赵丽霞-欧洲杯买球app官方网站

作者:电气工程学院发布时间:2021-12-12浏览次数:6763

赵丽霞

教授

博导

招生专业:电气工程、控制科学与工程、电子科学与技术

研究方向:宽禁带半导体器件及其可靠性

欧洲杯买球app官方网站的联系方式:lxzhao@tiangong.edu.cn

个人简介————————————————————————————————————————————

2005年于英国诺丁汉大学物理天文学院获得博士学位,随后到英国剑桥大学材料冶金学院gan研究中心工作,20072009年初在英国forge-europa工作,20095月加入中国科学院半导体研究所,同年入选中国科学院第一届“引进杰出技术人才”计划,是科学院青促会首批会员,2020年获中国电子学会“优秀科技工作者”荣誉称号。天津市”创新人才推进计划中青年科技创新领军人才计划”。

长期从事氮化物半导体材料、器件及可靠性方面的研究。先后主持承担科技部、国家自然科学基金委及科学院等科研项目14项。发表文章110余篇,迄今文章累计被引用2500多次;已授权发明专利22项,包括1项国际专利,负责起草国家标准5项,目前作为项目负责人正在制定一项国际标准,邀请报告20余次。目前是全国微束分析标准化技术委员会表面化学分析分技术委员会委员,天津市电气装备智能控制重点实验室主任,天津市装备制造与应用研究国际联合研究中心负责人。


主要学术论文 —————————————————————————————————————————————

[1]“a nanopillar-modified high-sensitivity asymmetric graphene–gan photodetector”, c. liux. d. lit. g. huw. k. zhuf. g. yant. s. wuk. y. wangl. x. zhao*, nanoscale, 2021, 13, 17512-17520.

[2]“high performance conical nanostructured gan-based photodetectors”, t. g. hu, x. d. li, c. liu, s. lin, k. y. wang, j. liu and l. x. zhao*, j. phys. d, 2021, 55, 035102.

[3]“cspb(br/i)3 perovskite nanocrystals for hybrid gan-based high bandwidth white light-emitting diodes”, z. h. ma, x. d. li, c. x. zhang, l. turyanska, s. lin, x. xi, j. li, t. g. hu, j. f. wang, a. patanè and l. x. zhao*, acs applied nano materials, 2021, 4, 8, 8383-8389.

[4]“the influence of point defects on algan-based deep ultraviolet leds,” z. h. ma, a. almalki, x. yang, x. wu, x. xi, j. li, s. lin, x. d. li, s. alotaibi, m. a. huwayz, m. henini and l. x. zhao*, journal of alloys and compounds2020845156177.

[5]“controllable fabrication of lateral periodic nanoporous gan and its enhanced photocatalytic water splitting performance”, x. d. li, c. yang, j. li, x. xi, z. h. ma, s. lin, l. x. zhao*, applied surface science, 2020526146618.

[6]“optical and frequency degradation behavior of gan-based micro-leds for visible light communication,”z. h. ma, h. c. cao, s. lin, x. d. li, x. xi, j. li, l. x. zhao*, optics express, 2020,28(9), 12795.

[7]“high responsivity and wavelength selectivity of gan-based resonant cavity photodiodes”, j. li, c. yang, l. liu, h. c. cao, s. lin, x. xi, x. d. li, z. h. ma, k. y. wang, a. patanè, l. x. zhao*, adv. optical mater.2020, 1901276.

[8]“ultra-high sensitivity graphene/nanoporous gan ultraviolet photodetectors”, j. li; x. xi; s. lin; z. h. ma; x. d. li; l. x. zhao*, acs applied materials and interfaces, 2020, 1211965.

[9]“ultra-high and fast ultraviolet response photodetectors based on lateral porous gan/ag nanowires composite nanostructure”, j. li, x. xi, x. d. li, s. lin, z. h. ma, h. x. xiu, l. x. zhao*, adv. optical mater.2020, 1902162.

[10]“color converted white light-emitting diodes with 637.6 mhz modulation bandwidth”h. c. cao, s. lin, z. h. ma, x. d. li j. li, l. x. zhao*, ieee electron. dev. lett., 2019, 40, 267.

[11]“degradation behavior of deep uv-leds studied by electro-optical methods and transmission electron microscopy”, h. x. xiu, y. zhang, j. j. fu, z. h. ma, l. x. zhao*,  j. j. feng*, current applied physics, 2019, 19, 20.

[12]“degradation and failure mechanism of algan-based uvc-leds”, z. h. ma, h. c. cao, s. lin, x.d. li, and l. x. zhao*, solid state electronics, 2019, 156, 92.

[13]“failure mechanism of phosphors in gan-based white leds”, z. h. ma, h. c. cao, x.j. sun, c. yang, x. xi, j. li, s. lin and l. x. zhao*, physica status solidi (a) 2019, 216(6):1800335.  

[14]“enhanced water splitting performance of gan nanowires fabricated using anode aluminum oxide templates”, x. xi, j. li, z.h. ma, x. d. li, l. x. zhao*, rsc advances, 2019, 9, 14937.

[15]“hybrid light emitting diodes based on stable, high brightness all-inorganic cspbi 3 perovskite nanocrystals and ingan”, c. x. zhang, l. turyanska, h. c. cao, l. x. zhao, m. w. fay, r. temperton, j. o'shea, n. r thomas, k. y. wang, w. l. luan, a. patanè, nanoscale, 2019, 11, 13450.

[16]“light modulation and water splitting enhancement using a composite porous gan structure”c. yang, x. xi, z. g. yu, h. c. cao, j. li, s. lin, z. h. ma, and l. x. zhao*acs applied materials and interfaces, 2018, 10, 5492.

[17]“composite degradation model and corresponding failure mechanism for mid-power gan-based white leds” h.c. cao, z. h. ma, b. j. sun, x. j. sun, c. yang, x. d. li, j. x. wang, l. x. zhao*, aip advances, 2018, 8, 035108.

[18]“gan nanocolumns fabricated by self-assembly ni mask and its enhanced photocatalytic performance in water splitting” x. xi, c. yang, h. c. cao, z. g. yu, j. li, s. lin, z. h. ma, l. x. zhao*, applied surface science, 2018, 462, 310.

[19]“modulation and optoelectronic properties of gan-based light emitting diodes on gan template”, s. lin, h. c. cao, j. li, x. j. sun, h. x. xiu, and l. x. zhao*, applied physics express, 2018, 11, 122101.

[20]“high-detectivity ultraviolet photodetectors based on laterally mesoporous gan”l. liu, c. yang, a. patanè, z. g. yu, f. g. yan, k. y. wang, h. x. lu, j. m. li and l. x. zhao*nanoscale, 2017, 9, 8142.

[21]“gan with laterally aligned nanopores to enhance the water splitting”c. yang, l. liu, s. c. zhu, z. g. yu, x. xi, s. t. wu, h. c. cao, j. m. li and l. x. zhao*, j. phys. chem. c 2017, 121, 7331.

[22]“influence of quantum confined stark effect and carrier localization effect on modulation bandwidth for gan-based leds”s. c. zhu, s. lin, j. li, h. c. cao, c. yang, j.m. li and l. x. zhao*appl. phys. lett.2017, 111, 171105.

[23]“enhancing the spontaneous emission rate by modulating carrier distribution in gan-based surface plasmon light-emitting diodes” s. c. zhu, z. g. yu, l. liu, c. yang, h. c. cao, x. xi, j. m. li and l. x. zhao*, opt. express, 2017, 25, 9617.



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