2017
50. ‘Emergence of Tertiary Dirac Points in Graphene Moiré Superlattices’,
G. Chen, M. Sui, D. Wang , S. Wang, J. Jung, P. Moon, S. Adam, K. Watanabe, T. Taniguchi, S. Zhou, M. Koshino, Guangyu Zhang and Yuanbo Zhang,
Nano Letters 10.1021/acs.nanolett.7b00735
49. ‘Graphene bubbles and their role in graphene quantum transport’,
N. Leconte, Hakseong Kim, Ho-Jong Kim, Dong Han Ha, Kenji Watanabe, Takashi Taniguchi, Jeil Jung, Suyong Jung,
Nanoscale, 9, 6041 - 6047 (2017).
48. 'Broken sublattice symmetry states in Bernal stacked multilayer graphene',
C. Yoon, Y. Jang, J. Jung, and H. Min,
2D Materials 4, 021025 (2017). DOI:10.1088/2053-1583/aa659a
2016
47. ‘Zero line modes at stacking faulted domain walls in multilayer graphene’,
C. Lee, G. Kim, J. Jung and H. Min,
Phys. Rev. B 94, 125438 (2016).
46. ‘Gaps induced by inversion symmetry breaking and second generation Dirac cones in graphene/hexagonal boron nitride’,
E. Wang, X. Lu, S. Ding, W. Yao, M. Yan, G. Wan, G. Chen, L. Ma, J. Jung, A. V. Fedorov, Y. Zhang, G. Zhang, S. Zhou,
Nature Physics doi:10.1038/nphys3856 (2016).
45. ‘Fractional Hofstadter States in Graphene on Hexagonal Boron Nitride’,
A. M. DaSilva, J. Jung and A. H. MacDonald,
Phys. Rev. Lett. 117, 036802 (2016).
44. ‘Electronic and Magnetic Properties of single layer MPX3 metal phosphorous trichalcogenides’,
B. Chittari, Y. J. Park, D. Lee, M. Han, A. H. MacDonald, E. H. Hwang, J. Jung,
Physical Review B 94, 184428 (2016).
43. ‘Efficient Multiscale Lattice Simulations of Strained and Disordered Graphene’,
N. Leconte, A. Ferreira, J. Jung,
Semiconductor and Semimetals, Volume 95, chapter 2. Elsevier (2016).
42. ‘PT Symmetry and Singularity-Enhanced Sensing Based on Photoexcited Graphene Metasurfaces’,
P. Y. Chen and J. Jung,
Phys. Rev. Applied 5, 064018 (2016).
41. ‘Tunability of 1/f Noise at multiple Dirac cones in hBN encapsulated graphene devices’,
C. Kumar, M. Kuiri, J. Jung, T. Das, A. Das,
Nano Letters, doi: 10.1021/acs.nanolett.5b04116
2015
40. ‘Role of geometry and topological defects in the one-dimensional zero-line modes of graphene’,
X. Bi, J. Jung, and Z. Qiao,
Physical Review B 92 (23), 235421 (2015).
39. ‘Spectroscopic visualization of grain boundaries of monolayer molybdenum disulfide by stacking bilayers’,
S. Park, M. S. Kim, H. Kim, J. Lee, G. H. Han, J. Jung, and J. Kim,
ACS Nano 9 (11), 11042-11048 (2015).
38. ‘Local spectroscopy of moire-induced electronic structure in gate-tunable twisted bilayer graphene’,
D. Wong, Y. Wang, J. Jung, S. Pezzini, A. M. DaSilva, H. Z. Tsai, H. S. Jung, R. Khajeh, Y. Kim, J. Lee, S. Kahn, S. Tollabimazraehno, H. Rasool, K. Watanabe, T. Taniguchi, A. Zettl, S. Adam, A. H. MacDonald, and M. F. Crommie,
Physical Review B 92 (15), 155409 (2015).
37. ‘Terahertz conductivity of graphene on boron nitride’.
A. M. DaSilva, J. Jung, S. Adam, A. H. MacDonald,
Physical Review B 92 (15), 155406 (2015).
36. ‘Transport and particle-hole asymmetry in graphene on boron nitride’,
A. M. DaSilva, J. Jung, S. Adam, and A. H. MacDonald,
Physical Review B 91 (24), 245422 (2015).
35. ‘Single-valley engineering in graphene superlattices’,
Y. Ren, X. Deng, Z. Qiao, C. Li, J. Jung, C. Zeng, Z. Zhang, and Q. Niu,
Physical Review B 91 (24), 245415 (2015).
34. ‘Magnetic oscillation of optical phonon in ABA-and ABC-stacked trilayer graphene’,
C. Cong, J. Jung, B. Cao, C. Qiu, X. Shen, A. Ferreira, S. Adam, and T. Yu,
Physical Review B 91 (23), 235403 (2015).
33. ‘Persistent current states in bilayer graphene’,
J. Jung and A. H. MacDonald,
Physical Review B 91 (15), 155423 (2015).
32. ‘Origin of the band gap in graphene on hexagonal boron nitride’,
J. Jung, A. DaSilva, A. H. MacDonald and S. Adam,
Nature Communications 6, 6308, doi:10.1038/ncomms7308 (2015).
31. ‘van der Waals Force: A Dominant Factor for Reactivity of Graphene’,
J. H. Lee, A. Avsar, J. Jung. J. Y. Tan, K. Watanabe, T. Taniguchi, S. Natarajan, G. Eda, S. Adam, A. H. Castro Neto, B. Ozylmaz,
Nano Letters 15 (1), 319 (2015).
2014
30. ‘Ab initio theory of moire superlattice bands in layered two dimensional materials’,
J. Jung, A. Raoux, Z. Qiao, and A. H. MacDonald,
Physical Review B 89, 205414 (2014).
29. ‘Current partition at topological channel intersections’,
Z. Qiao, J. Jung, C. Lin, Y. Ren, A. H. MacDonald and Q. Niu,
Physical Review Letters 112, 206601 (2014).
28. ‘Capacitance of carbon based electrical double-layer capacitors’,
H. Ji, X. Zhao, Z. Qiao, J. Jung, Y. Zhu, Y. Lu, L.L. Zhang, A. H. MacDonald and R. S. Ruoff,
Nature Communications 5:3317 doi: 10.1038/ncomms4317 (2014).
27. ‘Direct Chemical Conversion of Graphene to Boron, Nitrogen and Carbon Containing Atomic Layers’,
Y. Gong, G. Shi , Z. Zhang, W. Zhou, J. Jung, W. Gao, L. Ma, Y. Yang, S. Yang, G. You, R. Vajtai, Q. Xu, A. MacDonald, B. Yakobson, J. Lou, and P. Ajayan,
Nature Communications 5:3193 doi: 10.1038/ncomms4193 (2014).
26. ‘Accurate tight-binding and continuum models for the π bands of bilayer graphene’,
J. Jung and A. H. MacDonald,
Physical Review B 89, 035405 (2014).
2013
25. ‘Ultrathin high-temperature oxidation-resistant coatings of hexagonal boron nitride’,
Z. Liu, Y. Gong, W. Zhou, L. Ma, J. Yu, J. C. Idrobo, J. Jung, A. H. MacDonald, R. Vajtai, J. Lou, and P. M. Ajayan,
Nature Communications 4:2541, doi: 10.1038/ncomms3541 (2013).
24. ‘Gapped broken symmetry states in ABC trilayer graphene’,
J. Jung and A. H. MacDonald,
Physical Review B 88, 075408 (2013).
23. ‘Tight-binding model for graphene pi-bands from maximally localized Wannier functions’,
J. Jung and A. H. MacDonald,
Physical Review B 87, 195450 (2013).
2012
22. ‘Unbalanced edge modes and topological phase transition in gated trilayer graphene’,
X. Li, Z. Qiao, J. Jung, and Q. Niu,
Physical Review B 85, 201404(R) (2012).
21. ‘Transport properties of graphene nanoroads in boron nitride sheets’,
J. Jung, Z. Qiao, Q. Niu and A. H. MacDonald,
Nano Letters 12, 2936 (2012).
20. ‘Transport Spectroscopy of Symmetry-Broken Insulating States in Bilayer Graphene’,
J. Velasco Jr., L. Jing, W. Bao, Y. Lee, P. Kratz, V. Aji, M. Bockrath, C. N. Lau, C. Varma, R. Stillwell, D. Smirnov, Fan Zhang, J. Jung, A.H. MacDonald,
Nature Nanotechnology 7, 156 (2012).
19. ‘Pseudospin Order in Monolayer, Bilayer, and Double-Layer Graphene’,
A. H. MacDonald, J. Jung and F. Zhang,
Phys. Scr. T146, 014012 (2012).
2011
18. ‘Spontaneous Quantum Hall States and Novel Luttinger Liquids in Chiral Graphene’,
F. Zhang, J. Jung and A. H. MacDonald,
Journal of Physics: Conf. Ser. 334 012002 (2011).
17. ‘Electronic Highways in Bilayer Graphene’,
Z. Qiao, J. Jung, Q. Niu, A. H. MacDonald,
Nano Letters 11 (7), 2579 (2011).
16. ‘Valley-Hall Kink and Edge States in Multilayer Graphene’,
J. Jung, F. Zhang, Z. Qiao and A. H. MacDonald,
Physical Review B 84, 075418 (2011).
15. ‘Enhancement of non-local exchange near isolated band-crossings in graphene’,
J. Jung and A. H. MacDonald,
Physical Review B 84, 075418 (2011).
14. ‘Non-local exchange effects in zigzag edge magnetism of neutral graphene nanoribbons’,
J. Jung, Phys. Rev. B 83, 165415 (2011).
13. ‘Spontaneous Quantum Hall States in Chirally-stacked Few-Layer Graphene Systems’,
F. Zhang, J. Jung, G. A. Fiete, Q. Niu, A. H. MacDonald,
Physical Review Letters 106, 156801 (2011).
12. ‘Lattice Theory of Pseudospin Ferromagnetism in Bilayer Graphene: Competing Orders and Interaction Induced Quantum Hall States’,
J. Jung, F. Zhang and A. H. MacDonald,
Physical Review B 83, 115408 (2011).
Before 2010
11. ‘Magneto-electric coupling in zigzag graphene nanoribbons’,
J. Jung and A. H. MacDonald,
Physical Review B 81, 195408 (2010).
10. ‘Theory of the Magnetic-Field-Induced Insulator in Neutral Graphene’,
J. Jung and A. H. MacDonald,
Physical Review B 80, 235417 (2009).
9. ‘Carrier Density and Magnetism in Graphene Zigzag Nanoribbons’,
J. Jung and A. H. MacDonald,
Physical Review B 79, 235433 (2009).
8. ‘Theory of inter-edge superexchange in zigzag edge magnetism’,
J. Jung, T. Pereg-Barnea, and A. H. MacDonald,
Physical Review Letters 102, 227205 (2009).
7. ‘Ab initio formulation of the four-point conductance of interacting electronic systems’,
P. Bokes, J. Jung, and R. W. Godby,
Physical Review B 76, 125433 (2007).
6. Comment on 'Dynamical Corrections to the DFT-LDA Electron Conductance in Nanoscale Systems'
J. Jung, P. Bokes, and R. W. Godby,
Physical Review Letters 98, 259701 (2007).
5. ‘Self-consistent density functional calculation of the image potential at a metal surface’,
J. Jung, J. E. Alvarellos , E. Chacon and P. Garcia-Gonzalez,
Journal of Physics: Condensed Matter 19, 266008 (2007).
4. ‘Effects beyond the random-phase approximation in calculating the interaction between metal films’,
J. Jung, P. Garcia-Gonzalez, J. F. Dobson, and R. W. Godby,
Physical Review B 70, 205107 (2004).
3. ‘Assessment of density-functional approximations: Long-range correlations and self-interaction effects’,
J. Jung, P. Garcia-Gonzalez, J. E. Alvarellos, and R. W. Godby,
Physical Review A 69, 052501 (2004).
2. ‘Two interacting electrons confined within a sphere: An accurate solution’,
J. Jung and J. E. Alvarellos,
Journal of Chemical Physics 118, 10825 (2003).
1. ‘Spin-isospin excitations and beta-decay of proton rich nuclei’,
E. Moya de Guerra, P. Sarriguren, A. Escuderos, J. Jung,
Nuclear Physics A 690, 276 (2001).