMAL ENGINEERING[J]. 2015, 91: 53-61, http://dx.doi.org/10.1016/j.applthermaleng.2015.08.007.
[25] Jin, Z L, Fang, H S, Yang, N, Zhang, Z, Wang, S, Xu, J F. Influence of temperature-dependent thermophysical properties of sapphire on the modeling of Kyropoulos cooling process. JOURNAL OF CRYSTAL GROWTH[J]. 2014, 405: 52-58, http://dx.doi.org/10.1016/j.jcrysgro.2014.07.049.
[26] Fang, Haisheng, Zhang, Zhi, Pan, Yaoyu, Ma, Ronghui, Liu, Sheng, Wang, Mengying. Systematic study of epitaxy growth uniformity in a specific MOCVD reactor. CRYSTAL RESEARCH AND TECHNOLOGY[J]. 2014, 49(11): 907-918, https://www.webofscience.com/wos/woscc/full-record/WOS:000344917400010.
[27] Fang, HaiSheng, Zhang, Zhi, Jin, Zelin, Wang, Sen, Xu, JianFeng. Characteristics of melt convection during Kyropoulos sapphire crystal growth. INTERNATIONAL JOURNAL OF MATERIALS RESEARCH[J]. 2014, 105(10): 961-967, https://www.webofscience.com/wos/woscc/full-record/WOS:000343877200003.
[28] Fang, H S, Jin, Z L, Zhang, M J, Zhang, Z, Zhao, C J. Role of internal radiation at the different growth stages of sapphire by Kyropoulos method. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2013, 67: 967-973, http://dx.doi.org/10.1016/j.ijheatmasstransfer.2013.08.074.
[2] Cao, Jie, Lin, Yuan, Fu, Xianpeng, Wang, Zheng, Liu, Guoxu, Zhang, Zhi, Qin, Yuhan, Zhou, Han, Dong, Sicheng, Cheng, Guanggui, Zhang, Chi, Ding, Jianning. Self-powered overspeed wake-up alarm system based on triboelectric nanogenerators for intelligent transportation. NANO ENERGY[J]. 2023, 107: http://dx.doi.org/10.1016/j.nanoen.2022.108150.
[3] Dong, Sicheng, Bu, Tianzhao, Wang Zhaozheng, Feng Yuan, Liu Guoxu, Zeng Jianhua, Wang Zhihao, Cao Jie, Zhang Zhi, Liu Feng, Zhang Chi. Freestanding-Mode Tribovoltaic Nanogenerator for Harvesting Sliding and Rotational Mechanical Energy. Advanced Energy Materials[J]. 2023, 13(16): https://onlinelibrary.wiley.com/doi/abs/10.1002/aenm.202300079.
[4] Beibei Fan, Guoxu Liu, Xianpeng Fu, Zhaozheng Wang, Zhi Zhang, Chi Zhang. Composite film with hollow hierarchical silica/perfluoropolyether filler and surface etching for performance enhanced triboelectric nanogenerators. CHEMICAL ENGINEERING JOURNAL. 2022, 446: http://dx.doi.org/10.1016/j.cej.2022.137263.
[5] Yuan Lin, Youchao Qi, Jiaqi Wang, Guoxu Liu, Zhaozheng Wang, Junqing Zhao, Yi Lv, Zhi Zhang, Ning Tian, Mengbi Wang, Yuanfen Chen, Chi Zhang, Stefano Lenci. Self-Powered and Autonomous Vibrational Wake-Up System Based on Triboelectric Nanogenerators and MEMS Switch. SENSORS (BASEL, SWITZERLAND). 2022, 22(10): https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9145876/.
[6] Wang, Zhaozheng, Zhang, Zhi, Chen, Yunkang, Gong, Likun, Dong, Sicheng, Zhou, Han, Lin, Yuan, Lv, Yi, Liu, Guoxu, Zhang, Chi. Achieving an ultrahigh direct-current voltage of 130 V by semiconductor heterojunction power generation based on the tribovoltaic effect. ENERGY & ENVIRONMENTAL SCIENCE[J]. 2022, 15(6): 2366-2373, http://dx.doi.org/10.1039/d2ee00180b.
[7] Chen, Yunkang, Zhang, Zhi, Wang, Zhaozheng, Bu, Tianzhao, Dong, Sicheng, Wei, Wenwang, Chen, Zhiqiang, Lin, Yuan, Lv, Yi, Zhou, Han, Sun, Wenhong, Zhang, Chi. Friction-Dominated Carrier Excitation and Transport Mechanism for GaN-Based Direct-Current Triboelectric Nanogenerators. ACS APPLIED MATERIALS & INTERFACES[J]. 2022, 14(20): 24020-24027, http://dx.doi.org/10.1021/acsami.2c03853.
[8] Cao, Jie, Fu, Xianpeng, Zhu, Hao, Qu, Zhaoqi, Qi, Youchao, Zhang, Zhi, Zhang, Zhongqiang, Cheng, Guanggui, Zhang, Chi, Ding, Jianning. Self-Powered Non-Contact Motion Vector Sensor for Multifunctional Human-Machine Interface. SMALL METHODS[J]. 2022, 6(8): http://dx.doi.org/10.1002/smtd.202200588.
[9] Qi, Youchao, Liu, Guoxu, Bu, Tianzhao, Zeng, Jianhua, Zhang, Zhi, Zhang, Chi. Ferromagnetic-Based Charge-Accumulation Triboelectric Nanogenerator With Ultrahigh Surface Charge Density. SMALL[J]. 2022, 18(31): http://dx.doi.org/10.1002/smll.202201754.
[10] Zhang, Zhi, Wang, Zhaozheng, Chen, Yunkang, Feng, Yuan, Dong, Sicheng, Zhou, Han, Wang, Zhong Lin, Zhang, Chi. Semiconductor Contact-Electrification-Dominated Tribovoltaic Effect for Ultrahigh Power Generation. ADVANCED MATERIALS[J]. 2022, 34(20): http://dx.doi.org/10.1002/adma.202200146.
[11] Wang, Zhaozheng, Gong, Likun, Dong, Sicheng, Fan, Beibei, Feng, Yuan, Zhang, Zhi, Zhang, Chi. A humidity-enhanced silicon-based semiconductor tribovoltaic direct-current nanogenerator. JOURNAL OF MATERIALS CHEMISTRY A[J]. 2022, 10(47): 25230-25237, [12] Xie, Yuanyuan, Zhang, Zhi, Zhou, Han, Wang, Zhaozheng, Lin, Yuan, Chen, Yunkang, Lv, Yi, Chen, Yuanfen, Zhang, Chi. Multisource Energy Harvester with Coupling Structure and Multiplexing Mechanism. ADVANCED MATERIALS INTERFACES[J]. 2022, 9(16): http://dx.doi.org/10.1002/admi.202200468.
[13] Zhang, Zhi, He, T, Zhao, J, Liu, G, Wang, Z L, Zhang, C. Tribo-thermoelectric and tribovoltaic coupling effect at metal-semiconductor interface. MATERIALS TODAY PHYSICS[J]. 2021, 16: http://dx.doi.org/10.1016/j.mtphys.2020.100295.
[14] Zhang, Zhi, Jiang, Dongdong, Zhao, Junqing, Liu, Guoxu, Bu, Tianzhao, Zhang, Chi, Wang, Zhong Lin. Tribovoltaic Effect on Metal-Semiconductor Interface for Direct-Current Low-Impedance Triboelectric Nanogenerators. ADVANCED ENERGY MATERIALS[J]. 2020, 10(9): https://www.webofscience.com/wos/woscc/full-record/WOS:000510060400001.
[15] Jiang, Dongdong, Liu, Guoxu, Li, Wenjian, Bu, Tiaozhao, Wang, Yipu, Zhang, Zhi, Pang, Yaokun, Xu, Shaohang, Yang, Hang, Zhang, Chi. A Leaf-Shaped Triboelectric Nanogenerator for Multiple Ambient Mechanical Energy Harvesting. IEEE TRANSACTIONS ON POWER ELECTRONICS[J]. 2020, 35(1): 25-32, https://www.webofscience.com/wos/woscc/full-record/WOS:000506165200006.
[16] Zhao, Junqing, Bu, Tianzhao, Zhang, Xiaohan, Pang, Yaokun, Li, Wenjian, Zhang, Zhi, Liu, Guoxu, Wang, Zhong Lin, Zhang, Chi. Intrinsically Stretchable Organic-Tribotronic-Transistor for Tactile Sensing. RESEARCH[J]. 2020, 2020(1): 60-69, http://dx.doi.org/10.34133/2020/1398903.
[17] Zhang, Zhi, Liu, Zhongyi, Fang, Haisheng. Influences of growth parameters on the reaction pathway during GaN synthesis. JOURNAL OF CRYSTAL GROWTH[J]. 2018, 482: 44-55, http://dx.doi.org/10.1016/j.jcrysgro.2017.11.002.
[18] Zhang, Zhi, Pan, Yang, Yang, Jiuzhong, Jiang, Zhiming, Fang, Haisheng. Experimental study of trimethyl aluminum decomposition. JOURNAL OF CRYSTAL GROWTH[J]. 2017, 473: 6-10, http://dx.doi.org/10.1016/j.jcrysgro.2017.05.020.
[19] Zheng, Jiang, Fang, Haisheng, Zhang, Zhi, Yang, Jinzhe, Gan, Zhiyin, Yan, Han. Uniformity analysis of temperature distribution in an industrial MOCVD reactor. CRYSTAL RESEARCH AND TECHNOLOGY[J]. 2016, 51(10): 617-626, https://www.webofscience.com/wos/woscc/full-record/WOS:000388510800010.
[20] Zhang, Zhi, Fang, Haisheng, Yao, Qingxia, Yan, Han, Gan, Zhiyin. Species transport and chemical reaction in a MOCVD reactor and their influence on the GaN growth uniformity. JOURNAL OF CRYSTAL GROWTH[J]. 2016, 454: 87-95, http://dx.doi.org/10.1016/j.jcrysgro.2016.09.010.
[21] Jiang, Zhimin, Yan, Han, Liu, Sheng, Zhang, Zhi, Gan, Zhiyin, Fang, Haisheng. Uniformity investigation of MOCVD-grown LED layers. CRYSTAL RESEARCH AND TECHNOLOGY[J]. 2016, 51(1): 30-40, https://www.webofscience.com/wos/woscc/full-record/WOS:000368703100005.
[22] Wang, S, Fang, H S, Zhao, C J, Zhang, Z, Zhang, M J, Xu, J F. Gas flow optimization during the cooling of multicrystalline silicon ingot. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2015, 84: 370-375, http://dx.doi.org/10.1016/j.ijheatmasstransfer.2015.01.035.
[23] Hu, Shaolin, Liu, Sheng, Zhang, Zhi, Yan, Han, Gan, Zhiyin, Fang, Haisheng. A novel MOCVD reactor for growth of high-quality GaN-related LED layers. JOURNAL OF CRYSTAL GROWTH[J]. 2015, 415: 72-77, http://dx.doi.org/10.1016/j.jcrysgro.2014.12.038.
[24] Zhang, Zhi, Fang, Haisheng, Yan, Han, Jiang, Zhimin, Zheng, Jiang, Gan, Zhiyin. Influencing factors of GaN growth uniformity through orthogonal test analysis. APPLIED THERMAL ENGINEERING[J]. 2015, 91: 53-61, http://dx.doi.org/10.1016/j.applthermaleng.2015.08.007.
[25] Jin, Z L, Fang, H S, Yang, N, Zhang, Z, Wang, S, Xu, J F. Influence of temperature-dependent thermophysical properties of sapphire on the modeling of Kyropoulos cooling process. JOURNAL OF CRYSTAL GROWTH[J]. 2014, 405: 52-58, http://dx.doi.org/10.1016/j.jcrysgro.2014.07.049.
[26] Fang, Haisheng, Zhang, Zhi, Pan, Yaoyu, Ma, Ronghui, Liu, Sheng, Wang, Mengying. Systematic study of epitaxy growth uniformity in a specific MOCVD reactor. CRYSTAL RESEARCH AND TECHNOLOGY[J]. 2014, 49(11): 907-918, https://www.webofscience.com/wos/woscc/full-record/WOS:000344917400010.
[27] Fang, HaiSheng, Zhang, Zhi, Jin, Zelin, Wang, Sen, Xu, JianFeng. Characteristics of melt convection during Kyropoulos sapphire crystal growth. INTERNATIONAL JOURNAL OF MATERIALS RESEARCH[J]. 2014, 105(10): 961-967, https://www.webofscience.com/wos/woscc/full-record/WOS:000343877200003.
[28] Fang, H S, Jin, Z L, Zhang, M J, Zhang, Z, Zhao, C J. Role of internal radiation at the different growth stages of sapphire by Kyropoulos method. INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER[J]. 2013, 67: 967-973, http://dx.doi.org/10.1016/j.ijheatmasstransfer.2013.08.074.
科研活动
科研项目
( 1 ) 半导体界面摩擦伏特效应的机理与特性研究, 负责人, 国家任务, 2022-01--2024-12
( 2 ) 高性能摩擦伏特发电机的关键技术研究, 负责人, 地方任务, 2023-01--2024-12
( 3 ) 人体能量收集及电源管理模块设计制备研究, 参与, 国家任务, 2021-12--2024-11
( 4 ) 柔性可拉伸多功能电子皮肤关键技术研究, 参与, 地方任务, 2019-01--2020-12
( 5 ) 高品种特种光电功能玻璃关键制备技术及产业化, 参与, 国家任务, 2016-07--2020-06
( 2 ) 高性能摩擦伏特发电机的关键技术研究, 负责人, 地方任务, 2023-01--2024-12
( 3 ) 人体能量收集及电源管理模块设计制备研究, 参与, 国家任务, 2021-12--2024-11
( 4 ) 柔性可拉伸多功能电子皮肤关键技术研究, 参与, 地方任务, 2019-01--2020-12
( 5 ) 高品种特种光电功能玻璃关键制备技术及产业化, 参与, 国家任务, 2016-07--2020-06