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Hao Wang

Associate Researcher

[email protected]

Personal Homepage

Research Field

condensed matter theory, fractional quantum Hall effect system

Educational Background

2000.08-2006.12, Ph.D. (condensed matter physics), University of Minnesota, USA

1997.09-2000.07 M.S. (condensed matter physics), Tsinghua University

1992.09-1997.07 B.S. (modern applied physics), Tsinghua University

Working Experience

2013.02-2018.08 Assistant Professor, Department of Physics, Southern University of Science and Technology

2011.08-2013.02? Postdoc/Research Assistant Professor, Department of Physics, University of Hong Kong

2009.08-2011.08? Postdoc, Department of Physics, Virginia Tech., USA

2007.01-2009.08? Postdoc, Department of Physics, California State University at Northridge, USA

Papers and Patents

1.	Possible half-metallic phase in bilayer graphene: Calculations based on mean-field theory applied to a two-layer Hubbard model, Jie Yuan, Dong-Hui Xu, Hao Wang, Yi Zhou, Jin-Hua Gao, and Fu-Chun Zhang, Phys. Rev. B 88, 201109(R) (2013).
2.	Layer antiferromagnetic ground state in bilayer graphene: a first-principle investigation, Yong Wang, Hao Wang, Jin-hua Gao, and Fu-chun Zhang, Phys. Rev. B 87, 195413 (2013).
3.	Flat band electrons and interactions in rhombohedral trilayer graphene, Hao Wang, Jin-Hua Gao, and Fu-Chun Zhang, Phys. Rev. B 87, 155116 (2013).
4.	Fractional quantum Hall states in two-dimensional electron systems with anisotropic interactions, Hao Wang, Rajesh Narayanan, Xin Wan, and Funchun Zhang, Phys. Rev. B 86, 035122 (2012).
5.	Models of strong interaction in flat-band graphene nanoribbons: magnetic quantum crystals, Hao Wang and V. W. Scarola, Phys. Rev. B 85, 075438 (2012).
6.	Jastrow-correlated wavefunctions for flat-band lattices, Hao Wang and V. W. Scarola, Phys. Rev. B 83, 245109 (2011).
7.	Identifying quantum topological phases through statistical correlation, Hao Wang, B. Bauer, M. Troyer, and V. W. Scarola, Phys. Rev. B 83, 115119 (2011).
8.	Particle-hole symmetry breaking and 5/2 fractional quantum hall effect, Hao Wang, D. N. Sheng, and F. D. M. Haldane, Phys. Rev. B 80, 241311(R) (2009).
9.	Broken-symmetry states of Dirac fermions in graphene with a partially filled high landau level, Hao Wang, D. N. Sheng, L. Sheng, and F. D. M. Haldane, Phys. Rev. Lett. 100, 116802 (2008).
10.	Unconventional magnetic vortex structures observed in micromagnetic simulations, M. Yan, H. Wang, and C. E. Campbell, J. Magn. Magn. Mater. 320,?1937?(2008).
11.	Spin dynamics of a magnetic anitvortex: micromagnetic simulations, Hao Wang and C. E. Campbell, Phys. Rev. B 76, 220407(R) (2007).
12.	Vorticity and antivorticity in submicron ferromagnetic films, Hao Wang, M. Yan and C. E. Campbell, Int. J. Mod. Phys. B 21, 2289 (2007).
13.	Spin wave modes in thin-film ferromagnetic stripes, M. Yan, H. Wang, P. A. Crowell, C. E. Campbell, and C. Bayer, Condensed Matter Theories, vol. 20, Ed. J. W. Clark, R. M. Panoff, and H. Li, Nova Scientific, New York, 251-263 (2006).
14.	Spin waves in an inhomogeneously magnetized stripe, C. Bayer, J. P. Park, H. Wang, M. Yan, C. E. Campbell, and P. A. Crowell, Phys. Rev. B 69, 134401 (2004).
15.	Spin-resonant suppression and enhancement in ZnSe/Zn_1-xMn_xSe multiplayer heterostructures, Y. Guo, B.-L. Gu, H. Wang, and Y. Kawazoe, Phys. Rev. B 63, 214415 (2001).
16.	Spin-polarized transport through a ZnSe/Zn_1-xMn_xSe heterostructure under an applied electric field, Y. Guo, H. Wang, B.-L. Gu, and Y. Kawazoe, J. Appl. Phys. 88, 6614 (2000).
17.	Electric-field effects on electronic tunneling transport in magnetic barrier structures, Y. Guo, H. Wang, B.-L. Gu, and Y. Kawazoe, Phys. Rev. B 61, 1728 (2000).
18.	Electron coherent tunneling in low-dimensional magnetic quantum structures, Yong Guo, Hao Wang, Bing-Lin Gu, and Yoshiyuki Kawazoe, Physica E 8, 146 (2000).
19.	Wave-vector-dependent tunneling transmission characteristics in periodic and quasiperiodic semiconductor supperlattices, Guo Yong, Wang Hao, and Gu Bing-Lin, Tsinghua Science and Technology 5(2), (2000).
20.	Transport of electrons in double-barrier magnetic structures under a constant electric field, Wang Hao, Guo Yong, and Gu Bing-Lin, Acta Physics Sinica 48(9), 1723 (1999).