张立军

发布日期:2019-02-18 作者: 编辑:ylzzcom永利总站 点击:

基本情况

姓名:张立军

性别:男

职称:教授;博士研究生导师

所在系别:材料科学

最高学历:研究生

最高学位:博士学位

电话:0431-89228920

Emaillijun_zhang@jlu.edu.cn

备注:学术主页:http://www.researcherid.com/rid/F-7710-2011

详细情况
所在学科专业: 材料物理与化学
研究方向: 材料计算机模拟、新材料设计、半导体光电材料、半导体材料物理、新能源材料
讲授课程:

普通物理II(本科)

材料计算方法与技术(本科实验班)
教育经历:

2003/09-2008/06,ylzzcom永利总站 超硬材料国家重点实验室 凝聚态物理博士

1999/09-2003/06,东北师范大学 物理系 本科
工作经历:

2014/09-今,ylzzcom永利总站 教授&博士生导师

2013/02-2014/09,[美国]科罗拉多大学波尔得分校 研究助理教授

2013/02-2014/09,[美国]能源部逆向设计能源前沿研究中心 项目负责人之一

2010/02-2013/01,[美国]国家可再生能源实验室 博士后

2008/07-2010/01,[美国]橡树岭国家实验室 博士后
科研项目:

1.    国家基金委杰出青年基金项目:"新型光电半导体材料设计物性调控"400万元、2022/012026/12

2.    国家海外高层次青年人才引进计划:"半导体功能材料的物性研究和设计"200万元、2015/012019/12

3.    国家基金委优秀青年基金项目:"半导体功能材料的能带调控及新材料设计研究"130万元、2018/012020/12

4.  国家重点研发计划项目课题:"面向E级计算的软件系统集成和典型应用示范研究"170.50万元、2016/072020/12

5.    国家基金委重大研究计划培育项目:基于机器学习算法的半导体高核团簇理论研究80万元、2021/012023/12

6.    国家基金委面上项目:"高压下碲化物基热电功能材料设计及输运性质研究"60万元、2017/012020/12

7.    国家基金委青年项目:"以优化类石墨烯VIB族过渡金属硫属化合物的光电性质为目标的材料设计研究"29万元、2015/012017/12
学术论文:

长期从事材料计算模拟与新材料设计研究工作,基于高通量材料计算与人工智能机器学习算法结合的思路,发展了具有自主知识产权的材料设计新方法与软件JAMIP (Jilin Artificial-intelligence aided Materials-design Integrated Package, http://www.jamip-code.com),为国内外同行开展新材料设计研究提供了有效工具;聚焦半导体光电材料,开展新材料设计与光电性能调控研究,多个从理论上设计的新材料与新性能调控策略得到实验证实,取得了对半导体光电材料与器件领域有指引作用的创新成果。

共发表SCI论文180余篇,所有论文共被引用14390次,H因子57
2014年回国,作为第一/通讯作者在Nature Reviews Materials, Nature Photonics, Nature Energy, Nature Communications, Phys. Rev. Lett., J. Am. Chem. Soc., Adv. Mater.等期刊发表论文90余篇。

代表性论文(标注*为通讯作者):

[45] “Mechanically and Operationally Stable Flexible Inverted Perovskite Solar Cells with 20.32% Efficiency by a Simple Oligomer Cross-Linking Method”, Sci. Bull. 67, 794-802 (2022), Jiang, Xing, Wang, Zhang, Yin, Liu, Bi, LJZ*, Feng* and Sun*.

[44] “Design of Organic–Inorganic Hybrid Heterostructured Semiconductors via High-Throughput Materials Screening for Optoelectronic Applications”, J. Am. Chem. Soc. 144, 16656 (2022), Li, Yang, Zhao, Zhang, Wang, He, Fu, LJZ*.

[43] “Excitation-Dependent Perovskite/Polymer Films for Ultraviolet Visualization”, Sci. Bull. 67, 1755 (2022), Sun, Li, Dong, Hua, Chang, Zhong, LJZ*, Shan* and Pan*.

[42] “Flexible All-Perovskite Tandem Solar Cells Approaching 25% Efficiency with Molecule-Bridged Hole-Selective Contact”, Nature Energy 7, 708 (2022), Li, Wang, Wang, Lin, Luo, Liu, Zhou, Xiong, Bao, Chen, Tian, Deng, Xiao, Wu, Saidaminov, Lin, Ma, Zhao, Wu, LJZ* and Tan*.

[41] “Molecular Engineering Towards Efficientwhite-Light-Emitting Perovskite”, Nature Commun. 12, 4890 (2021), Zhang, Zhao, Xie, Zhang, Wang, Yaqoob, Yin, Kaghazchi, Li, Zhang, Wang, LJZ*, Xu*, and Xing*.

[40] “JAMIP: an Artificial-Intelligence Aided Data-Driven Infrastructure for Computational Materials Informatics”, Sci. Bull. 66, 1973 (2021), Zhao, Zhou, Xing, Zhao, Luo, Li, Sun, Na, Xie, Yang, Wang, Wang, He, Lv, Fu*, and LJZ*.

[39] “Alternative Lone-Pair ns2-Cation-based Semiconductors beyond Lead Halide Perovskites for Optoelectronic Applications”, Adv. Mater. 33, 2008574 (2021), Li, Luo, Wang, and LJZ*.

[38] “High-throughput Computational Materials Screening and Discovery of Optoelectronic Semiconductors”, WIREs Comput Mol Sci. 11, e1489 (2021), Luo, Li, Wang, Faizan, and LJZ*.

[37] “High Color-Rendering Index and Stable White Light-Emitting Diodes by Assembling Two Broadband Emissive Self-Trapped Excitons”, Adv. Mater. 33, 2001367 (2021), Ma, Shi*, Yang, Li, Zhang, Wang, Li, Wu, Tian, Zhang, LJZ*, Li and Shan*.

[36] “New Polymorphs of Two-Dimensional Indium Selenide with Enhanced Electronic Properties”, Adv. Funct. Mater. 30, 2001920 (2020), Sun, Li, Li, Biswas, Patanè and LJZ*.

[35] “Efficient and Stable Ruddlesden-Popper Perovskite Solar Cell with Tailored Interlayer Molecular Interaction”, Nature Photonics 14, 154 (2020), Ren, Yu, Chao, Xia, Sun, Zuo, Li, Niu, Yang, Ju, Li, Du, Gao, Zhang, Wang, LJZ*, Chen* and Huang*.

[34] “Colloidal Synthesis of Ternary Copper Halides Nanocrystals for High-Efficiency Deep-Blue Light-Emitting Diodes with a Half-Lifetime Above 100 Hours”, Nano Lett. 20, 3568 (2020), Wang, Shi*, Ma, Yang, Zhang, Ji, Wang, Chen, Na, Chen, Wu, Zhang, Li, LJZ* and Shan*.

[33] “Stable Yellow Light-Emitting Devices Based on Ternary Copper Halides with Broadband Emissive Self-Trapped Excitons”, ACS Nano 14, 4475 (2020), Ma, Shi*, Qin, Cui, Yang, Wang, Wang, Ji, Chen, Sun, Wu, Zhang, Li, LJZ*, Shan*.

[32] “Van der Waals SnSe2(1−x)S2x Alloys: Composition‐Dependent Bowing Coefficient and Electron–Phonon Interaction”, Adv. Funct. Mater. 30, 1908092 (2020), Kudrynskyi, Wang, Sutcliffe, Bhuiyan, Fu, Yang, Makarovsky, Eaves, Solomon, Maslyuk, Kovalyuk, LJZ*, Patanè*.

[31] “Stable and Luminescent Halide Perovskite Fabricated in Water”, Light: Science & Applications 9, 106 (2020), Na and LJZ*.

[30] “Bottom-up Growth of Homogeneous Moiré Superlattices in Bismuth Oxychloride Spiral Nanosheets”, Nature Commun. 10, 4472 (2019), Liu, Sun, Cui*, Qi, He, Bao, Ma, Lu, Fang, Zhang, Zheng, Yu, Singh, Xiong, LJZ* and Zheng*.

[29] “Atomically Engineering Activation Sites onto Metallic 1T-MoS2 Catalysts for Enhanced Electrochemical Hydrogen Evolution”, Nature Commun. 10, 982 (2019), Huang, Sun, Zheng, Aoki, Pattengale, Huang, He, Bian, Younan, Williams, Hu, Ge, Pu, Yan, Pan, LJZ*, Wei* and Gu*.

[28] “Strain Engineering in Perovskite Solar Cells and Its Impacts on Carrier Dynamics”, Nature Commun. 10, 815 (2019), Zhu, Niu, Fu, Li, Hu, Chen, Na, Liu, Zai, Ge, Lu, Ke, Bai, Yang, Chen, Li, Sui, LJZ*, Zhou* and Chen*.

[27] “Ultrasensitive Detection of miRNA with an Antimonene-Based Surface Plasmon Resonance Sensor”, Nature Commun. 10, 28 (2019), Xue, Liang, Li, Sun, Xiang, Zhang, Dai, Duo, Wu, Qi, Nanjunda, Shivananju, LJZ*, Cui*, Zhang* and Bao*.

[26] “Thermochromic Lead‐Free Halide Double Perovskites”, Adv. Funct. Mater. 29, 1807375 (2019), Ning, Zhao, Klarbring, Bai, Ji, Wang, Simak, Tao, Ren, LJZ*, Huang, Abrikosov and Gao* .

[25] “Dopability of Divalent Tin Containing Phosphates for p-Type Transparent Conductors”, Phys. Rev. Materials 3, 124606 (2019), Li, Li, Faizan, Peng*, LJZ*.

[24] “Impact of Organic Molecule Rotation on the Optoelectronic Properties of Hybrid Halide Perovskites”, Phys. Rev. Materials 3, 125401 (2019), Xu, Stroppa, Lv, Zhao, Yang, Biswas, LJZ*.

[23] “Pressure-Induced Emission of Cesium Lead Halide Perovskite Nanocrystals”, Nature Commun. 9, 4506 (2018), Ma, Liu, Lu, Wang, Feng, Yang, Wang, Xiao*, LJZ*, Redfern and Zou*.

[22] “Dielectric Behavior as a Screen in Rational Searches for Electronic Materials: Metal Pnictide Sulfosalts”, J. Am. Chem. Soc. 140, 18058 (2018), He, Singh*, Patsorn Boon-on, Lee* and LJZ*.

[21] “Experimental Identification of Critical Condition for Drastically Enhancing Thermoelectric Power Factor of Two-Dimensional Layered Materials”, Nano Lett. 18, 7538 (2018), Zeng, He, Liang*, Liu, Sun, Pan, Wang, Cao, Liu, Wang, Zhang, Yan, Su, Wang, Watanabe, Taniguchi, Singh, LJZ* and Miao*.

[20] “Chlorine-Incorporation-Induced Formation of the Layered Phase for Antimony-Based Lead-Free Perovskite Solar Cells”, J. Am. Chem. Soc. 140, 1019 (2018), Jiang, Yang, Jiang, Liu, Zhao, Ming, Luo, Qin, Fan, Han, LJZ* and Zhou*.

[19] “Formation and Diffusion of Metal Impurities in Perovskite Solar Cell Material CH3NH3PbI3: Implications on Solar Cell Degradation and Choice of Electrode”, Advanced Science 5, 1700662 (2018), Ming, Yang, Li, LJZ* and Du*.

[18] “Rational Design of Halide Double Perovskites for Optoelectronic Applications”, Joule 2, 1662 (2018), Zhao, Yang, Ren, Sun, Xiao* and LJZ*.

[17] “Intrinsic Defect Properties in Halide Double Perovskites for Optoelectronic Applications”, Phys. Rev. Applied (Published as Letter) 10, 041001 (2018), Li, Zhao, Yang, Du* and LJZ*.

[16] “Materials Discovery at High Pressures”, Nature Reviews Materials 2, 17005 (2017), LJZ, Wang, Lv and Ma*.

[15] “Cu-In Halide Perovskite Solar Absorbers”, J. Am. Chem. Soc. 139, 6718 (2017), Zhao, Yang, Sun, Li, LJZ*, Yu and Zunger.

[14] “Design of Lead-Free Inorganic Halide Perovskites for Solar Cells via Cation-Transmutation”, J. Am. Chem. Soc. 139, 2630 (2017), Zhao, Yang, Fu, Yang, Xu, Yu, Wei* and LJZ*.

[13] “Highly Oriented Low-Dimensional Tin Halide Perovskites with Enhanced Stability and Photovoltaic Performance”, J. Am. Chem. Soc. 139, 6693 (2017), Liao, Liu, Zhou, Yang, Shang, Shi, Li, Jiang, LJZ*, Quan, Quintero-Bermudez, Sutherland, Mi, Sargent and Ning*.

[12] “Tellurium Hydrides at High Pressures: High-Temperature Superconductors”, Phys. Rev. Lett. 116, 057002 (2016), Zhong, Wang, Zhang, Liu, Zhang, Song, Yang*, LJZ* and Ma*.

[11] “Intrinsic Ultralow Lattice Thermal Conductivity of the Unfilled Skutterudite FeSb3”, Phys. Rev. B 94, 075122 (2016), Fu, Singh, Li* and LJZ*.

[10] “Evolution of Electronic Structure as a Function of Layer Thickness in Group-VIB Transition Metal Dichalcogenides: Emergence of Localization Prototypes”, Nano Lett. 15, 949 (2015), LJZ* and Zunger*.

[9] “Reinterpretation of the Expected Electronic Density of States of Semiconductor Nanowires”, Nano Lett. 15, 88 (2015), Wang, Luo, LJZ* and Zunger*.

[8] “Genetic Design of Enhanced Valley Splitting towards a Spin Qubit in Silicon”, Nature Commun. 4, 2396 (2013), LJZ*, Luo, Saraiva, Koiller* and Zunger*.

[7] “The Birth of a Type-II Nanostructure: Carrier Localization and Optical Properties of Isoelectronically Doped CdSe:Te Nanocrystals”, ACS Nano 6, 8325 (2012), LJZ*, Lin, Luo and Franceschetti*.

[6] “Genomic Design of Strong Direct-Gap Optical Transition in Si/Ge Core/Multishell Nanowires”, Nano Lett. 12, 984 (2012), LJZ*, d’Avezac, Luo and Zunger*.

[5] “Wide InP Nanowires with Wurtzite/Zincblende Superlattice Segments are Type-II whereas Narrower Nanowires Become Type-I: An Atomistic Pseudopotential Calculation”, Nano Lett. 10, 4055 (2010), LJZ, Luo, Zunger*, Akopian, Zwiller and Harmand.

[4] “Comment on ‘Spectroscopic Signatures of Novel Oxygen-Defect Complexes in Stoichiometrically Controlled CdSe”, Phys. Rev. Lett. 102, 209601 (2009), LJZ, T-Thienprasert, Du, Singh and Limpijumnong.

[3] “Density Functional Study of Excess Fe in Fe1+xTe: Magnetism and Doping”, Phys. Rev. B 79, 012506 (2009), LJZ, Singh and Du.

[2] “CaCl2-Type High-Pressure Phase of Magnesium Hydride Predicted by ab initio Phonon Calculations”, Phys. Rev. B 75, 144109 (2007), LJZ, Wang, Cui, Li, Li, He, Ma* and Zou.

[1]“Pressure-Induced Enhancement of Electron-Phonon Coupling in Superconducting CaC6 from First Principles”, Phys. Rev. B 74, 184519 (2006), LJZ, Xie, Cui, Li, He, Ma* and Zou.
授权专利:

[1] Jilin Artificial-intelligence aided Materials-design Integrated Package软件 [简称: JAMIP] V1.0,软件著作权登记号:2021SR0349238

[2] Structure Prototype Generator Infrastructure [简称: SPGI] V1.0,软件著作权登记号:2019SR1060756

[3] Jilin University Materials-design Python Package [简称: JUMP2] V1.0,软件著作权登记号:2017SR514752
获奖情况:

[1]国家基金委杰青 国家基金委 2021

[2]国家海外高层次青年人才引进计划 中组部 2014

[3]国家基金委优青 国家基金委 2017

[4]“计算材料学青年奖(每次授予1人)” 中国材料研究学会2018

[5]“吉林省青年科技奖—特别奖(每次授予3人)” 吉林省委组织部 2019

[6]长春市第七批有突出贡献专家 长春市 2019

[7]吉林省第十六批享受政府津贴专家(省有突出贡献专家) 吉林省 2020
社会兼职:

[1]《Nano Research》Young Star Editor

[2]《Nano Select》Associated Editor

[3]《InfoMat》青年编委

[4]《Chinese Physics Letters》、《Chinese Physics B》、《物理学报》和《物理》青年编委

[5]《半导体学报》编委会编委

[6]《中国光学》编委会青年编委

[7]Nature、Nature Commun.、Phys. Rev. Lett.、Adv. Mater.、J. Am. Chem. Soc.、Nano Lett.、Phys. Rev.系列等国际学术期刊审稿人

[8]中国光学工程学会微纳专业委员会委员
指导员工: 在读:博士研究生12人,硕士研究生10人
已毕业:博士研究生11人,硕士研究生7人

 

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