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秦光照

发布于:2019-09-22 星期日 17:28:22 点击数:562

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基本信息

姓名:秦光照
系别:能源与动力工程系
职称/职务:教授/博士生导师
电话:+86 13671054918
E-mail: gzqin@hnu.edu.cn
更多详细信息请见个人主页:http://qgz.sxl.cn/
       秦光照,男,出生于1991年11月,河南开封人。湖南大学机械与运载工程学院教授,博士生导师,岳麓学者,国家海外高层次人才计划会评入选者(2018)。曾先后在郑州大学、中国科学院、德国亚琛工业大学和美国南卡罗莱纳大学从事科研工作。博士论文获德国亚琛工业大学最佳博士论文奖(拉丁文最高荣誉学位SUMMA CUMLAUDE),同时获国家留学基金委授予的2017年度国家优秀自费留学生奖学金(全球500人/年)。此外,担任《Physical Review Letters》在内等23个知名国际期刊的特约审稿人,并获杰出审稿人奖,同时兼任留德中国物理学者学会理事。2019年9月加入湖南大学,主要从事微纳传热及先进热管理技术方面的研究工作,包括力学性质、电子结构、晶格振动、声子热输运等的第一性原理计算研究,重点关注微纳尺度能量输运与转换,聚焦于先进热管理技术中的基础科学问题的研究。
       课题组长期招聘博士后,年薪15-30万元,申请者需已经获得博士学位或即将获得博士学位,具有物理、材料、化学、机械、电子、计算机或相关专业背景,在国际主流学术刊物上以第一作者或通讯作者发表过研究论文,具有独立思考和创造性思维能力,良好的中英文阅读和写作能力,有能力指导低年级学生,并带领学生共同完成课题。
       全职博士后在站期间计算工作年限从进站之日起计算,博士后期间经评审后可认定为副研究员。在站期间成果丰富,入选湖南大学“杰出博士后奖”(每年评选一次)者,可直接申请副教授岗位。
       同时热忱欢迎有志一起发展事业的小伙伴们通过应聘湖南大学副教授(正式编制)或助理教授岗位(正式编制+非升即走)加盟课题组团队,共同奋斗美好的明天!申请者需已经获得博士学位或即将获得博士学位,并在国际主流学术期刊发表有一定数量和质量的论文,更多具体细节欢迎咨询详谈。

教育背景

2015/08 – 2018/08 德国亚琛工业大学 机械工程 (导师:胡明)
2012/09 – 2015/07 中国科学院大学 凝聚态物理
2007/09 – 2011/07 郑州大学 应用物理学

工作履历

2019/09 – 至今 湖南大学 汽车车身先进设计制造国家重点实验室 教授
2018/09 – 2019/08 美国南卡罗莱纳大学 机械工程系 博士后

学术兼职

学术期刊编辑:SCIREA Journal of Energy、SCIREA Journal of Materials
学术出版社编辑:InTech
留德中国物理学者学会(GCPD)第26届理事会理事
新媒体学术平台材料人学术委员会发起委员
美国物理协会(American Physical Society, APS)会员
美国材料协会(Materials Research Society, MRS)会员
国际会议特约审稿人
1.16th International Heat Transfer Conference(传热领域最具影响力会议)
2.International Program Committee for 2018 7th International Conference on Advanced Materials and Engineering Materials
国际SCI期刊审稿人
1. Physical Review Letters
2. Physical Review Materials
3. Physical Review Applied
4. Physical Review B
5. Nanoscale
6. ACS Applied Materials & Interfaces
7. Journal of Applied Physics
8. Scientific Reports
9. Physical Chemistry Chemical Physics
10. ChemistrySelect
11. Computational Condensed Matter
12. Physics Letters A
13. The Journal of Physical Chemistry
14. Materials and Design
15. Solid State Ionics
16. Physics and Chemistry of the Earth
17. Applied Physics Letters
18. Surface and Coatings Technology
19. ACS Applied Electronic Materials
20. Energy
21. Superlattices and Microstructures
22. Journal of Magnetism and Magnetic Materials
23. Journal of Physics: Condensed Matter

研究领域

主要研究领域与兴趣为微纳传热及先进热管理技术,包括力学性质、电子结构、晶格振动、声子热输运等的第一性原理计算研究,同时也包括分子动力学以及多尺度模拟方法的发展等,重点关注微纳尺度下的能量输运与转换,集中于传热过程中基础科学问题的研究,在中国制造2025国家战略发展规划、工程及产业化等应用中有着重要的需求,对于半导体微电子器件热管理、高效能量输运与转换、以及新型热能节能环保技术等面向国家重大需求的领域具有广泛应用。
课题组在微纳热管理领域拟开展研究方向包括但不限于以下几方面 :
1.先进热管理中的传热性能和热输运过程的调控及其机制理论研究
2.多维度复杂结构中能量输运过程的多尺度模拟与实验验证研究
3.先进热功能器件材料设计的高通量机器学习及数据驱动智能设计研究
科研团队每年招收博士生1人,硕士研究生5人,同时欢迎有科研理想的本科生入组学习,开展科研训练。热忱欢迎对纳米科技、微型系统、表面工程、芯片散热、改性调控、热电转换、新能源、电池热管理、智能材料等方向感兴趣的同学加入课题组,专业背景可以是机械、力学、物理学、电子、化学、计算机、光学、材料科学与技术、艺术设计等。课题组与美国、新加坡、德国、香港等国内外众多顶级课题组有深入合作关系,加入课题组的学生有机会获得到国际顶级机构联合培养的机会。

科研项目

FUNDING PROJECTS
1.Guangzhao Qin, Development of machine learning based interatomic potential for multiscale modeling of thermal management of electronics using Boron Arsenide (BAs), $5,000.00, 01/07/2019 – 30/09/2020, ASPIRE – I, TRACK 2, USC Office of the Vice President for Research;
COMPUTING PROJECTS
1.Guangzhao Qin and Biyao Wu, Realizing low thermal conductivity by bond nanodesigning, RWTH Cluster (No. rwth0366, 0.24 Mio. core-h), 01/10/2018 – 31/09/2019;
2.Guangzhao Qin, For the fundamental understanding of the negative Poisson's ratio in graphene, RWTH Cluster (No. rwth0288, 0.24 Mio. core-h), 01/02/2018 – 31/01/2019;
3.Guangzhao Qin and Huimin Wang, Strained modulated thermal transport in penta-AlN2 by first-principles calculation, RWTH Cluster (No. rwth0250, 0.24 Mio. core-h), 01/09/2017 – 31/08/2018;
4.Guangzhao Qin, First-principles study of phonon transport in monolayer gallium nitride (GaN), RWTH Cluster (No. rwth0223, 0.24 Mio. core-h), 01/06/2017 – 31/05/2018;
5.Guangzhao Qin and Ming Hu, Electric field modulated phonon transport in two-dimensional materials, RWTH Cluster (No. jara0168, 2.00 Mio. core-h), 01/05/2017 – 30/04/2018;
6.Guangzhao Qin, Huimin Wang, and Ming Hu, Phonon transport in Al-doped ZnO film from first-principles, RWTH Cluster (No. jara0160, 1.35 Mio. core-h), 01/11/2016 – 30/10/2017;
7.Guangzhao Qin, Huimin Wang, and Ming Hu, Strained modulated phonon transport in monolayer ZnO by first-principles calculation, RWTH Cluster (No. rwth0148, 1.2 Mio. core-h), 01/08/2016 – 31/07/2017;
8.Guangzhao Qin and Ming Hu, Phonon transport in two-dimensional phosphorene based on first-principles calculations, JURECA, Juelich Supercomputing Centre (JSC) (Project ID: JHPC38, 0.7 Mio. core-h), 01/05/2016 – 30/04/2017;

学术成果

近五年共计合作出版发表工程热物理相关领域著名权威期刊SCI论文40余篇,其中(共同)第一/通讯作者20篇(中科院一区8篇),ESI高被引5篇,总计被引1000+次,h因子13。另有合作出版学术专著2部,软件著作权2个。
Google Scholar: https://scholar.google.com/citations?user=mtlxt_gAAAAJ
JOURNAL PUBLICATIONS (Google Scholar total citation: 1160; h-index: 13)
(Co#-)First-author & Corresponding author*
1.Zhehao Sun, Kunpeng Yuan, Xiaoliang Zhang*, Guangzhao Qin*, and Dawei Tang*, Different response of thermal conductivity by enhancing interlayer force in bilayer graphene versus graphite, accepted by JAP;
2.Zhehao Sun, Kunpeng Yuan, Xiaoliang Zhang*, Guangzhao Qin*, Xiaojing Gong*, and Dawei Tang*, Disparate strain response of thermal transport properties of bilayer penta-graphene compared to monolayer, Phys. Chem. Chem. Phys 21, 15647 (2019);
3.Huimin Wang#, Guangzhao Qin#, Jiayue Yang, Zhenzhen Qin, Qiang Wang*, Yagang Yao*, and Ming Hu*, First-principle calculations of electronic, optical and thermal transport properties of monolayer MX (M=Ga, In; X=S, Se), J. Appl. Phys. 125, 245104 (2019);
4.Guangzhao Qin, Kuan-Rong Hao, Qing-Bo Yan*, Ming Hu*, and Gang Su*, Exploring T-Carbon for Energy Applications, Nanoscale 11, 5798 (2019);
5.Zhenzhen Qin, Guangzhao Qin*, and Ming Hu*, Origin of anisotropic negative Poisson's ratio in graphene, Nanoscale 10, 10365 (2018);
6.Guangzhao Qin, Zhenzhen Qin, Huimin Wang, and Ming Hu*, Lone-pair electrons induced anomalous enhancement of thermal transport in strained planar two-dimensional materials, Nano Energy 50, 425-430 (2018);
7.Guangzhao Qin, Zhenzhen Qin, Huimin Wang, and Ming Hu*, On the diversity in the thermal transport properties of graphene: A first-principles-benchmark study testing different exchange-correlation functionals, Comput. Mater. Sci. 151, 153-159 (2018);
8.Guangzhao Qin* and Ming Hu, The role of resonant bonding in governing the thermal transport properties of two-dimensional black phosphorus, arXiv:1801.04429 (2018);
9.Huimin Wang#, Guangzhao Qin#, Zhenzhen Qin, Guojian Li, Qiang Wang*, and Ming Hu*, Lone-pair Electrons do not Necessarily Lead to Low Lattice Thermal Conductivity: An Exception of Two-dimensional Penta-CN2, J. Phys. Chem. Lett. 9, 2474-2483 (2018);
10.Guangzhao Qin and Ming Hu*, Thermal transport in phosphorene, Small 14, 1702465 (2018);
11.Guangzhao Qin and Ming Hu*, Accelerating evaluation of converged lattice thermal conductivity, npj Computational Materials 4, 3 (2018);
12.Guangzhao Qin and Ming Hu*, Thermal transport properties of monolayer phosphorene: a mini-review of theoretical studies, Frontiers in Energy 12(1), 87-96 (2018);
13.Guangzhao Qin, Zhenzhen Qin, Huimin Wang, and Ming Hu*, Anomalously temperature dependent thermal conductivity of monolayer GaN with large deviation from the traditional 1/T law, Phys. Rev. B 95, 195416 (2017);
14.Guangzhao Qin, Zhenzhen Qin, Sheng-Ying Yue, Qing-Bo Yan, and Ming Hu*, External electric field driving the ultra-low thermal conductivity of silicene, Nanoscale 9, 7227 (2017);
15.Sheng-Ying Yue#, Guangzhao Qin#, Xiaoliang Zhang, Xianlei Sheng, Gang Su*, and Ming Hu*, Thermal transport in novel carbon allotropes with sp2 or sp3 hybridization: An ab initio study, Phys. Rev. B 95, 085207 (2017);
16.Jia-Yue Yang#, Guangzhao Qin#, and Ming Hu*, Nontrivial contribution of Fröhlich electron-phonon interaction to lattice thermal conductivity of wurtzite GaN, Appl. Phys. Lett. 109, 242103 (2016);
17.Guangzhao Qin, Xiaoliang Zhang, Sheng-Ying Yue, Zhenzhen Qin, Huimin Wang, Yang Han, and Ming Hu*, Resonant bonding driven giant phonon anharmonicity and low thermal conductivity of phosphorene, Phys. Rev. B 94, 165445 (2016);
18.Guangzhao Qin, Zhenzhen Qin, Wu-Zhang Fang, Li-Chuan Zhang, Sheng-Ying Yue, Qing-Bo Yan*, Ming Hu*, and Gang Su*, Diverse anisotropy of phonon transport in two-dimensional group IV-VI compounds: A comparative study, Nanoscale 8, 11306 (2016); ESI Highly Cited Paper (TOP 100 cited articles published in Nanoscale in 2016);
19.Guangzhao Qin, Qing-Bo Yan*, Zhenzhen Qin, Sheng-Ying Yue, Ming Hu*, and Gang Su*, Anisotropic intrinsic lattice thermal conductivity of phosphorene from first principles, Phys. Chem. Chem. Phys. 17, 4854 (2015); ESI Highly Cited Paper;
20.Guangzhao Qin, Qing-Bo Yan*, Zhenzhen Qin, Sheng-Ying Yue, Hui-Juan Cui, Qing-Rong Zheng, and Gang Su*, Hinge-like structure induced unusual properties of black phosphorus and new strategies to improve the thermoelectric performance, Scientific Reports 4, 6946 (2014); ESI Highly Cited Paper;
Co-author
21.Li-Chuan Zhang, Lizhi Zhang*, Guangzhao Qin, Qing-Rong Zheng, Ming Hu*, Qing-Bo Yan*,  and Gang Su*, Two-dimensional magnetic metal-organic frameworks with shastry-sutherland lattice, submitted to JPCL;
22.Chengxiao Peng, Guangzhao Qin, Lichuan Zhang, Guangbiao Zhang, Chao Wang, Yuli Yan, Yuanxu Wang*, and Ming Hu*, Dependence of phonon transport properties with stacking thickness in layered ZnO, Journal of Physics D: Applied Physics 51, 315303 (2018);
23.Yupeng Shen, Fancy Qian Wang, Jie Liu, Yaguang Guo, Xiaoyin Li, Guangzhao Qin, Ming Hu, Qian Wang*, A C20 fullerene-based sheet with ultrahigh thermal conductivity, Nanoscale 10, 6099 (2018);
24.Yanguang Zhou, Zheyong Fan, Guangzhao Qin, Jia-Yue Yang, Tao Ouyang, and Ming Hu*, Methodology Perspective of Computing Thermal Transport in Low-Dimensional Materials and Nanostructures: The Old and the New, ACS Omega 3, 3278 (2018);
25.Zeyu Liu, Xufei Wu, Vikas Varshney, Jonghoon Lee, Guangzhao Qin, Ming Hu, Ajit K Roy, and Tengfei Luo*, Bond saturation significantly enhances thermal energy transport in two-dimensional pentagonal materials, Nano Energy 45, 1-9 (2018);
26.Huimin Wang, Guangzhao Qin, Guojian Li, Qiang Wang*, and Ming Hu*, Unconventional thermal transport enhancement with large atom mass: A comparative study of two-dimensional transition dichalcogenides, 2D materials 5, 015022 (2018);
27.Huake Liu, Guangzhao Qin, Yuan Lin, and Ming Hu*, Uniform strain dependent thermal conductivity of pentagonal and hexagonal silicene, submitted to PCCP;
28.Zhenzhen Qin, Guangzhao Qin, Bin Shao, Xu Zuo*, Unconventional magnetic anisotropy in one-dimentional Rashba system realized by adsorbing Gd atom on zigzag graphene nanoribbons, Nanoscale 9, 11657 (2017);
29.Yang Han, Yanguang Zhou, Guangzhao Qin, Jinming Dong, Douglas S. Galvao, and Ming Hu*, Unprecedented Increase of the Lattice Thermal Conductivity of Auxetic Carbon Crystals under Tensile Strain, Carbon 122, 374 (2017);
30.Sheng-Ying Yue, Xiaoliang Zhang, Guangzhao Qin, Simon R. Phillpot*, and Ming Hu*, Metric for strong intrinsic fourth-order phonon anharmonicity, Phys. Rev. B 95, 195203 (2017);
31.Huimin Wang, Guangzhao Qin, Guojian Li, Qiang Wang, Ming Hu*, Low thermal conductivity of monolayer ZnO and its anomalous temperature dependence, Phys. Chem. Chem. Phys. 19, 12882 (2017);
32.Zhenzhen Qin, Guangzhao Qin, Xu Zuo*, Zhihua Xiong*, and Ming Hu*, Orbitally driven low thermal conductivity of monolayer gallium nitride (GaN) with planar honeycomb structure: a comparative study, Nanoscale 9, 4295 (2017);
33.Wuzhang Fang, Li-Chuan Zhang, Guangzhao Qin, Qing-Bo Yan, Qing-Rong Zheng*, and Gang Su*, Layer dependence of geometric, electronic and piezoelectric properties of SnSe, arXiv:1603.01791 (2016);
34.Ying Pan, Ye Tao, Guangzhao Qin, Yuriy Fedoryshyn, Shyamprasad Natarajan Raja, Ming Hu, Christian Lukas Degen, and Dimos Poulikakos*, Surface Chemical Tuning of Phonon and Electron Transport in Free-Standing Silicon Nanowire Arrays, Nano Lett. 16 (10), 6364 (2016);
35.Sheng-Ying Yue, Xiaoliang Zhang, Guangzhao Qin, Jiayue Yang, Stephen Stackhouse, and Ming Hu*, Insight into the role of vibrational modes of organic cluster in ultra-low thermal conductivity of perovskite solar cells, Phys. Rev. B 94, 115427 (2016);
36.Sheng-Ying Yue, Xiaoliang Zhang, Stephen Stackhouse, Guangzhao Qin, Edoardo Di Napoli, and Ming Hu*, Methodology for determining the electronic thermal conductivity of metals via direct nonequilibrium ab initio molecular dynamics, Phys. Rev. B 94, 075149 (2016);
37.Yang Han, Jinming Dong, Guangzhao Qin, and Ming Hu*, Phonon Transport in Ground State of Two-dimensional Silicon and Germanium, RSC Adv., 6, 69956 (2016);
38.Huake Liu, Guangzhao Qin, Yuan Lin, and Ming Hu*, Disparate Strain Dependent Thermal Conductivity of Two-dimensional Penta-Structures, Nano Lett. 16 (6), 3831 (2016);
39.Yang Han, Guangzhao Qin, Christoph Jungemann, and Ming Hu*, Strain modulated electronic and thermal transport properties of two-dimensional O-silica, Nanotechnology 27 (26), 265706 (2016);
40.Han Xie, Tao Ouyang, Éric Germaneau, Guangzhao Qin, Ming Hu*, Hua Bao*, Large tunability of lattice thermal conductivity of monolayer silicene via mechanical strain, Phys. Rev. B 93, 075404 (2016); ESI Highly Cited Paper;
41.Li-Chuan Zhang, Guangzhao Qin, Wu-Zhang Fang, Hui-Juan Cui, Qing-Rong Zheng, Qing-Bo Yan*, Gang Su*, Tinselenidene: a Two-dimensional Auxetic Material with Ultralow Lattice Thermal Conductivity and Ultrahigh Hole Mobility, Scientific Reports 6, 19830 (2016);
42.Zhenzhen Qin, Zhihua Xiong*, Guangzhao Qin, Lanli Chen, Energetics and magnetism of Co-doped GaN(0001) surfaces: A first-principles study, J. Appl. Phys. 116, 224503 (2014);
43.Xiaoliang Zhang, Han Xie, Ming Hu*, Hua Bao*, Shengying Yue, Guangzhao Qin, and Gang Su, Thermal conductivity of silicene calculated using an optimized Stillinger-Weber potential, Phys. Rev. B 89, 054310 (2014); ESI Highly Cited Paper;
44.Zhenzhen Qin, Zhihua Xiong*, Guangzhao Qin and Qixin Wan, Behavior of aluminum adsorption and incorporation at GaN(0001) surface: First-principles study, J. Appl. Phys. 114, 194307 (2013);
BOOK CHAPTERS
1.Guangzhao Qin and Ming Hu*, In book: Two-dimensional Materials - Synthesis, Characterization and Potential Applications, Chapter: Diverse Thermal Transport Properties of Two-Dimensional Materials: A Comparative Review, Editor: Pramoda Kumar Nayak, pp.199-217, InTech (2016), DOI: 10.5772/64298; (Accepted for indexing in the Book Citation Index in the Web of Science™ Core Collection (BKCI). The Book Citation Index (BKCI) is the world’s leading citation index with multidisciplinary content from the top tier publications.) Reached 1000 downloads at 2018-11-27.
2.Guangzhao Qin†, Han Xie†, Hua Bao*, and Ming Hu, In book: Silicon Nanomaterials Sourcebook: Low-Dimensional Structures, Quantum Dots, and Nanowires, Volume One, Chapter: Two dimensional silicon, Editor: Klaus D. Sattler, CRC Press 2017, Pages 43-76, DOI: 10.1201/9781315153544-4;
PATENTS
1.Software Copyright (China 2014SR078775): Shuffle Player (sfplayer), a command line interfaced (CLI) media player written in BASH;
2.Software Copyright (China 2014SR099203): ProcLiterature, a software written in BASH for managing and citing literature through HTML browser;

奖励与荣誉

2019年4月:美国南卡罗莱纳大学博士后卓越创新研究奖
2019年4月:美国材料研究协会春季会议最佳海报提名奖
2018年6月:德国亚琛工业大学最佳博士论文(拉丁文最高荣誉学位SUMMA CUM LAUDE)
2018年3月:《Computational Condensed Matter》杰出审稿人
2018年2月: 国际著名一区SCI期刊Nanoscale编辑部贺电
Congratulations from The Royal Society of Chemistry: ‘Diverse anisotropy of phonon transport in two-dimensional group IV-VI compounds: A comparative study’ [Nanoscale 8, 11306 (2016)] is one of the top 100 cited articles published in Nanoscale in 2016 based on Web of Science citations from January 2018
2018年1月: 国家优秀自费(非公派)留学生奖学金(全球500人次)
2014年9月: 中国北京,理论和高性能计算化学2014国际学术会议,最佳海报设计奖
2013年12月:第十届国家研究生数学建模大赛,组长,成功参赛奖
2007年4月: 河南省三好学生