Nanoscale Optics Laboratory
Nanoscale Optics Laboratory
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Publications
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Selected Journal
Publications:
2024
137. S. Roy, X. Yang, and J. Gao, "Biaxial strain tuned upconversion photoluminescence of monolayer WS2," Scientific Reports, 14, 3860 (2024). [
136. S. Roy, J. Gao, and X. Yang, "Upconversion photoluminescence of monolayer WSe2 with biaxial strain tuning," Optics Express, 32, 3308-3315 (2024). [
135. S. Roy, X. Yang, and J. Gao, "Uniaxial strain tuning of upconversion photoluminescence in monolayer WSe2," Advanced Photonics Research, 2300220 (2024). [
2023
134. F. Meng, X. Yang, and J. Gao, "Phonon-assisted upconversion photoluminescence of monolayer MoS2 at elevated temperatures," Optics Express, 31, 28437-28443 (2023). [
133. F. Meng, X. Yang, and J. Gao, "High-temperature phonon-assisted upconversion photoluminescence of monolayer WSe2," Applied Physics Letters, 123, 013502 (2023). [
132. X. Zeng, D. Rosenmann, D. A. Czaplewski, J. Gao, and X. Yang, "Chiral metasurfaces of wavy rectangle resonators with tunable circular dichroism," Optik, 286, 171024 (2023). [
131. H. Tang, L. Stan, D. A. Czaplewski, X. Yang, and J. Gao, "Wavelength-tunable infrared chiral metasurfaces with phase-change materials," Optics Express, 31, 21118-21127 (2023). [
2022
130. A. Mushtaq, X. Yang, and J. Gao, "Unveiling room temperature upconversion photoluminescence in monolayer WSe2," Optics Express, 30, 45212-45220 (2022). [
129. L. Bindi, A. Dasgupta, P. Mukherjee, J. Gao, X. Yang, and J. A. Jaszczak, "Misfit-generated structural and optical anisotropies of the natural MoS2-PbS van der Waals heterostructure merelaniite," Physical Review Materials, 6, 115202 (2022). [
128. A. Dasgupta, D. I. Belakovskiy, I. V. Chaplygin, J. Gao, and X. Yang, "Large in-plane vibrational and optical anisotropy in natural 2D heterostructure abramovite," Scientific Reports, 12, 16803 (2022). [
127. X. Zeng, D. Rosenmann, D. A. Czaplewski, J. Gao, and X. Yang, "Mid-infrared chiral metasurface absorbers with split-ellipse structures," Optics Communications, 525, 128854 (2022). [
126. R. P. N. Tripathi, X. Yang, and J. Gao, "Anisotropic third-harmonic generation of exfoliated As2S3 thin flakes," Optics Express, 30, 22661-22670 (2022). [
125. A. Dasgupta, X. Yang, and J. Gao, "Natural 2D layered mineral cannizzarite with anisotropic optical responses," Scientific Reports, 12, 10006 (2022). [
124. H. Tang, D. Rosenmann, D. A. Czaplewski, X. Yang, and J. Gao, "Dual-band selective circular dichroism in mid-infrared chiral metasurfaces," Optics Express, 30, 20063-20075 (2022). [
123. R. P. N. Tripathi, J. Gao, and X. Yang, "Natural layered mercury antimony sulfosalt livingstonite with anisotropic optical properties," Optics Express, 30, 19611-19628 (2022). [
122. R. P. N. Tripathi, X. Yang, and J. Gao, "Polarization-sensitive optical responses from natural layered hydrated sodium sulfosalt gerstleyite," Scientific Reports, 12, 4242 (2022). [
2021
121. A. Dasgupta, X. Yang, and J. Gao, "Naturally occurring van der Waals heterostructure lengenbachite with strong in-plane structural and optical anisotropy," npj 2D Materials and Applications, 5, 88 (2021). [
120. A. Dasgupta, J. Gao, and X. Yang, "Naturally occurring 2D heterostructure nagyagite with anisotropic optical properties," Advanced Materials Interfaces, 2021, 2101106 (2021). [
119. R. P. N. Tripathi, J. Gao, and X. Yang, "Anisotropic optical responses of layered thallium arsenic sulfosalt gillulyite," Scientific Reports, 11, 22002 (2021). [
118. R. P. N. Tripathi, X. Yang, and J. Gao, "Polarization-dependent optical responses in natural 2D layered mineral teallite," Scientific Reports, 11, 21895 (2021). [
117. R. P. N. Tripathi, X. Yang, and J. Gao, "Van der Waals layered mineral getchellite with anisotropic linear and nonlinear optical responses," Laser & Photonics Reviews, 15, 2100182 (2021). [
116. A. Dasgupta, J. Gao, and X. Yang, "Natural van der Waals heterostructure cylindrite with highly anisotropic optical responses," npj 2D Materials and Applications, 5, 74 (2021). [
115. R. P. N. Tripathi, J. Gao, and X. Yang, "Naturally occurring layered mineral franckeite with anisotropic Raman scattering and third-harmonic generation responses," Scientific Reports, 11, 8510 (2021). [
114. H. Sar, J. Gao, and X. Yang, "2D layered SiP as anisotropic nonlinear optical material," Scientific Reports, 11, 6372 (2021). [
2020
113. X. Yang, and J. Gao, "Broadband and chiral infrared plasmonic metasurface absorbers," Annual Review of Heat Transfer, 23, 199-229 (2020). [
112. S. Mahmud, D. Rosenmann, D. A. Czaplewski, J. Gao, and X. Yang, "Chiral plasmonic metasurface absorbers in mid-infrared wavelength range," Optics Letters, 45, 5372-5375 (2020). (Editors' Pick) [
111. A. Dasgupta, X. Yang, and J. Gao, "Nonlinear beam shaping with binary phase modulation on patterned WS2 monolayer," ACS Photonics, 7, 2506-2514 (2020). [
110. H. Sar, J. Gao, and X. Yang, "In-plane anisotropic third-harmonic generation from germanium arsenide thin flakes," Scientific Reports, 10, 14282 (2020). [
109. S. Mahmud, D. Rosenmann, D. A. Czaplewski, J. Gao, and X. Yang, "Plasmon-phonon coupling between mid-infrared chiral metasurfaces and molecular vibrations," Optics Express, 28, 21192-21201 (2020). (Editors' Pick) [
108. W. Cao, J. Gao, and X. Yang, "Determination of effective parameters of fishnet metamaterials with vortex based interferometry," Optics Express, 28, 20051-20061 (2020). [
107. L. Ouyang, D. Rosenmann, D. Czaplewski, J. Gao, and X. Yang, "Broadband infrared circular dichroism in chiral metasurface absorbers," Nanotechnology, 31, 295203 (2020). [
106. A. Dasgupta, J. Gao, and X. Yang, "Anisotropic third-harmonic generation in layered germanium selenide," Laser & Photonics Reviews, 14, 1900416 (2020). [
2019
105. Y. Zhang, X. Yang, and J. Gao, "Generation of polarization singularities with geometric metasurfaces," Scientific Reports, 9, 19656 (2019). [
104. A. Dasgupta, X. Yang, and J. Gao, "Nonlinear conversion of orbital angular momentum in tungsten disulfide monolayer," Journal of Optics, 21, 125404 (2019). [
103. Z. Li, D. Rosenmann, D. Czaplewski, X. Yang, and J. Gao, "Strong circular dichroism in chiral plasmonic metasurfaces optimized by micro-genetic algorithm," Optics Express, 27, 28313-28323 (2019). [
102. A. Dasgupta, J. Gao, and X. Yang, "Atomically thin nonlinear transition metal dichalcogenide holograms," Nano Letters, 19, 6511-6516 (2019). [
101. Y. Zhang, J. Gao, and X. Yang, "Optical vortex transmutation with geometric metasurfaces of rotational symmetry breaking," Advanced Optical Materials, 7, 1901152 (2019). [
100. Y. Zhang, J. Gao, and X. Yang, "Spatial variation of vector vortex beams with plasmonic metasurfaces," Scientific Reports, 9, 9969 (2019). [
99. Y. Zhang, X. Yang, and J. Gao, "Generation of nondiffracting vector beams with ring-shaped plasmonic metasurfaces," Physical Review Applied, 11, 064059 (2019). [
98. Y. Zhang, X. Yang, and J. Gao, "Orbital angular momentum transformation of optical vortex with aluminum metasurfaces," Scientific Reports, 9, 9133 (2019). [
97. A. Dasgupta, J. Gao, and X. Yang, "Second-harmonic optical vortex conversion from WS2 monolayer," Scientific Reports, 9, 8780 (2019). [
96. L. Li, C. J. Mathai, S. Gangopadhyay, X. Yang, and J. Gao, "Spontaneous emission rate enhancement with aperiodic Thue-Morse multilayer," Scientific Reports, 9, 8473 (2019). [
95. Y. Chen, X. Yang, and J. Gao, "3D Janus plasmonic helical nanoapertures for polarization-encrypted data storage," Nature - Light: Science & Applications, 8, 45 (2019). [
94. M. Akbari, J. Gao, and X. Yang, "Manipulating transverse photovoltage across plasmonic triangle holes of symmetry breaking," Applied Physics Letters, 114, 171102 (2019). [
93. W. Liu, X. Yang, and J. Gao, "Optical transportation and accumulation of micro-particles by self-accelerating cusp beams," Physical Review A, 99, 043839 (2019). [
92. Y. Zhang, J. Gao, and X. Yang, "Topological charge inversion of optical vortex with geometric metasurfaces," Advanced Optical Materials, 7, 1801486 (2019). [
91. Y. Chen, J. Gao, and X. Yang, "Chiral grayscale imaging with plasmonic metasurfaces of stepped nanoapertures," Advanced Optical Materials, 7, 1801467 (2019). [
90. W. Wang, X. Yang, T. S. Luk, and J. Gao, "Enhanced quantum dots spontaneous emission with metamaterial perfect absorbers," Applied Physics Letters, 114, 021103 (2019). [
89. W. Wang, X. Yang, and J. Gao, "Scaling law of Purcell factor in hyperbolic metamaterial cavities with dipole excitation," Optics Letters, 44, 471-474 (2019). [
88. Z. Li, L. Stan, D. Czaplewski, X. Yang, and J. Gao, "Broadband infrared binary-pattern metasurface absorbers with micro genetic algorithm optimization," Optics Letters, 44, 114-117 (2019). [
2018
87. L. Ouyang, W. Wang, D. Rosenmann, D. Czaplewski, J. Gao, and X. Yang, "Near-infrared chiral plasmonic metasurface absorbers," Optics Express, 26, 31484-31489 (2018). [
86. Y. Chen, X. Yang, and J. Gao, "Spin-controlled wavefront shaping with plasmonic chiral geometric metasurfaces," Nature - Light: Science & Applications, 7, 84 (2018). [
85. W. Liu, J. Gao, and X. Yang, "Optical transportation of micro-particles by non-diffracting Weber beams," Journal of Optics, 20, 125401 (2018). [
84. Y. Chen, J. Gao, and X. Yang, "Direction-controlled bifunctional metasurface polarizers," Laser & Photonics Reviews, 12, 1800198 (2018). [
83. M. Akbari, J. Gao, and X. Yang, "Generation of transverse photo-induced voltage in plasmonic metasurfaces of triangle holes," Optics Express, 26, 21194-21203 (2018). [
82. Y. Chen, X. Yang, and J. Gao, "Spin-selective second-harmonic vortex beam generation with Babinet-inverted plasmonic metasurfaces," Advanced Optical Materials, 6, 1800646 (2018). [
81. W. Liu, Y. Zhang, J. Gao, and X. Yang, "Generation of three-dimensional optical cusp beams with ultrathin metasurfaces," Scientific Reports, 8, 9493 (2018). [
80. Y. Zhang, X. Yang, and J. Gao, "Twisting phase and intensity of light with plasmonic metasurfaces," Scientific Reports, 8, 4884 (2018). [
79. H. Deng, C. J. Mathai, S. Gangopadhyay, J. Gao, and X. Yang, "Ultra-broadband infrared absorption by tapered hyperbolic multilayer waveguides," Optics Express, 26, 6360-6370 (2018). [
78. Z. Li, L. Stan, D. Czaplewski, X. Yang, and J. Gao, "Wavelength-selective mid-infrared metamaterial absorbers with multiple tungsten cross resonators," Optics Express, 26, 5616-5631 (2018). [
77. Y. Zhang, W. Liu, J. Gao, and X. Yang, "Generating focused 3D perfect vortex beams by plasmonic metasurfaces," Advanced Optical Materials, 6, 1701228 (2018). [
76. Y. Chen, J. Gao, and X. Yang, "Chiral metamaterials of plasmonic slanted nanoapertures with symmetry breaking," Nano Letters, 18, 520-527 (2018). [
2017
75. J. Zeng, T. S. Luk, J. Gao, and X. Yang, "Structured light generation by magnetic metamaterial half-wave plates at visible wavelength," Journal of Optics, 19, 125103 (2017). [
74. H. Deng, L. Stan, D. Czaplewski, J. Gao, and X. Yang, "Broadband infrared absorbers with stacked double chromium ring resonators," Optics Express, 25, 28295-28304 (2017). [
73. J. Zeng, T. S. Luk, J. Gao, and X. Yang, "Spiraling light with magnetic metamaterial quarter-wave turbines," Scientific Reports, 7, 11824 (2017). [
72. W. Wan, J. Gao, and X. Yang, "Metasurface holograms for holographic imaging," Advanced Optical Materials, 5, 1700541 (2017). [
71. L. Sun, J. Gao, and X. Yang, "Klein tunneling near the Dirac points in metal-dielectric multilayer metamaterials," Scientific Reports, 7, 9678 (2017). [
70. W. Cao, X. Yang, and J. Gao, "Broadband polarization conversion with anisotropic plasmonic metasurfaces," Scientific Reports, 7, 8841 (2017). [
69. W. Wang, D. Rosenmann, D. Czaplewski, X. Yang, and J. Gao, "Realizing structural color generation with aluminum plasmonic V-groove metasurfaces," Optics Express, 25, 20454-20465 (2017). [
68. L. Li, W. Wang, T. S. Luk, X. Yang, and J. Gao, "Enhanced quantum dot spontaneous emission with multilayer metamaterial nanostructures," ACS Photonics, 4, 501-508 (2017). [
2016
67. W. Wan, J. Gao, and X. Yang, "Full-color plasmonic metasurface holograms," ACS Nano, 10, 10671-10680 (2016). [
66. Z. Li*, W. Wang*, D. Rosenmann, D. Czaplewski, X. Yang, and J. Gao, "All-metal structural color printing based on aluminum plasmonic metasurfaces," (*equal contribution), Optics Express, 24, 20472-20480 (2016). [
65. J. Zeng, L. Li, X. Yang, and J. Gao, "Generating and separating twisted light by gradient-rotation split-ring antenna metasurfaces," Nano Letters, 16, 3101-3108 (2016). [
64. W. Wan, X. Yang, and J. Gao, "Strong coupling between mid-infrared localized plasmons and phonons," Optics Express, 24, 12367-12374 (2016). [
63. J. Maser, L. Li, H. Deng, X. Yang, and J. Rovey, "Transmission spectrum of asymmetric nanostructures for plasmonic space propulsion," Journal of Spacecraft and Rockets, 53, 998-1000 (2016). [
62. L. Sun, X. Yang, and J. Gao, "Analysis of nonlocal effective permittivity and permeability in symmetric metal-dielectric multilayer metamaterials," Journal of Optics, 18, 065101 (2016). [
61. L. Sun, J. Gao, and X. Yang, "Optical nonlocality induced Zitterbewegung near the Dirac point in metal-dielectric multilayer metamaterials," Optics Express, 24, 7055-7062 (2016). [
2015
60. F. Cheng, X. Yang, and J. Gao, "Ultrasensitive detection and characterization of molecules with infrared plasmonic metamaterials," Scientific Reports, 5, 14327;
doi:10.1038/srep14327 (2015). [
59. J. Zeng, J. Gao, T. S. Luk, N. M. Litchinitser, and X. Yang, "Structuring Light by Concentric-Ring Patterned Magnetic Metamaterial Cavities," Nano Letters, 15, 5363-5368 (2015). [
58. F. Cheng, X. Yang, D. Rosenmann, L. Stan, D. Czaplewski, and J. Gao, "Enhanced structural color generation in aluminum metamaterials coated with a thin polymer layer," Optics Express, 23, 25329-25339 (2015). [
57. T. Geng, S. Zhuang, J. Gao, and X. Yang, "Nonlocal effective medium approximation for metallic nanorod metamaterials," Physical Review B, 91, 245128 (2015). [
56. F. Cheng, J. Gao, L. Stan, D. Rosenmann, D. Czaplewski, and X. Yang, "Aluminum plasmonic metamaterials for structural color printing," Optics Express, 23, 14552-14560 (2015). [
55. L. Sun, Z. Li, T. S. Luk, X. Yang, and J. Gao, "Nonlocal effective medium analysis in symmetric metal-dielectric multilayer metamaterials," Physical Review B, 91, 195147 (2015). [
54. H. Deng*, Z. Li*, L. Stan, D. Rosenmann, D. Czaplewski, J. Gao, and X. Yang, "Broadband perfect absorber based on one ultrathin layer of refractory metal," (*equal contribution), Optics Letters, 40, 2592-2595 (2015). [
53. F. Cheng, J. Gao, T. S. Luk, and X. Yang, "Structural color printing based on plasmonic metasurfaces of perfect light absorption," Scientific Reports, 5, 11045; doi: 10.1038/srep11045 (2015). [
52. J. Rovey, P. D. Friz, C. Hu, M. S. Glascock, and X. Yang, "Plasmonic force space propulsion," Journal of Spacecraft and Rockets, 52, 1163-1168 (2015); doi: 10.2514/1.A33155. [
51. L. Sun, X. Yang, W. Wang, and J. Gao, "Diffraction-free optical beam propagation with near-zero phase variation in extremely anisotropic metamaterials," Journal of Optics, 17, 035101 (2015). [
2014
50. L. Sun, F. Cheng, C. J. Mathai, S. Gangopadhyay, J. Gao, and X. Yang, "Experimental characterization of optical nonlocality in metal-dielectric multilayer metamaterials," Optics Express, 22, 22974-22980 (2014). [
49. Z. Li, S. Cakmakyapan, B. Butun, C. Daskalaki, S. Tzortzakis, X. Yang, and E. Ozbay, "Fano resonances realized in THz metamaterials composed of continuous metallic wires and split ring resonators," Optics Express, 22, 26572-26584 (2014). [
48. L. Sun, J. Gao, and X. Yang, "Realizing broadband electromagnetic transparency with a graded-permittivity sphere," Journal of Optics, 16, 085101 (2014). [
47. F. Cheng, X. Yang, and J. Gao, "Enhancing intensity and refractive index sensing capability with infrared plasmonic perfect absorbers," Optics Letters, 39, 3185-3188 (2014). [
46. H. Deng, T. Wang, J. Gao, and X. Yang, "Metamaterial thermal emitters based on nanowire cavities for high-efficiency thermophotovoltaics," Journal of Optics, 16, 035102 (2014). [
45. J. Gao, and X. Yang, "Anomalous optical coupling between two silicon wires of a slot waveguide in epsilon-near-zero metamaterials," Optics Communications, 314, 18-22 (2014). [
2013
44. L. Sun, X. Yang, and J. Gao, "Loss-compensated broadband epsilon-near-zero metamaterials with gain media," Applied Physics Letters, 103, 201109 (2013). [
43. P. A. Huidobro, S. Ota, X. Yang, X. Yin, F.J. Garcia-Vidal, and X. Zhang, "Plasmonic Brownian Ratchet," Physical Review B (Rapid Communication), 88, 201401(R) (2013); selected as an Editor's Suggestion. [
42. X. R. Jin, L. Sun, X. Yang, and J. Gao, "Quantum entanglement in plasmonic waveguides with near-zero mode indices," Optics Letters, 38, 4078-4081 (2013). [
41. X. Yang, C. Hu, H. Deng, D. Rosenmann, D. A. Czaplewski, and J. Gao, "Experimental demonstration of near-infrared epsilon-near-zero multilayer metamaterial slabs," Optics Express, 21, 23631-23639 (2013). [
40. H. Zhou, H. Deng, S. A. Ghetmiri, H. H. Abu-Safe, S. Q. Yu, X. Yang*, and Z. R. Tian*, "Optimizing height and packing-density of oriented one-dimensional photocatalysts for efficient water-photoelectrolysis," (*corresponding authors), The Journal of Physical Chemistry C, 117 (40), 20778-20783 (2013). [
39. L. Sun, J. Gao, and X. Yang, "Giant optical nonlocality near the Dirac point in metal-dielectric multilayer metamaterials," Optics Express, 21, 21542-21555 (2013). [
38. J. Gao, L. Sun, H. Deng, C. J. Mathai, S. Gangopadhyay, and X. Yang, "Experimental realization of epsilon-near-zero metamaterial slabs with metal-dielectric multilayers," Applied Physics Letters, 103, 051111 (2013). [
37. L. Sun, J. Gao, and X. Yang, "Broadband epsilon-near-zero metamaterials with step-like metal-dielectric multilayer structures," Physical Review B, 87, 165134 (2013). [
36. Y. He*, L. Sun*, S. He, and X. Yang, "Deep subwavelength beam propagation in extremely loss-anisotropic metamaterials," (*equal contribution), Journal of Optics, 15, 055105 (2013). [
35. Y. He, H. Deng, X. Jiao, S. He, J. Gao, and X. Yang, "Infrared perfect absorber based on nanowire metamaterial cavities," Optics Letters, 38, 1179-1181 (2013). [
34. X. Yang, "MEMS enabled reconfigurable electromagnetic metamaterials," Journal of Optics, invited commentary in the special issue on Switchable and Reconfigurable Metamaterials (2013). [link].
2012
33. L. Sun, S. Feng, and X. Yang, "Loss enhanced transmission and collimation in anisotropic epsilon-near-zero metamaterials," Applied Physics Letters, 101, 241101 (2012). [
32. X. Yang, J. Yao, J. Rho, X. Yin,
and X. Zhang, "Experimental realization of three-dimensional indefinite cavities at the nanoscale with anomalous scaling laws," Nature Photonics, 6, 450-454 (2012). [
31. Y. He, S. He, J. Gao,
and X. Yang, "Giant optical forces in nanoscale slot waveguides of hyperbolic metamaterials," Optics Express, 20, 22372-22382 (2012). [
30. L. Sun, K. W. Yu, and X. Yang, "Integrated optical devices based on broadband epsilon-near-zero meta-atoms," Optics Letters, 37, 3096-3098 (2012). [
29. Y. He, S. He, and X. Yang, "Optical field enhancement in nanoscale slot waveguides of hyperbolic metamaterials," Optics Letters, 37, 2907-2909 (2012). [
28. Y. He, S. He, J. Gao,
and X. Yang, "Nanoscale metamaterial optical waveguides with ultrahigh refractive indices," Journal of the Optical Society of America B, 29, 2559-2566 (2012). [
2011
27. X. Yang, Y. Liu, R. F. Oulton, X. Yin,
and X. Zhang, "Optical forces in hybrid plasmonic waveguides," Nano Letters, 11, 321-328 (2011). [
26. X. Yang, A. Ishikawa, X. Yin, and X. Zhang, "Hybrid
photonic-plasmonic crystal nanocavities," ACS Nano,
5, 2831-2838 (2011).
25. J. Yao, X. Yang, X. Yin, G. Bartal,
and X. Zhang, "Three-dimensional nanometer-scale optical cavities of
indefinite medium," Proc. Natl. Acad. Sci. U.S.A. 108, 11327-11331
(2011).
2010 and before
24. X. Yang, M. Yu, D. L. Kwong, and
C. W. Wong, "Coupled resonances in multiple silicon photonic crystal cavities
in all-optical solid-state analog to electromagnetically-induced
transparency," IEEE Journal of Selected Topics in Quantum Electronics,
16, 288-294 (2010).
23. X. Yang, M. Yu, D. L. Kwong, and
C. W. Wong, "All-optical analogue to electromagnetically induced transparency
in multiple coupled photonic crystal nanocavities," Physical Review
Letters, 102, 173902 (2009).
22. T. Gu, S. Kocaman, X. Yang, J. F. McMillan, M. B. Yu, G.-Q. Lo, D.-L. Kwong,
and C. W. Wong, "Deterministic integrated tuning of multi-cavity resonances
and phase for slow-light in coupled photonic crystal cavities," Applied
Physics Letters, 98, 121103
(2011).
21. S. Kocaman, X. Yang, J. F.
McMillan, M. Yu, D. L. Kwong, and C. W. Wong, "Observations of temporal group delays in slow-light multiple coupled
photonic crystal cavities," Applied Physics Letters, 96, 221111
(2010).
20. Y. F. Xiao, J. Gao, J. F. McMillan, X.
Yang, Y.-L. Chen, Z.-F. Han, G.-C. Guo, and C.
W. Wong, "Coupled quantum electrodynamics in photonic crystal nanocavities
towards controlled phase gate operations," New Journal of Physics, 10, 123013 (2008).
19. X. Yang, C. Chen, C. Husko, and C.
W. Wong, "Digital resonance tuning of high-Q/Vm silicon photonic crystal nanocavities by atomic layer deposition," Applied
Physics Letters, 91, 161114 (2007). [
18. X. Yang, C. Husko, M. Yu, D. L. Kwong, and C. W. Wong, "Observation of femto-joule optical bistability involving Fano resonances in high-Q/Vm silicon photonic crystal nanocavities," Applied Physics Letters, 91, 051113 (2007).
17. X. Yang and C. W. Wong, "Coupled-mode theory for stimulated
Raman scattering in high-Q/Vm silicon photonic band gap nanocavity lasers," Optics Express, 15,
4763-4780 (2007).
16. X. Yang and C. W. Wong, "Stimulated Raman amplification and
lasing in silicon photonic band gap nanocavities," Sensors and Actuators
A: Physical, 133, 278-282 (2007).
15. R. Bose, X. Yang, R. Chatterjee,
J. Gao, and C. W. Wong, "Weak coupling interactions
of colloidal lead sulphide (PbS) nanocrystals with silicon photonic crystal
nanocavities near 1.55 um at room temperature," Applied
Physics Letters, 90, 111117 (2007).
14. J. Gao, P. Heider,
C. Chen, X. Yang, C. Husko, and C. W. Wong, "Observations of whispering gallery modes in asymmetric optical resonators
with rational caustics," Applied
Physics Letters, 91, 181101 (2007).
13. Y. F. Xiao, J. Gao, X. Yang, R.
Bose, G. C. Guo, and C. W. Wong, "Nanocrystals in silicon photonic crystal standing-wave
cavities as spin-photon phase gates for quantum information processing," Applied Physics Letters, 91, 151105
(2007). [
12. J. F. McMillan, X. Yang, N. C. Paniou,
R. M. Osgood, and C. W. Wong, "Enhanced stimulated Raman scattering in
slow-light photonic crystal waveguides," Optics Letters, 31, 1235
(2006). [
11. X. Yang and C. W. Wong, "Design of photonic band gap
nanocavities for stimulated Raman amplification and lasing in monolithic
silicon," Optics Express, 13, 4723-4730 (2005).
10. X. Yang, H. Ma, and Y. -N Huang, "Prediction of homogeneous shear flow and a backward-facing step flow with linear and nonlinear turbulence models," Communications in Nonlinear Science and Numerical Simulation, 10, 315-328 (2005).
8. X. Yang and H. Ma, "Computation of strongly swirling confined
flows with cubic eddy-viscosity turbulence models," International Journal
for Numerical Methods in Fluids, 43, 1355 (2003).
7. X. Yang and H. Ma, "Linear and nonlinear eddy-viscosity
turbulence models for a confined swirling co-axial jet," Numerical Heat
Transfer: Part B: Fundamentals, 43, 289- 305 (2003).
6. X. Yang and H. Ma, "Study of separated flow in a diffuser
using linear and nonlinear eddy-viscosity turbulence models," Acta Aerodynamica Sinica, 22, 29-35 (2004).
5. X. Yang and H. Ma, "Modeling of turbulent transonic flows with linear and nonlinear eddy-viscosity turbulence models," Journal of the Graduate School of the Chinese Academy of Sciences, 21, 454-461 (2004).
4. X. Yang and H. Ma, "Nonlinear turbulence models in
shock/boundary-layer interaction," Acta Mechanica Sinica, 35, 57-63
(2003).
3. X. Yang, J. Zhu, and H. Ma, "Nonlinear and multiple-scale turbulence models in shock/boundary-layer interaction," Journal of University of Science and Technology of China, 1, 191-196 (2003).
2. X. Yang and H. Ma, "Investigation of nonlinear turbulence models for separated supersonic flows," Acta Aerodynamica Sinica, 20, 458-464 (2002).
1. X. Yang and H. Ma, "Assessment of linear eddy-viscosity turbulence models in shock/boundary-layer interaction," Journal of Aerospace Power, 17, 273-279 (2002).
Book Chapters:
1. C. W. Wong, X. Yang, R. Chatterjee,
S. Kocaman, J. F. McMillan, and C. J. Chen, "Controlling dispersion and nonlinearities in mesoscopic silicon photonic crystals," in VLSI
Micro/Nanophotonics: Science, Technology, Applications, book chapter, CRC Press Taylor & Francis Group, ISBN: 9781574447293, Boca Rato, FL 33487, 2010. [link]
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