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Theses and Dissertations
Dominic Bosomtwi‘s Ph.D. Dissertation “Optical responses of hybrid electromagnetic nanostructures”
University of New Mexico, 2024
Michael A. Illescas’ M.S. Thesis “Improved experimental validation of an electromagnetic subcell model for narrow slots with depth”
University of New Mexico, 2023
Aoxue Han’s Ph.D. Dissertation “Linear and nonlinear optical properties in plasmonic and dielectric nanoparticle lattices”
University of Arizona, 2023
Babicheva’s Ph.D. Dissertation “Ultra-compact plasmonic waveguide modulators”
Technical University of Denmark, 2013
Book and Book Chapters
V.E. Babicheva and A.B. Evlyukhin, “Directional scattering of dielectric nanoantennas,” pp. 71–113, Chapter 4 in “All-Dielectric Nanophotonics,” Eds: A.S. Shalin, A. Canós Valero, A. Miroshnichenko, Elsevier, 2024
V.E. Babicheva “Subwavelength resonant nanostructures: fabrication and functionalities,” authored book – monograph, doi:10.9734/bpi/mono/978-81-19761-23-4, BP International, 96 p., 2023
Y. Abate, V.E. Babicheva, V.S. Yakovlev, and N. Dietz, “Towards understanding and control of nanoscale phase segregation in indium-gallium-nitride alloys,” pp. 183-207, Chapter 6 in “III-nitride materials, devices, and nano-structures,” 424 pages, Ed: Zhe Chuan Feng, World Scientific Publishing, 2017.
Articles
2024
76. V.E. Babicheva and A.B. Evlyukhin, “Mie-resonant metaphotonics,” Advances in Optics and Photonics 16, 539–658, 2024 [IF: 27.1]
75. V. Karimi and V.E. Babicheva, “MXene-antenna electrode with collective multipole resonances,” Nanoscale 16, 4656–4667, 2024 [IF: 6.7]
74. V.E. Babicheva and M. Rumi, “Chalcophosphate metasurfaces with multipolar resonances and electro-optic tuning,” RSC Advances 14, 33906, 2024 [IF: 3.9]
73. V.E. Babicheva, “Resonant metasurfaces with van der Waals hyperbolic nanoantennas and extreme light confinement,” Nanomaterials 14, 1539, 2024 [IF: 4.4]
72. A. Romero and V.E. Babicheva, “Enhanced light confinement in nonlocal resonant metasurfaces with weak multipolar scatterers,” Journal of Applied Physics 136, 083106, 2024 [*Editor’s Pick*; IF: 2.7]
71. V. Karimi and V.E. Babicheva, “Optical chirality in MXene nanoantenna arrays,” MRS Advances 9, 557–564, 2024 [IF: 0.8]
2023
70. M.S. Islam and V.E. Babicheva, “Lattice Mie resonances and emissivity enhancement in mid-infrared iron pyrite metasurfaces,” Optics Express 31, 40380–40392, 2023 [IF: 3.833]
69. V. Karimi and V.E. Babicheva, “Multipole Mie resonances in MXene-antenna arrays,” Journal of Physical Chemistry C 127, 17791–17801, 2023 [IF: 4.177]
68. A. Krasnok, V.E. Babicheva, and C. Rockstuhl, “Physics of complex photonic media and metamaterials: feature issue introduction,” Optical Materials Express 13, 2446–2448, 2023 [IF: 3.074]
67. V. Karimi and V.E. Babicheva, “Dipole-lattice nanoparticle resonances in finite arrays,” Optics Express 31, 16857–16871, 2023 [IF: 3.833]
66. M.S. Islam and V.E. Babicheva, “Lattice resonances of lossy transition metal and metalloid antennas,” MRS Advances 8, 138–147, 2023 [IF: 0.800]
65. D. Bosomtwi and V.E. Babicheva, “Beyond conventional sensing: Hybrid plasmonic metasurfaces and bound states in the continuum,” Nanomaterials 13, 1261, 2023 [IF: 5.719]
64. V.E. Babicheva, “Optical processes behind plasmonic applications,” Nanomaterials 13, 1270, 2023 [*feature paper*; IF: 5.719]
2022
63. A. Han, J.V. Moloney, V.E. Babicheva, “Applicability of multipole decomposition to plasmonic- and dielectric-lattice resonances,” Journal of Chemical Physics 156, 114104, 2022 [*invited paper*; IF: 3.488]
62. Z.-X. Zhou, M.-J. Ye, M.-W. Yu, J.-H. Yang, K.-L. Su, C.-C. Yang, C.-Y. Lin, V.E. Babicheva, I.V. Timofeev, and K.-P. Chen, “Germanium metasurfaces with lattice Kerker effect in near-infrared photodetectors,” ACS Nano 16, 5994–6001, 2022 [IF: 13.903]
2021
61. D. Bosomtwi, M. Osiński, and V. E. Babicheva, “Lattice effect for enhanced hot-electron generation in nanoelectrodes,” Optical Materials Express 11, 3232 (2021). [IF: 3.442]
60. V. Babicheva, Y. Sivan, K.-P. Chen, and A. Evlyukhin, “Plasmonics and hot electrons: feature issue introduction,” Optical Materials Express 11(11), 3686-3687 (2021). [IF: 3.442]
59. V. Karimi and V. E. Babicheva, “Semiconductor nanopillars for programmable directional lasing emissions,” MRS Advances 6(8), 234-240 (2021). [IF: 0.800]
58. V. E. Babicheva and A. Evlyukhin, “Multipole lattice effects in high refractive index metasurfaces,” Journal of Applied Physics 129, 040902 (2021). [IF: 2.328]
57. A. Han, C. Dineen, V. E. Babicheva, and J. V. Moloney, “Second Harmonic Generation in Metasurfaces with Multipole Resonant Coupling,” Nanophotonics 9, 3545–3556 (2020). [IF: 6.950]
56. J.-H. Yang, V.E. Babicheva, M.-W. Yu, T.-C. Lu, T.-R. Lin, K.-P. Chen, “Structural Colors Enabled by Lattice Resonance on Silicon Nitride Metasurfaces,” ACS Nano 14, 5678–5685 (2020). [IF: 13.903]
55. H. Ahmed and V.E. Babicheva, “Nanostructured Tungsten Disulfide WS2 as Mie Scatterers and Nanoantennas,” MRS Advances 5, 1819-1826 (2020). [IF: 0.800]
Link to read-only version without subscription
54. V.E. Babicheva and J. Moloney, “Lattice Zenneck modes on subwavelength antennas,” Laser & Photonics Reviews 13, 1800267 (2019). [IF: 8.529]
5-min video summarizing the main results
53. V.E. Babicheva, “Transition Metal Dichalcogenide Nanoantennas Lattice,” MRS Advances
4, 2283 (2019). [IF: 0.800]
Link to read-only version without subscription
52. V. Babicheva, I. Staude, D. Gerard, “Collective effects and coupling phenomena in resonant optical metasurfaces: introduction,” Journal of the Optical Society of America B (JOSA B), 36(7), CEC1-CEC3 (2019). [*SI intro*; IF: 2.048]
51. V.E. Babicheva and A. B. Evlyukhin, “Analytical model of resonant electromagnetic dipole-quadrupole coupling in nanoparticle arrays,”
Physical Review B 99, 195444 (2019). [IF: 3.813]
50. V.E. Babicheva and J. V. Moloney, “Lattice resonances in transdimensional WS2 nanoantenna arrays,” Applied Sciences 9, 2005 (2019). [*invited paper*; IF: 1.689]
49. V.E. Babicheva, “Multipole Resonances in Transdimensional Lattices of Plasmonic and Silicon Nanoparticles,” MRS Advances 4, 713-722 (2019). [IF: 0.800]
Link to read-only version without subscription
48. P.D. Terekhov, V.E. Babicheva, K. Baryshnikova, A. Shalin, A. Karabchevsky, A. B. Evlyukhin, “Multipole analysis of dielectric metasurfaces composed of nonspherical nanoparticles and lattice invisibility effect,” Physical Review B 99, 045424 (2019). [IF: 3.813]
47. V.E. Babicheva and J. Moloney, “Lattice effect influence on the electric and magnetic dipole resonance overlap in a disk array,”
Nanophotonics 7(10), 1663-1668 (2018). [*invited paper*; IF: 6.014] arXiv link
3-min video summarizing the main results
46. V.E. Babicheva, “Lattice effect in Mie-resonant dielectric nanoparticle array under the oblique light incidence,” MRS Communications 8, 1455-1462 (2018).[*invited paper*; IF: 3.010] arXiv link
Link to read-only version without subscription
2-min video summarizing the main results
45. V.E. Babicheva and A.B. Evlyukhin, “Resonant suppression of light transmission in high-refractive-index nanoparticle metasurfaces,” Optics Letters 43(21), 5186-5189 (2018). [IF: 3.589] arXiv link
44. V.E. Babicheva, “Lattice Kerker effect in the array of hexagonal boron nitride antennas,” MRS Advances 3, 2783-2788 (2018). [IF: 0.800] arXiv link
Link to read-only version without subscription
43. V.E. Babicheva and A.B. Evlyukhin, “Interplay and coupling of electric and magnetic multipole resonances in plasmonic nanoparticle lattices,”
MRS Communications 8, 712-717 (2018).
[*invited Prospective*; IF: 3.010] arXiv link
Link to read-only version without subscription
Highlighted in Materials360 Newsletters 18(13), 2018
42. V.E. Babicheva, S. Gamage, L. Zhen, S.B. Cronin, V.S. Yakovlev, Y. Abate, “Near-field Surface Waves in Few-Layer MoS2,” ACS Photonics 5, 2106 (2018). [IF: 6.756] arXiv link
41. V.E. Babicheva and A.B. Evlyukhin, “Metasurfaces with electric quadrupole and magnetic dipole resonant coupling,” ACS Photonics 5, 2022 (2018). [IF: 6.756] arXiv link
40. C.Y. Yang, J.H. Yang, Z.Y. Yang, Z.X. Zhou, M.G. Sun, V.E. Babicheva, K.P. Chen, “Nonradiating Silicon Nanoantenna Metasurfaces as Narrow-band Absorbers,” ACS Photonics 5, 2596 (2018). [IF: 6.756]
39. V.E. Babicheva, “Directional scattering by the hyperbolic-medium antennas and silicon particles,” MRS Advances 3, 1913 (2018). [IF: 0.800] arXiv link
Link to read-only version without subscription
38. V.E. Babicheva and A.B. Evlyukhin, “Resonant Lattice Kerker Effect in Metasurfaces with Electric and Magnetic Optical Responses,” Laser & Photonics Reviews 11, 1700132 (2017). [IF: 8.434] arXiv link
5-min video summarizing the main results
37. V.E. Babicheva, “Long-range propagation of plasmon and phonon polaritons in hyperbolic-metamaterial waveguides,” Journal of Optics 19, 124013 (2017). [*invited paper* in SI Emerging Leaders; IF: 1.741] arXiv link
36. V.E. Babicheva, S. Gamage, M.I. Stockman, and Y. Abate, “Near-field edge fringes at sharp material boundaries,” Optics Express 25, 23935-23944 (2017). [IF: 3.307] arXiv link
35. V.E. Babicheva, M. Petrov, K. Baryshnikova, P. Belov, “Reflection compensation mediated by electric and magnetic resonances of all-dielectric metasurfaces [Invited],” Journal of the Optical Society of America B (JOSA B) 34, D18-D28 (2017). [*invited paper* in SI Photonic Metadevices; IF: 1.731] arXiv link
34. Y. Abate, D. Seidlitz, A. Fali, S. Gamage, V. Babicheva, V. Yakovlev, M. Stockman, R. Collazo, D. Alden, N. Dietz, “Nanoscopy of Phase Separation in InxGa1-xN Alloys,” ACS Applied Materials & Interfaces 8, 23160–23166 (2016). [IF: 7.145]
33. A. Boulesbaa, V.E. Babicheva, K. Wang, I.I. Kravchenko, M.-W. Lin, M. Mahjouri-Samani, C. Jacob, A.A. Puretzky, K. Xiao, I. Ivanov, C.M. Rouleau, D.B. Geohegan,
“Ultrafast Dynamics of Metal Plasmons Induced by 2D Semiconductor Excitons in Hybrid Nanostructure Arrays,” ACS Photonics 3, 2389–2395 (2016). [IF: 5.404]
32. Y. Abate, S. Gamage, L. Zhen, S.B. Cronin, H. Wang, V. Babicheva, M.H. Javani, M.I. Stockman, “Nanoscopy reveals surface-metallic black phosphorus,” Light: Science & Applications 5, e16162 (2016). [IF: 14.603] arXiv link
31. K.V. Baryshnikova, M.I. Petrov, V.E. Babicheva, P.A. Belov, “Plasmonic and silicon spherical nanoparticle antireflective coatings,” Scientific Reports 6, 22136 (2016). [IF: 5.078]
30. A.V. Chebykin, V.E. Babicheva, I.V. Iorsh, A.A. Orlov, P.A. Belov, and
S.V. Zhukovsky, “Enhancement of the Purcell factor in multiperiodic hyperboliclike metamaterials,” Phys. Rev. A 93, 033855 (2016). [IF: 2.991]
29. S.V. Zhukovsky, I.E. Protsenko, R. Sh. Ikhsanov, I.V. Smetanin, V.E. Babicheva, A.V. Uskov, “Transition absorption as a mechanism of surface photoelectron emission from metals,” Physica Status Solidi (RRL)-Rapid Research Letters 9, 570-574 (2015). [IF: 2.343] arXiv link
28. V.E. Babicheva, M.Y. Shalaginov, S. Ishii, A. Boltasseva, and A.V. Kildishev, “Long-range plasmonic waveguides with hyperbolic cladding,” Optics Express 23, 31109-31119 (2015). [IF: 3.525]
27. V.E. Babicheva, A. Boltasseva, A.V. Lavrinenko, “Transparent conducting oxides for electro-optical plasmonic modulators,” Nanophotonics 4, 165-185 (2015). [*invited Review* in SI Emerging Materials for Nanophotonics; top 10 most downloaded papers of 2015; IF: 5.689]
26. V.E. Babicheva, M.Y. Shalaginov, S. Ishii, A. Boltasseva, and A.V. Kildishev, “Finite-width plasmonic waveguides with hyperbolic multilayer cladding,” Opt. Express 23, 9681-9689 (2015). [IF: 3.525]
Patent application citing the work Plasmonic waveguides and waveguiding methods
25. V.E. Babicheva, R.Sh. Ikhsanov, S.V. Zhukovsky, I.E. Protsenko, I.V. Smetanin, and A.V. Uskov, “Hot electron photoemission from plasmonic nanostructures: Role of surface photoelectric effect and transition absorption,” ACS Photonics 2, 1039-1048 (2015). [IF: 5.404] arXiv link
24. R.Sh. Ikhsanov, V.E. Babicheva, I.E. Protsenko, A.V. Uskov, M.E. Guzhva, “Bulk photoemission from metal films and nanoparticles,” Quantum Electronics 45, 50-58 (2015). [IF: 0.886]
23. V.E. Babicheva, S.V. Zhukovsky, A.V. Lavrinenko, “Bismuth ferrite as low-loss switchable material for plasmonic waveguide modulator,” Optics Express 22, 28890-28897 (2014). [IF: 3.525]
Patent application citing the work Electrooptic modulator
22. S.V. Zhukovsky, A. Orlov, V.E. Babicheva, A.V. Lavrinenko, J. E. Sipe, “Photonic-band-gap engineering for volume plasmon polaritons in multiscale multilayer hyperbolic metamaterials,” Phys. Rev. A 90, 013801 (2014). [IF: 2.991] arXiv link
Highlighted in SPIE Newsroom, Nanotechnology, October 2014, doi: 10.1117/2.1201410.005626
21. A.A. Orlov, A.K. Krylova, S.V. Zhukovsky, V.E. Babicheva, P.A. Belov, “Multi-periodicity in plasmonic multilayers: general description and diversity of topologies,” Phys. Rev. A 90, 013812 (2014). [IF: 2.991]
20. S.V. Zhukovsky, V.E. Babicheva, A.B. Evlyukhin, I.E. Protsenko, A.V. Lavrinenko, A.V. Uskov, “Giant photogalvanic effect in noncentrosymmetric plasmonic nanoparticles,” Phys. Rev. X 4, 031038 (2014). [IF: 9.043] arXiv link
19. A.A. Orlov, E.A. Yankovskaya, S.V. Zhukovsky, V.E. Babicheva, I.V. Iorsh, and P.A. Belov, “Retrieval of Effective Parameters of Subwavelength Periodic Photonic Structures,” Crystals 4, 417-426 (2014). [IF: 2.075]
18. S. Ishii, M. Y. Shalaginov, V.E. Babicheva, A. Boltasseva, and A.V. Kildishev, “Plasmonic waveguides cladded by hyperbolic metamaterials,” Optics Letters 39, 4663-4666 (2014). [IF: 3.179] arXiv link
Patent application citing the work Plasmonic waveguides and waveguiding methods
17. N. Kinsey, M. Ferrera, G.V. Naik, V.E. Babicheva, V.M. Shalaev, A. Boltasseva, “Experimental demonstration of titanium nitride plasmonic interconnects,” Optics Express 22, 12238-12247 (2014). [IF: 3.525]
16. S.V. Zhukovsky, V.E. Babicheva, A.V. Uskov, I.E. Protsenko, A.V. Lavrinenko, “Electron photoemission in plasmonic nanoparticle arrays: analysis of collective resonances and embedding effects,” Applied Physics A 116, 929-940 (2014). [IF: 1.694] arXiv link
15. A.V. Uskov, I.E. Protsenko, R.Sh. Ikhsanov, V.E. Babicheva, S.V. Zhukovsky, A.V. Lavrinenko, E.P. OReilly, H. Xu, “Internal photoemission from plasmonic nanoparticles: Comparison between surface and volume photoelectric effects,” Nanoscale 6, 4716-4727 (2014). [IF: 7.394] arXiv link
14. S.V. Zhukovsky, V.E. Babicheva, A.V. Uskov, I.E. Protsenko, A.V. Lavrinenko, “Enhanced electron photoemission by collective lattice resonances in plasmonic nanoparticle-array photodetectors and solar cells,” Plasmonics 9, 283-289 (2014). [IF: 2.738] arXiv link
13. V.E. Babicheva, N. Kinsey, G.V. Naik, M. Ferrera, A.V. Lavrinenko, V.M. Shalaev, A. Boltasseva, “Towards CMOS-compatible nanophotonics: Ultra-compact modulators using alternative plasmonic materials,” Optics Express 21, 27326-27337 (2013). [IF: 3.525]
Highlighted in SPIE Newsroom, Optoelectronics & Communications, May 2014, doi: 10.1117/2.1201404.005462
12. V.E. Babicheva, R. Malureanu, A.V. Lavrinenko, “Plasmonic finite-thickness metal-semiconductor-metal waveguide as ultra-compact modulator,” Photonics and Nanostructures – Fundamentals and Applications 11, 323–334 (2013). [#22 in the most cited PNFA articles published since 2012 as of 02/11/2017, IF: 1.350] arXiv link
11. V.E. Babicheva, A.V. Lavrinenko, “Plasmonic modulator based on metal-insulator-metal waveguide with barium titanate core,” Photonics Letters of Poland 5, 57-59 (2013). [IF: N/A]
10. V.E. Babicheva, I.V. Kulkova, R. Malureanu, K. Yvind, A.V. Lavrinenko, “Plasmonic modulator based on gain-assisted metal-semiconductor-metal waveguide,” Photonics and Nanostructures – Fundamentals and Applications 10, 389-399 (2012). [#4 in the most cited PNFA articles published since 2012 as of 02/11/2017, IF: 1.350] arXiv link
9. V.E. Babicheva, A.V. Lavrinenko, “Plasmonic modulator optimized by patterning of active layer and tuning permittivity,” Optics Communications 285, 5500–5507 (2012). [IF: 1.542] arXiv link
8. V.E. Babicheva, S.S. Vergeles, P.E. Vorobev, S. Burger, “Localized surface plasmon modes in a system of two interacting metallic cylinders,” JOSA B 29, 1263-1269 (2012). [IF: 2.210] arXiv link
7. V.E. Babicheva, Y.E. Lozovik, “Anomalous transmission of electromagnetic wave through periodic arrays of subwavelength slits arranged on thin metal films,” Optics and Spectroscopy 110, 119-123 (2011). [IF: 0.673]
6. V.E. Babicheva, Y.E. Lozovik, “Role of surface plasmon polaritons in anomalous transmission of an electromagnetic wave through two arrays with subwavelength slits,” Physics of the Solid State 53, 804-809 (2011). [IF: 0.782]
5. V.E. Babicheva, Y.E. Lozovik, “Light passage through a film with subwavelength slits,” Bulletin of the Lebedev Physics Institute 37, 309-310 (2010). [IF: 0.506]
4. V.E. Babicheva, Y.E. Lozovik, “Extraordinary transmission of electromagnetic waves in photonic nanostructures,” Journal Nanomaterials and Nanostructures – XXI Century 1, 11-18 (2010). [IF: N/A]
// Original in Russian: Бабичева В.Е., Лозовик Ю.Е. Аномальное прохождение электромагнитных волн в фотонных наноструктурах. Журнал “Наноматериалы и наноструктуры – XXI век” 1(2), 11-18 (2010).
3. V.E. Babicheva, Y.E. Lozovik, “Probable role of surface plasmon polaritons and extraordinary transmission of electromagnetic wave through metal film with slits,” Fizicheskoe Obrazovanie v VUZah (Physics in Higher Education) 16, P10 (2010). [IF: N/A]
2. V.E. Babicheva, Y.E. Lozovik, “Extraordinary transmission of electromagnetic wave through slit array in metal film,” Fizicheskoe Obrazovanie v VUZah (Physics in Higher Education) 15, P6 (2009). [IF: N/A]
1. V.E. Babicheva, Y.E. Lozovik, “Role of propagating slit mode in enhanced transmission through slit arrays in metallic films,” Optical and Quantum Electronics 41, 299-313 (2009). [IF: 0.657]