公卫江
2008年—2014年:东北大学物理系工作
2009年,被聘为中国科学院国际材料物理中心协作成员;同年,入选辽宁省“百千万人才工程”千人层次。
2010年,被聘为副教授
2014年,被聘为教授、博士生导师
2015年-2016年,在美国得州大学达拉斯分校做访问学者
一直从事低维半导体介观体系中电子输运性质方面的研究。一方面,系统地研究了耦合量子点结构的电子及自旋输运特性以及由其调控的热电和热自旋效应。通过讨论耦合量子点结构中由几何结构和各种参数(如:量子点的能级、点间耦合、外加电磁场等)调制的量子干涉和电子关联效应,全面描述一些典型量子点结构的电子输运性质,并分析了Fano效应、Kondo效应以及Josephson效应等量子输运现象的表现规律。另一方面,关注一些新型材料的电子结构和电子输运特性,如石墨烯、WoS2等材料,研究了此类材料中尺寸、缺陷、杂质以及无序等机制对电子结构的影响,为新材料在器件应用上提供帮助。目前关注拓扑超导体中由Majorana束缚态诱导的量子输运特性,并通过在不同几何构型量子点结构的末端耦合Majorana零模式来考察该结构中的电子输运性质,为Majorana束缚态的探测提供了新思路。
到目前为止,在国内外主要学术刊物上已发表被SCI收录论文80余篇,包括Phys.Rev.B, Sci. Rep., ppl.Phys.Lett., J. Appl.Phys., EPL等杂志。
国家自然科学基金专项基金项目:量子点环中的电子输运性质;
国家自然科学基金青年基金项目:量子点体系中由自旋偏压调控的电子态和电子输运性质;
中央高校基本科研业务费专项资金:几种典型量子点分子体系中的自旋操控,
耦合量子点结构中的热电性质,
嵌有线缺陷的石墨烯纳米条带中的热电性质;
博士后基金面上项目:量子点分子体系中的自旋操控;
辽宁省自然基金:自旋-轨道耦合对量子点分子体系的热电性质的影响;
2016
[59] Wan-Fei Shan, Cui Jiang, Zhen Gao, Guang-Yu Yi, and Wei-Jiang Gong*, Influence of an interacting quantum dot on the fractional Josephson effect, Solid State Communications 229, 5-9 (2016).
[58] Wei-Jiang Gong, Zhen Gao, Wan-Fei Shan, Guangyu Yi, Influence of an embedded quantum dot on the Josephson effect in the topological superconducting junction with Majorana doublets, Scientific Reports 6, 23033 (2016).
[57] Wei-Jiang Gong, Xiao-Qi Wang, Guang-Yu Yi, and Yu Han, Andreev reflections in a Y-shaped junction with Majorana zero mode, Current Applied Physics 16(7): 673-680 (2016).
[56] Wei-Jiang Gong, Xiao-Qi Wang, Yu-Lian Zhu, and Hai-Na Wu, Out-of-phase Andreev transports in a double-quantum-dot Cooper-pair splitter, J. Appl. Phys. 119, 214305 (2016).
[55] Zhen Gao, Xiao-Qi Wang, Wan-Fei Shan, Hai-Na Wu, Wei-Jiang Gong*, Josephson effects in the junction formed by DIII-class topological and s-wave superconductors with an embedded quantum dot, Scientific reports 6, 28311 (2016).
[54] Wei-Jiang Gong, Yu-Lian Zhu, Xiao-Qi Wang, Hai-Na Wu, Enhancing the Cooper-pair splitting in one Fano interferometer, Europhysics Letters 114, 47010(2016).
[53] Xiao-Qi Wang, Guang-Yu Yi, and Wei-Jiang Gong*, Dicke-Josephson effect in a cross-typed triple-quantum-dot junction, Solid State Communications 247,12-16 (2016).
[52] Zhen Gao and Wei-Jiang Gong*, Kondo effect modified by Majorana doublet at end of a DIII-class topological superconductor, Physics Review B 94,104506 (2016).
2015
[51] Wei-Jiang Gong, Ying Zhao, Zhen Gao, and Guang-Yu Yi, Odd-even effect of the persistent current in a quantum dot ring with embedded Majorana bound states, Journal of the Physical Society of Japan 84, 024707 (2015).
[50] Wei-Jiang Gong, Ying Zhao, Zhen Gao, Universal transport properties of a quantum dot system coupled to one Majorana zero mode, Current Applied Physics 15, 520 (2015).
[49] Wei-Jiang Gong, Li-Hui Jin, Xue Sun, Yu Han, Electron transport through a graphene quantum dot: the role of line defect, Applied Physics A 118, 1211-1217 (2015).
[48] Zhen Gao, Wei-Jiang Gong*, Shu-Feng Zhang, and Yi-Song Zheng, Tunable fractional Josephson effect in the topological superconducting junction with embedded quantum dots, Europhysics Lett. 109, 40010 (2015).
[47] Wei-Jiang Gong, Zhen Gao, and Xiao-Qi Wang, Influence of Majorana doublet on transport through a quantum dot system with ferromagnetic leads, Current Applied Physics 15(10), 1278 (2015).
[46] Zhen Gao and Wei-Jiang Gong*, Kondo physics in the junction with DIII-class topological and s-wave superconductors, Europhysics Letters 112, 57002 (2015).
2014
[45] Wei-Jiang Gong, Hui-Min Wang, Yu Han, Impurities-contributed abnormal thermoelectric effect in a parallel double quantum dot structure, Current Applied Physics 14,34 (2014).
[44] Wei-Jiang Gong, Shu-Feng Zhang, Zhi-Chao Li, Guangyu Yi, and Yi-Song Zheng, Detection of a Majorana-fermion zero mode by a T-shaped quantum-dot structure, Physical Review B 89, 245413 (2014).
[43] Wei-Jiang Gong, Shu-Feng Zhang, Zhi-Chao Li, Guangyu Yi, and Yi-Song Zheng, Andreev Reflection in a T-Shaped Double-Quantum-Dot Structure Induced by Majorana Bound States. Journal of the Physical Society of Japan 83, 034706 (2014).
[42] Wei-Jiang Gong, B. H. Wu, Shu-Feng Zhang, and Yi-Song Zheng, Odd-even effect of transport through a chain of Majorana bound states in a T-shaped junction, Europhysics Letters 106, 30003 (2014).
[41] Cui Jiang, Gang Lu, and Wei-Jiang Gong, Tunable transport through a quantum dot chain with side-coupled Majorana bound states, Journal of Applied Physics 116, 103704 (2014).
2013
[40] Wei-Jiang Gong, An Du, Yan Wang, Xiao-Hui Chen, “Optically assistedthermoelectric and thermospin effect in a quantum dot structure”, J. Phys. Soc. Jpn. 82, 014603 (2013).
[39] Wei-Jiang Gong*, Cui Jiang, Xiao-Yan Sui, An Du, and Xiao-Hui Chen, “Spin-bias-induced thermal rectification in a quantum dot structure”, Solid State Communications 161, 29 (2013).
[38] Yan Wang, Wei-Jiang Gong*, Xiao-Yan Sui, and Xiao-Hui Chen, “Thermoelectric and thermospin switch realized by a three-terminal nanojunction”, J. Appl. Phys. 113, 184308(2013).
[37] Yu Han, Yan Wang, and Wei-Jiang Gong*, Unidirectional heat current through a one dimensional quantum spin heterostructure, Appl. Phys. A 112, 255 (2013).
[36] W. J. Gong*, X. Y. Sui, L. Zhu, G. D. Yu and X. H. Chen, Line-defect-induced Fano interference in an armchair graphene nanoribbon, Europhysics Letters 103, 18003 (2013).
[35]Xiao-Yan Sui, Zhi-Chao Li, Wei-Jiang Gong*, Guo-Dong Yu, Xiao-Hui Chen, A graphene quantum dot based an armchair graphene nanoribbon with line defect, physica status solidi: RRL 7,152 (2013).
[34] Guanyu Yi, Zhichao Li, Xiaohui Chen, Haina Wu, and Wei-Jiang Gong*, Persistent current driven by the Josephson effect in a triple-quantum-dot ring with superconducting leads, Phys. Rev. B 87, 195442 (2013).
[33] Yu Han, Xiao-Yan Sui, and Wei-Jiang Gong*, “Fano Effects in electron transport through an armchair graphene nanoribbon with one line defect”, J. Appl. Phys. 113, 233701 (2013).( 2.21)
[32] Wei-Jiang Gong, Xiao-Yan Sui, Yan Wang, Guo-Dong Yu, and Xiao-Hui Chen, “Fano effect and bound state in continuum in electron transport through an armchair graphene nanoribbon with line defect”, Nanoscale Research Letters 8, 330 (2013).
[31] Cui Jiang, Wei-Jiang Gong, and Yi-Song Zheng, Transport properties of paired Majorana bound states in a parallel junction, J. Appl. Phys. 114, 243708 (2013).
2012
[30] Wei-Jiang Gong, Shuang Fan, Francis N. Kariuki, Guo-Zhu Wei, and An Du, “Spin separation in a quantum dot ring driven by a temperature bias”, J. Appl. Phys. 111, 013705 (2012).
[29] Cui Jiang, Wei-Jiang Gong, and Yisong Zheng, “Spin accumulation in parallel-coupled quantum dots driven by a symmetric dipolar spin battery”, J. Appl. Phys. 111, 053708 (2012).
[28] Cui Jiang, Wei-Jiang Gong*, and Guo-Zhu Wei, “Tunable spin manipulation in a quantum dot embedded in an Aharonov-Bohm interferometer”, J. Appl. Phys. 111, 054306 (2012).
[27] Wei-Jiang Gong, Yu Han, Francis N. Kariuki, and An Du, “Spin accumulation in a multi-arm Aharonov-Bohm-Fano interferometer”, J. Appl. Phys. 111, 093707 (2012).
[26] Wei-Jiang Gong, Cui Jiang, Xiaoyan Sui, and An Du, “Thermoelectric Properties in a Parallel Double Quantum Dot Structure Modulated by the Fano Interferences”, J. Phys. Soc. Jpn. 81, 104601(2012).
[25] Wei-Jiang Gong, Yu Han, Guo-Zhu Wei, An Du, “Spin accumulation assisted by the Aharonov-Bohm-Fano effect of quantum dot structures”, Nanoscale Research Letters 7, 510 (2012).
[24] Cui Jiang, Wei-Jiang Gong, Yisong Zheng, “Thermoelectric effects of a laterally coupled double-quantum-dot structure”, Eur. Phys. J. B85, 364 (2012).
[23] Yu Han, Wei-Jiang Gong*, Hui-Min Wang, An Du, “Fano antiresonance in electron transport through a parallel-coupled quantum-dot structure”, J. Appl. Phys. 112, 123701 (2012).
2011
[22] Weijiang Gong, Hui Li, Sha Zhang, and Guozhu Wei,”The Aharonov-Bohm-Fano interferometer as a spin-manipulating device”, J. Appl. Phys. 109, 074315 (2011).
[21] Weijiang Gong, Hui Li, Yu Han, Guozhu Wei,”Detection of spin bias in a four-terminal quantum-dot ring”, Phys. Lett. A 375. 1333 (2011).
[20] Sha Zhang, Weijiang Gong*, Guozhu Wei, and An Du, “Rashba-induced spin accumulation in a quantum wire with an impurity” J. Appl. Phys. 109, 023704 (2011).
[19]Sha Zhang, Hui Li, Wei-Jiang Gong*, and Guo-Zhu Wei, “Impurity-modulated electron properties in a double-quantum-dot Aharonov–Bohm ring”, J. Appl. Phys. 109, 013714 (2011).
2010
[18] Weijiang Gong,Xuefeng Xie, and Guozhu Wei, “Coulomb-modified equilibrium and nonequilibrium properties in a double quantum dot Aharonov–Bohm–Fano interference device”, J. Appl. Phys. 107, 073702 (2010).
[17]C. Jiang, X. F. Xie, W.J. Gong* and G.Z. Wei,”Nonequilibrium electron and spin properties in a parallel double quantum dot Fano interference device”, Eur. Phys. J. B 75, 237 (2010).
[16] Weijiang Gong, Yu Han, Xuefeng Xie, and Guozhu Wei, “Coulomb-modified Fano interference in a double quantum dot Aharonov–Bohm ring”, Phys. Status Solidi B 247, 2222 (2010).
2009
[15] Weijiang Gong and Yisong Zheng, “Coulomb-modified spin polarization in a four-terminal parallel double-quantum-dot structure”,J. Appl. Phys. 105, 033708 (2009).
[14] Weijiang Gong and Yisong Zheng, “Spin-dependent electron transport through a parallel double-quantum-dot structure”,Physica E 41, 574(2009).
[13] Weijiang Gong, Yu Han, and Guozhu Wei, “Antiresonance and bound states in the continuum in electron transport through parallel-coupled quantum-dot structures”,J. Phys. Condens. Matter 17, 175801 (2009).
[12] Weijiang Gong, Yu Han, Guozhu Wei, “Rashba-induced transverse pure spin currents in a four-terminal quantum dot ring“. Sol. Stat. Comm. 149, 1831 (2009).
[11] Yu Han, Weijiang Gong*, Haina Wu, and Guozhu Wei,“Decoupling and antiresonance in electron transport through a quantum dot chain embodied in an Aharonov–Bohm interferometer” Physica B 404, 2001 (2009).
[10] Yu Han, Weijiang Gong*, and Guozhu Wei,“Bound states in the continuum in electronic transport through parallel-coupled quantum-dot structures” Phys. Status Solidi B 246, 1634 (2009).
[9] Yu Han, Weijiang Gong*, and Guozhu Wei “Realization of longitudinal pure spincurrents in a four-terminal parallel double-quantum-dot structure“Phys. Status Solidi B 246, 2140 (2009).
[8] HAN Yu, GONG Wei-Jiang*, and WEI Guo-Zhu, “Spin-Dependent Electron Properties of a Triple-Terminal Quantum Dot Structure”, Commun. Theor. Phys. 52, 1117 (2009) .
[7] Weijiang Gong and Cui Jiang, “Impurity-modified Fano effect in a double quantum dot Aharonov–Bohm interferometer”, J. Appl. Phys. 106, 013710(2009).
2008
[6]Weijiang Gong, Yisong Zheng, Jie Wang, and Tianquan Lü,“Effect of electron–phonon interaction on Fano interference in the parallel double quantum dot structure”,Phys. Stat. Sol. (b) 245, 1175 (2008).
[5] Weijiang Gong, Yisong Zheng , Yu Liu, Francis N. Kariuki, Tianquan Lü, “ Fano effect in a T-shaped double quantum dot structure in the presenceof Rashba spin–orbit coupling”, Phys. Lett. A 372, 2934 (2008).
[4] Weijiang Gong, Yisong Zheng, Yu Liu, Tianquan Lu¨, “A Feynman path analysis of the Fano effect in electronic transport through a parallel double quantum dot structure”, Physica E 40, 618 (2008).
[3]Weijiang Gong, Yisong Zheng, Jianfei Zou, Tianquan Lü, “Spin polarization and separation in a triple-quantum-dot ring”Sol. Stat. Comm.. 147, 288 (2008).
[2] Weijiang Gong, Yisong Zheng,and Tianquan Lü, “Tunable pure spin currents in a triple-quantum-dot ring”Appl. Phys. Lett. 92, 042104 (2008).
2006
[1] Weijiang Gong, Yisong Zheng, Yu Liu, and Tianquan Lv, “Well-defined insulating band for electronic transport through a laterally coupled double-quantum-dot chain: Nonequilibrium Green’s function calculations” Phys. Rev. B 73, 245329(2006).