黄河,男,玛丽居里学者,人社部高层次留学人才,澳大利亚优青(ARC DECRA),入选斯坦福大学发布全球前 2% 顶尖科学家榜单 (Top 2% of Scientists on Stanford List,2022,2023),曾入选国家级海外高层次青年项目(企业类,因个人发展而放弃),姑苏创新领军人才,江苏省双创博士,特聘教授,博导,硕士师从吴明红教授(中国工程院士),2017年8月博士毕业于香港城市大学物理与材料科学系(现材料科学与工程系)Andrey Rogach讲席教授(欧洲科学院外籍院士)课题组。随后在德国慕尼黑大学Jochen Feldmann讲席教授(德国科学院院士)从事博后工作3年。博后期间凭借在量子点优化和应用方面的工作独立获得了欧洲公认的欧盟玛丽居里个人奖学金(资助额度合超过130万人民币)。2021年3月来到苏州大学并获得包括国家自然科学基金青年科学基金项目在内的5个科研项目。累计在纳米领域发表文章42篇(第一或通讯作者文章共21篇,包括Nat Commun、4篇Angew Chem、Mater Today、Adv Sci、Chem Mater等高质量论文),论文总引用超过6900次,H因子29。
主要从事领域:光电材料的调控与器件、原位异位光谱监控与机理探究,基于钙钛矿等新型光电材料器件和应用。
期刊独立审阅人:Nature Commun, Adv Mater, ACS Nano, Chem Mater, ACS Applied Nano Materials, Langmuir, Inorganic Chemistry
2022~至今 澳XXX研究理事会评审专家
2022~至今 欧XXX研究理事会项目评审专家
2022~至今 XX大学职称评审专家
2021~至今 XX市科技局项目评审专家
研究方向
1)基于钙钛矿等新型纳米材料的器件与应用——着重探寻在发光二极管、太阳能电池和催化领域的应用。
苏州作为光电子产业聚集地,有诸多相关公司。我们课题组以新型钙钛矿材料为出发点,探寻新型材料的光学特性。
2)纳米材料的光学监控与机理探究:
通过自主搭建的不同的光学监控手段,对钙钛矿的生长过程、反应机理进行探究。并利用所获得的知识计划开发新型光电材料。
3)介孔材料的应用与优化:
开发适合增强钙钛矿材料稳定性的包覆的介孔材料,并利用介孔材料优化钙钛矿。
博士:谢金峰
博士交换生:张建恩(河北大学)
硕士:
2023级—韩雨洁,汤文韬,杜海琼
2024级—汪璟,刘振业
2025级—吴云乐,任昊然,李润庭,琚润铠
本科导师制:
2024届:黄登明(升学-北京理工大学光电学院)、汤健、张雅丽(升学-南京大学)、刘振业(升学-苏州大学本课题组硕士);
2025届:崔毓栋(升学-上海航天八院);
2026届:吴静雯、纪超然、陈志涛、王博伟、龙忠翔
2027届:唐俊麟、赵梦哲、施文翔
2028届:
毕业生:
2025届—谢秀慧,梅承佳,马腾,刘峻(苏州大学优秀毕业研究生)
2024届—曾颖(国家奖学金获得者)、钱庆一、倪传鑫
博士交换生:Anna Vedernikova(俄罗斯总统奖学金获得者)
硕士交换生:Danila A. Tatarinov (俄罗斯总统奖学金获得者)(圣光机大学-博士)
2024届—黄登明(升学-北京理工大学光电学院)、张雅丽(升学-南京大学硕士)、刘振业(升学-苏州大学本课题组硕士);
2023届—袁苏毓、黄水娟、吴宇浩、刘宇轩、曹宇(苏州大学-硕士)、周雨星、韦彬彬、张宇婷、严蓓
2022届—章隽辰、陈欣(南京理工大学硕士)、董黎竹(南京邮电大学-硕士)、李阁阁、翁婧、许梦瑶、王乔(上海理工大学-硕士)、陈曦
苏州市外籍院士工作站 (Andrey Rogach)
国际联合实验室 (Suda-ITMO)
入职苏大后(倒序):
12.Jun Liu, Jianen Zhang, Qi Xue,* Huiying Gao, Shirui Zhang, Jinfeng Xie, Li Guan, Xiaohong Zhang,* He Huang* Hydration-mediated morphological and electronic tuning in layered double perovskites for p-type transparent conductors, Matter, 2025, https://doi.org/10.1016/j.matt.2025.102478.
11.Gao Huiying, Xie Jinfeng, Zhang Shirui, Mei Chengjia, Liu Jun, Du Haiqiong, Zhao Chengsi, Ni Weihai, Huang He*, Xue Qi* Non-metal anion doping construction of the durable cathode with optimized oxygen vacancies in aqueous zinc-ion batteries.Nano Research Energy, 2025, https://doi.org/10.26599/NRE.2025.9120182
10.Jun Liu; Anna A. Vedernikova; Qi Xue*; Huiying Gao; Xiuhui Xie; Jinfeng Xie; Elena V Ushakova; He Huang*; Xiaohong Zhang*, Interfacial Structural Transformation for the Synthesis of Lead-Free Double Perovskite Nanocrystals, Advanced Science, 2025, 2416046, http://doi.org/10.1002/advs.202416046.
9.马腾#,谢金峰#,张世瑞,杜海琼,赵成思,薛琪*,黄河*超声驱动水油两相中绿色合成高稳定性CsPbBr3@MS-SiO2复合材料[J/OL]. 液晶与显示, 2025,1-11. DOI: 10.37188/CJLCD.2025-009
8.Anna A. Vedernikova; Mikhail D. Miruschenko; Irina A. Arefina; Jinfeng Xie; He Huang; Aleksandra V. Koroleva; Evgeniy V. Zhizhin; Sergei A. Cherevkov; Alexander S. Timin; Kseniya A. Mitusova; Sergei A. Shipilovskikh; Elena V. Ushakova*, Green and Red Emissive N,O-Doped Chiral Carbon Dots Functionalized with l-Cysteine, Journal of Physical Chemistry Letters, 2024, 15, 1, 113–120.
7.Yuliya A. Timkina; Ivan D. Skurlov; Danila A. Tatarinov; Elizaveta A. Batueva; Azat O. Ismagilov; Natalya K. Kuzmenko; Aleksandra V. Koroleva; Evgeniy V. Zhizhin; Jinfeng Xie;
He Huang; Elena V. Ushakova; Aleksandr P. Litvin*, Strong circularly polarized photoluminescence from mixed halide perovskite nanocrystals induced by anion-assisted chirality imprinting, Journal of Luminescence, 2024, 275, 120817.
6.Danila A. Tatarinov; Jinfeng Xie; Qingyi Qian; Qingqing Wang; Nadezhda A. Maslova; Lyubov N. Borodina; Aleksandr P. Litvin*; He Huang*, In-situ Post-Synthetic Treatment of CsPbBr3 Perovskite Nanocrystals in Nanoporous Silica Microspheres, Chinese Journal of Chemistry, 2024, 42 (22), 2779–2787.
5.Qingqing Wang; Jinfeng Xie; He Huang*; Weihai Ni; Qi Xue*; Enhanced ambient-stability and charge transport property of the CsPbBr3@Polyaniline, Journal of Luminescence, 2024, 275, 120770.
4.Chuanxin Ni; Jinfeng Xie; Qi Xue*; Ying Zeng; Qingyi Qian; Qingqing Wang; He Huang*, Water-induced controllable synthesis of CsPbBr3 nanorods/nanocubes from CsBr nanocrystals, Journal of Materials Chemistry C, 2024, 12, 11948-11954.
3.Jinfeng Xie; Linzhong Wu; Muhan Cao*; Qixuan Zhong; Ying Zeng; Chuanxin Ni; Qingyi Qian; Xiaohong Zhang*; He Huang*; Efficient Interfacial Synthesis Strategy for Perovskite CsPbBr3 Nanorods in the Biphase Solution, Advanced Materials Technologies, 2022, 7, 2200131.
2.Ying Zeng; Jinfeng Xie; Qi Xue*; Chuanxin Ni; Qingyi Qian; Yuxiang Guan; He Huang*; The synthesis of metal halide perovskite nanocrystals: surface and interface engineering, CrystEngComm, 2022,24, 7345-7359.
1.Linzhong Wu; Yiou Wang; Mariam Kurashvili; Amrita Dey; Muhan Cao; Markus Döblinger; Qiao Zhang*; Jochen Feldmann; He Huang*; Tushar Debnath*; Interfacial Manganese-doping in CsPbBr3 Nanoplatelets by Employing a Molecular Shuttle, Angewandte Chemie International Edition, 2022, 134, e202115.
Growth Mechanism of Strongly Emitting CH3NH3PbBr3 Perovskite Nanocrystals with a Tunable Band Gap. H. Huang, J. Raith, S. V. Kershaw, S. Kalytchuk, O. Tomanec, L. Jing, A. S. Susha, R. Zboril, A. L. Rogach*. Nat. Commun.2017, 8(1), 996. (IF=12.121; Total citation=100)
Spontaneous Crystallization of Perovskite Nanocrystals in Nonpolar Organic Solvents: A Versatile Approach for their Shape-controlled Synthesis. H. Huang,* Y. Li, Y. Tong, E.-P. Yao, M. Döblinger, M. W. Feil, A. F. Richter, A. L. Rogach, J. Feldmann, and L. Polavarapu*. Angew. Chem. Int. Ed. 2019, 58(46), 16558-16562(IF=12.959; Total citation=41)
Revealing the formation mechanism of CsPbBr3 perovskite nanocrystals produced via a slowed-down microwave assisted synthesis. Y. Li, H. Huang*,Y. Xiong, S. V. Kershaw, A. L. Rogach*. Angew. Chem. Int. Ed. 2018, 57(20), 5833-5837 (IF=12.959; Total citation=56)
Top-Down Fabrication of Stable Methylammonium Lead Halide Perovskite Nanocrystals Employing a Mixture of Ligands as Coordinating Solvents. He Huang, Qi Xue, Bingkun Chen, Yuan Xiong, Julian Schneider, Chunyi Zhi, Haizheng Zhong, Andrey L. Rogach*. Angew. Chem. Int. Ed. 2017, 56 (32), 9571-9576 (IF=12.959; Total citation=83)
5. Advances in metal halide perovskite nanocrystals: Synthetic strategies, growth mechanisms, and optoelectronic applications. Y Li, X Zhang, H. Huang,* S. V. Kershaw, A. L. Rogach*. Mater. Today 2020, 32, 204 (IF=26.416; Total citation=28)
Lead Halide Perovskite Nanocrystals in the Research Spotlight: Stability and Defect Tolerance. H. Huang, M. I. Bodnarchuk, S. V. Kershaw, M. V. Kovalenko, A. L. Rogach*. ACS Energy Lett. 2017, 2(9), 2071−2083(IF=19.003; Total citation=405) (ISI highly cited paper)
Control of Emission Color of High Quantum Yield CH3NH3PbBr3 Perovskite Quantum Dots by Precipitation Temperature. H. Huang, A. S. Susha, S. V. Kershaw, T. F. Hung, A. L. Rogach*. Adv. Sci. 2015, 2 (9), 1500194. (IF=15.84; Total citation=390) (ISI highly cited paper)
Growth of Perovskite CsPbBr3 Nanocrystals and Their Formed Superstructures Revealed by In-situ Spectroscopy. H. Huang* Maximilian W. Feil, Simon Fuchs, Tushar Debnath, Alexander F. Richter, Yu Tong, Linzhong Wu, Yiou Wang, Markus Döblinger, and Bert Nickel, Chem. Mater. 2020, 32, 8877-8884 ((IF=9.567; Highlight as cover paper)
Water Resistant CsPbX3 Nanocrystals Coated with Polyhedral Oligomeric Silsesquioxane and Their Use as Solid State Luminophores in All-Perovskite White Light-Emitting Devices. H. Huang, B. Chen, Z. Wang, T. F. Hung, A. S. Susha, H. Zhong; A. L. Rogach*. Chem. Sci. 2016, 7 (9), 5699-5703. (IF=9.346; Total citation=335) (ISI highly cited paper)
Colloidal Lead Halide Perovskite Nanocrystals: Synthesis, Optical Properties and Applications. H. Huang, L. Polavarapu, J. A. Sichert, A. S. Susha, A. S. Urban*, A. L. Rogach*. NPG Asia Mater. 2016, 8 (11), e328. (IF=8.131; Total citation=253) (ISI highly cited paper)
11. Excitons and Biexciton Dynamics in Single CsPbBr3 Perovskite Quantum Dots. B. Li#, H. Huang#, G. Zhang*, C. Yang, W. Guo, R. Chen, C. Qin, Y. Gao, V.P. Biju, A. L. Rogach, L. Xiao, S. Jia*. J. Phys. Chem. Lett. 2018, 24(9), 6934-6940(IF=6.71; Total citation=21)
Polyhedral Oligomeric Silsesquioxane Enhances the Brightness of Perovskite Nanocrystal-Based Green Light-Emitting Devices. H. Huang#, H. Lin#, S. V. Kershaw, A. S. Susha, W. C. Choy*, A. L. Rogach*. J. Phys. Chem. Lett. 2016, 7 (21), 4398-4404. (IF=6.71; Total citation=84)
Facile Synthesis of FAPbI3 Nanorods. H. Huang*, L. Wu, Y. Wang, A.F. Richter, M. Döblinger, J. Feldmann*. Nanomaterials. 2020, 10, 72(IF=4.324; Total citation=4)
Reversible transformation between CsPbBr3 and Cs4PbBr6 nanocrystals. Y. Li, H. Huang*, Y. Xiong, S. V. Kershaw, A. L. Rogach*. CrystEngComm 2018,20, 4900-4904 (IF=3.117; Total citation=17)
1、招收硕士生、博士生
2、招聘半导体微纳材料、光电器件等方向的博士后,提供具有竞争力的薪酬待遇
3、欢迎本科生参加科研,提供相关帮助
4、欢迎感兴趣的同学与我联系交流,来组参观学习,热忱期待你的加入!
诚聘博后
研究方向
1)纳米材料的合成调控、原位异位监控和机理探究:针对钙钛矿的合成特性,通过不同的监控手段,对钙钛矿的生长过程、反应机理进行探究。同时计划开发新型光电材料。
2)介孔材料的合成与优化:合成适合钙钛矿包覆的介孔材料,并利用介孔材料优化钙钛矿
3)基于钙钛矿等新型纳米材料器件和应用:尤其是在发光二极管和催化领域的应用
博士后岗位要求
1. 有强烈的工作责任心、团队合作精神和奉献精神,具备较强的协调沟通能力,按课题组计划开展工作;
2. 博士毕业三年内或即将毕业,具有合成化学/光化学/材料/物理化学等交叉领域其中任一相关专业背景;
3. 具有较好的英文阅读与写作能力,以第一作者身份发表过高水平学术论文;
4. 具有较强的独立科研能力,具备较强的分析问题和解决问题的能力;
5. 具备良好的团队合作精神和浓厚的科研兴趣;
岗位待遇
博士后研究期间待遇按《苏州大学博士后管理工作条例》规定执行,此外课题组再提供具有竞争力的其他待遇。统招博士后实行协议年薪制(三年期统招博士后人员聘期内的总薪酬由基本年薪和奖补金两部分构成。绩效评估优秀者的总薪酬为100万元,绩效评估良好者的总薪酬为80万元,绩效评估合格者的总薪酬为60万元);学校为博士后按教职工待遇缴纳五险一金(不计入总年薪),享受教职工福利;学校给予租房补贴1000元/月(不计入总年薪);科研成果可享受学校与组内科研奖励(不计入总年薪);可支持优秀候选人申请博新计划或特别资助(薪酬可叠加);支持申报国家博士后科学基金、国家自然科学基金青年项目、江苏省各项基金等;在站工作表现优异者,出站后可根据研究资历,可竞聘苏大正式的讲师或副教授岗位。
本课题组与慕尼黑大学、香港城市大学等在内的课题组已建立长期的合作交流关系,可推荐国内外知名课题组进行进修和联合培养。目前已经与香港城市大学某课题组达成联培协议。
请将详细的个人简历(包括个人联系方式,学习研究工作经历,前期主要研究基础,代表论文等)发送到电子邮箱:hh@suda.edu.cn,电子邮件标题请注明:姓名+现单位+博士后申请。收到会及时回复并要求后续的推荐信或推荐人联系方式。招满为止(若招满,会第一时间告知后续投简历者)
黄河,男,玛丽居里学者,人社部高层次留学人才,澳大利亚优青(ARC DECRA),入选斯坦福大学发布全球前 2% 顶尖科学家榜单 (Top 2% of Scientists on Stanford List,2022,2023),曾入选国家级海外高层次青年项目(企业类,因个人发展而放弃),姑苏创新领军人才,江苏省双创博士,特聘教授,博导,硕士师从吴明红教授(中国工程院士),2017年8月博士毕业于香港城市大学物理与材料科学系(现材料科学与工程系)Andrey Rogach讲席教授(欧洲科学院外籍院士)课题组。随后在德国慕尼黑大学Jochen Feldmann讲席教授(德国科学院院士)从事博后工作3年。博后期间凭借在量子点优化和应用方面的工作独立获得了欧洲公认的欧盟玛丽居里个人奖学金(资助额度合超过130万人民币)。2021年3月来到苏州大学并获得包括国家自然科学基金青年科学基金项目在内的5个科研项目。累计在纳米领域发表文章42篇(第一或通讯作者文章共21篇,包括Nat Commun、4篇Angew Chem、Mater Today、Adv Sci、Chem Mater等高质量论文),论文总引用超过6900次,H因子29。
主要从事领域:光电材料的调控与器件、原位异位光谱监控与机理探究,基于钙钛矿等新型光电材料器件和应用。
期刊独立审阅人:Nature Commun, Adv Mater, ACS Nano, Chem Mater, ACS Applied Nano Materials, Langmuir, Inorganic Chemistry
2022~至今 澳XXX研究理事会评审专家
2022~至今 欧XXX研究理事会项目评审专家
2022~至今 XX大学职称评审专家
2021~至今 XX市科技局项目评审专家
研究方向
1)基于钙钛矿等新型纳米材料的器件与应用——着重探寻在发光二极管、太阳能电池和催化领域的应用。
苏州作为光电子产业聚集地,有诸多相关公司。我们课题组以新型钙钛矿材料为出发点,探寻新型材料的光学特性。
2)纳米材料的光学监控与机理探究:
通过自主搭建的不同的光学监控手段,对钙钛矿的生长过程、反应机理进行探究。并利用所获得的知识计划开发新型光电材料。
3)介孔材料的应用与优化:
开发适合增强钙钛矿材料稳定性的包覆的介孔材料,并利用介孔材料优化钙钛矿。
博士:谢金峰
博士交换生:张建恩(河北大学)
硕士:
2023级—韩雨洁,汤文韬,杜海琼
2024级—汪璟,刘振业
2025级—吴云乐,任昊然,李润庭,琚润铠
本科导师制:
2024届:黄登明(升学-北京理工大学光电学院)、汤健、张雅丽(升学-南京大学)、刘振业(升学-苏州大学本课题组硕士);
2025届:崔毓栋(升学-上海航天八院);
2026届:吴静雯、纪超然、陈志涛、王博伟、龙忠翔
2027届:唐俊麟、赵梦哲、施文翔
2028届:
毕业生:
2025届—谢秀慧,梅承佳,马腾,刘峻(苏州大学优秀毕业研究生)
2024届—曾颖(国家奖学金获得者)、钱庆一、倪传鑫
博士交换生:Anna Vedernikova(俄罗斯总统奖学金获得者)
硕士交换生:Danila A. Tatarinov (俄罗斯总统奖学金获得者)(圣光机大学-博士)
2024届—黄登明(升学-北京理工大学光电学院)、张雅丽(升学-南京大学硕士)、刘振业(升学-苏州大学本课题组硕士);
2023届—袁苏毓、黄水娟、吴宇浩、刘宇轩、曹宇(苏州大学-硕士)、周雨星、韦彬彬、张宇婷、严蓓
2022届—章隽辰、陈欣(南京理工大学硕士)、董黎竹(南京邮电大学-硕士)、李阁阁、翁婧、许梦瑶、王乔(上海理工大学-硕士)、陈曦
苏州市外籍院士工作站 (Andrey Rogach)
国际联合实验室 (Suda-ITMO)
入职苏大后(倒序):
12.Jun Liu, Jianen Zhang, Qi Xue,* Huiying Gao, Shirui Zhang, Jinfeng Xie, Li Guan, Xiaohong Zhang,* He Huang* Hydration-mediated morphological and electronic tuning in layered double perovskites for p-type transparent conductors, Matter, 2025, https://doi.org/10.1016/j.matt.2025.102478.
11.Gao Huiying, Xie Jinfeng, Zhang Shirui, Mei Chengjia, Liu Jun, Du Haiqiong, Zhao Chengsi, Ni Weihai, Huang He*, Xue Qi* Non-metal anion doping construction of the durable cathode with optimized oxygen vacancies in aqueous zinc-ion batteries.Nano Research Energy, 2025, https://doi.org/10.26599/NRE.2025.9120182
10.Jun Liu; Anna A. Vedernikova; Qi Xue*; Huiying Gao; Xiuhui Xie; Jinfeng Xie; Elena V Ushakova; He Huang*; Xiaohong Zhang*, Interfacial Structural Transformation for the Synthesis of Lead-Free Double Perovskite Nanocrystals, Advanced Science, 2025, 2416046, http://doi.org/10.1002/advs.202416046.
9.马腾#,谢金峰#,张世瑞,杜海琼,赵成思,薛琪*,黄河*超声驱动水油两相中绿色合成高稳定性CsPbBr3@MS-SiO2复合材料[J/OL]. 液晶与显示, 2025,1-11. DOI: 10.37188/CJLCD.2025-009
8.Anna A. Vedernikova; Mikhail D. Miruschenko; Irina A. Arefina; Jinfeng Xie; He Huang; Aleksandra V. Koroleva; Evgeniy V. Zhizhin; Sergei A. Cherevkov; Alexander S. Timin; Kseniya A. Mitusova; Sergei A. Shipilovskikh; Elena V. Ushakova*, Green and Red Emissive N,O-Doped Chiral Carbon Dots Functionalized with l-Cysteine, Journal of Physical Chemistry Letters, 2024, 15, 1, 113–120.
7.Yuliya A. Timkina; Ivan D. Skurlov; Danila A. Tatarinov; Elizaveta A. Batueva; Azat O. Ismagilov; Natalya K. Kuzmenko; Aleksandra V. Koroleva; Evgeniy V. Zhizhin; Jinfeng Xie;
He Huang; Elena V. Ushakova; Aleksandr P. Litvin*, Strong circularly polarized photoluminescence from mixed halide perovskite nanocrystals induced by anion-assisted chirality imprinting, Journal of Luminescence, 2024, 275, 120817.
6.Danila A. Tatarinov; Jinfeng Xie; Qingyi Qian; Qingqing Wang; Nadezhda A. Maslova; Lyubov N. Borodina; Aleksandr P. Litvin*; He Huang*, In-situ Post-Synthetic Treatment of CsPbBr3 Perovskite Nanocrystals in Nanoporous Silica Microspheres, Chinese Journal of Chemistry, 2024, 42 (22), 2779–2787.
5.Qingqing Wang; Jinfeng Xie; He Huang*; Weihai Ni; Qi Xue*; Enhanced ambient-stability and charge transport property of the CsPbBr3@Polyaniline, Journal of Luminescence, 2024, 275, 120770.
4.Chuanxin Ni; Jinfeng Xie; Qi Xue*; Ying Zeng; Qingyi Qian; Qingqing Wang; He Huang*, Water-induced controllable synthesis of CsPbBr3 nanorods/nanocubes from CsBr nanocrystals, Journal of Materials Chemistry C, 2024, 12, 11948-11954.
3.Jinfeng Xie; Linzhong Wu; Muhan Cao*; Qixuan Zhong; Ying Zeng; Chuanxin Ni; Qingyi Qian; Xiaohong Zhang*; He Huang*; Efficient Interfacial Synthesis Strategy for Perovskite CsPbBr3 Nanorods in the Biphase Solution, Advanced Materials Technologies, 2022, 7, 2200131.
2.Ying Zeng; Jinfeng Xie; Qi Xue*; Chuanxin Ni; Qingyi Qian; Yuxiang Guan; He Huang*; The synthesis of metal halide perovskite nanocrystals: surface and interface engineering, CrystEngComm, 2022,24, 7345-7359.
1.Linzhong Wu; Yiou Wang; Mariam Kurashvili; Amrita Dey; Muhan Cao; Markus Döblinger; Qiao Zhang*; Jochen Feldmann; He Huang*; Tushar Debnath*; Interfacial Manganese-doping in CsPbBr3 Nanoplatelets by Employing a Molecular Shuttle, Angewandte Chemie International Edition, 2022, 134, e202115.
Growth Mechanism of Strongly Emitting CH3NH3PbBr3 Perovskite Nanocrystals with a Tunable Band Gap. H. Huang, J. Raith, S. V. Kershaw, S. Kalytchuk, O. Tomanec, L. Jing, A. S. Susha, R. Zboril, A. L. Rogach*. Nat. Commun.2017, 8(1), 996. (IF=12.121; Total citation=100)
Spontaneous Crystallization of Perovskite Nanocrystals in Nonpolar Organic Solvents: A Versatile Approach for their Shape-controlled Synthesis. H. Huang,* Y. Li, Y. Tong, E.-P. Yao, M. Döblinger, M. W. Feil, A. F. Richter, A. L. Rogach, J. Feldmann, and L. Polavarapu*. Angew. Chem. Int. Ed. 2019, 58(46), 16558-16562(IF=12.959; Total citation=41)
Revealing the formation mechanism of CsPbBr3 perovskite nanocrystals produced via a slowed-down microwave assisted synthesis. Y. Li, H. Huang*,Y. Xiong, S. V. Kershaw, A. L. Rogach*. Angew. Chem. Int. Ed. 2018, 57(20), 5833-5837 (IF=12.959; Total citation=56)
Top-Down Fabrication of Stable Methylammonium Lead Halide Perovskite Nanocrystals Employing a Mixture of Ligands as Coordinating Solvents. He Huang, Qi Xue, Bingkun Chen, Yuan Xiong, Julian Schneider, Chunyi Zhi, Haizheng Zhong, Andrey L. Rogach*. Angew. Chem. Int. Ed. 2017, 56 (32), 9571-9576 (IF=12.959; Total citation=83)
5. Advances in metal halide perovskite nanocrystals: Synthetic strategies, growth mechanisms, and optoelectronic applications. Y Li, X Zhang, H. Huang,* S. V. Kershaw, A. L. Rogach*. Mater. Today 2020, 32, 204 (IF=26.416; Total citation=28)
Lead Halide Perovskite Nanocrystals in the Research Spotlight: Stability and Defect Tolerance. H. Huang, M. I. Bodnarchuk, S. V. Kershaw, M. V. Kovalenko, A. L. Rogach*. ACS Energy Lett. 2017, 2(9), 2071−2083(IF=19.003; Total citation=405) (ISI highly cited paper)
Control of Emission Color of High Quantum Yield CH3NH3PbBr3 Perovskite Quantum Dots by Precipitation Temperature. H. Huang, A. S. Susha, S. V. Kershaw, T. F. Hung, A. L. Rogach*. Adv. Sci. 2015, 2 (9), 1500194. (IF=15.84; Total citation=390) (ISI highly cited paper)
Growth of Perovskite CsPbBr3 Nanocrystals and Their Formed Superstructures Revealed by In-situ Spectroscopy. H. Huang* Maximilian W. Feil, Simon Fuchs, Tushar Debnath, Alexander F. Richter, Yu Tong, Linzhong Wu, Yiou Wang, Markus Döblinger, and Bert Nickel, Chem. Mater. 2020, 32, 8877-8884 ((IF=9.567; Highlight as cover paper)
Water Resistant CsPbX3 Nanocrystals Coated with Polyhedral Oligomeric Silsesquioxane and Their Use as Solid State Luminophores in All-Perovskite White Light-Emitting Devices. H. Huang, B. Chen, Z. Wang, T. F. Hung, A. S. Susha, H. Zhong; A. L. Rogach*. Chem. Sci. 2016, 7 (9), 5699-5703. (IF=9.346; Total citation=335) (ISI highly cited paper)
Colloidal Lead Halide Perovskite Nanocrystals: Synthesis, Optical Properties and Applications. H. Huang, L. Polavarapu, J. A. Sichert, A. S. Susha, A. S. Urban*, A. L. Rogach*. NPG Asia Mater. 2016, 8 (11), e328. (IF=8.131; Total citation=253) (ISI highly cited paper)
11. Excitons and Biexciton Dynamics in Single CsPbBr3 Perovskite Quantum Dots. B. Li#, H. Huang#, G. Zhang*, C. Yang, W. Guo, R. Chen, C. Qin, Y. Gao, V.P. Biju, A. L. Rogach, L. Xiao, S. Jia*. J. Phys. Chem. Lett. 2018, 24(9), 6934-6940(IF=6.71; Total citation=21)
Polyhedral Oligomeric Silsesquioxane Enhances the Brightness of Perovskite Nanocrystal-Based Green Light-Emitting Devices. H. Huang#, H. Lin#, S. V. Kershaw, A. S. Susha, W. C. Choy*, A. L. Rogach*. J. Phys. Chem. Lett. 2016, 7 (21), 4398-4404. (IF=6.71; Total citation=84)
Facile Synthesis of FAPbI3 Nanorods. H. Huang*, L. Wu, Y. Wang, A.F. Richter, M. Döblinger, J. Feldmann*. Nanomaterials. 2020, 10, 72(IF=4.324; Total citation=4)
Reversible transformation between CsPbBr3 and Cs4PbBr6 nanocrystals. Y. Li, H. Huang*, Y. Xiong, S. V. Kershaw, A. L. Rogach*. CrystEngComm 2018,20, 4900-4904 (IF=3.117; Total citation=17)
1、招收硕士生、博士生
2、招聘半导体微纳材料、光电器件等方向的博士后,提供具有竞争力的薪酬待遇
3、欢迎本科生参加科研,提供相关帮助
4、欢迎感兴趣的同学与我联系交流,来组参观学习,热忱期待你的加入!
诚聘博后
研究方向
1)纳米材料的合成调控、原位异位监控和机理探究:针对钙钛矿的合成特性,通过不同的监控手段,对钙钛矿的生长过程、反应机理进行探究。同时计划开发新型光电材料。
2)介孔材料的合成与优化:合成适合钙钛矿包覆的介孔材料,并利用介孔材料优化钙钛矿
3)基于钙钛矿等新型纳米材料器件和应用:尤其是在发光二极管和催化领域的应用
博士后岗位要求
1. 有强烈的工作责任心、团队合作精神和奉献精神,具备较强的协调沟通能力,按课题组计划开展工作;
2. 博士毕业三年内或即将毕业,具有合成化学/光化学/材料/物理化学等交叉领域其中任一相关专业背景;
3. 具有较好的英文阅读与写作能力,以第一作者身份发表过高水平学术论文;
4. 具有较强的独立科研能力,具备较强的分析问题和解决问题的能力;
5. 具备良好的团队合作精神和浓厚的科研兴趣;
岗位待遇
博士后研究期间待遇按《苏州大学博士后管理工作条例》规定执行,此外课题组再提供具有竞争力的其他待遇。统招博士后实行协议年薪制(三年期统招博士后人员聘期内的总薪酬由基本年薪和奖补金两部分构成。绩效评估优秀者的总薪酬为100万元,绩效评估良好者的总薪酬为80万元,绩效评估合格者的总薪酬为60万元);学校为博士后按教职工待遇缴纳五险一金(不计入总年薪),享受教职工福利;学校给予租房补贴1000元/月(不计入总年薪);科研成果可享受学校与组内科研奖励(不计入总年薪);可支持优秀候选人申请博新计划或特别资助(薪酬可叠加);支持申报国家博士后科学基金、国家自然科学基金青年项目、江苏省各项基金等;在站工作表现优异者,出站后可根据研究资历,可竞聘苏大正式的讲师或副教授岗位。
本课题组与慕尼黑大学、香港城市大学等在内的课题组已建立长期的合作交流关系,可推荐国内外知名课题组进行进修和联合培养。目前已经与香港城市大学某课题组达成联培协议。
请将详细的个人简历(包括个人联系方式,学习研究工作经历,前期主要研究基础,代表论文等)发送到电子邮箱:hh@suda.edu.cn,电子邮件标题请注明:姓名+现单位+博士后申请。收到会及时回复并要求后续的推荐信或推荐人联系方式。招满为止(若招满,会第一时间告知后续投简历者)