PhD thesis
“Ultra-compact plasmonic waveguide modulators,”
Technical University of Denmark, 2013
Book Chapter
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.
arXivs
xx. V.E. Babicheva, “Multipole resonances and directional scattering by hyperbolic-media antennas,”
arxiv.org/abs/1706.07259
xx. V.E. Babicheva, “Surface and edge resonances of phonon-polaritons in scattering-type near-field optical microscopy”
arxiv.org/abs/1709.06274
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, accepted (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: N/A]
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]
![](https://nanometa.unm.edu/wp-content/uploads/2020/06/fig_px510_py250_SHG_Multipole_part.jpg)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2020/05/download.jpg)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2020/05/WS2_epsilon.jpg)
55. H. Ahmed and V.E. Babicheva, “Nanostructured Tungsten Disulfide WS2 as Mie Scatterers and Nanoantennas,” MRS Advances 5, 1819-1826 (2020). [N/A]
Link to read-only version without subscription
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/06/TOC-1.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/09/Fig_Array_thmbnail.jpg)
53. V.E. Babicheva, “Transition Metal Dichalcogenide Nanoantennas Lattice,” MRS Advances
4, 2283 (2019). [IF: N/A]
Link to read-only version without subscription
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/06/N52.jpg)
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]
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/06/PRB-1-300x275.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/ApplSci-1.jpg)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/MRS_Advances.jpg)
49. V.E. Babicheva, “Multipole Resonances in Transdimensional Lattices of Plasmonic and Silicon Nanoparticles,” MRS Advances 4, 713-722 (2019). [IF: N/A]
Link to read-only version without subscription
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/Screenshot-2019-01-18-15.01.1411.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/45.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/46.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/45.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/44.png)
44. V.E. Babicheva, “Lattice Kerker effect in the array of hexagonal boron nitride antennas,” MRS Advances 3, 2783-2788 (2018). [IF: N/A] arXiv link
Link to read-only version without subscription
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/43.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/42.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/ToC_.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/ph-2017-01186p_0007.gif)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/hs.png)
39. V.E. Babicheva, “Directional scattering by the hyperbolic-medium antennas and silicon particles,” MRS Advances 3, 1913 (2018). [IF: N/A] arXiv link
Link to read-only version without subscription
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/GraphAbs_v3_vertical_edited.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/37.png)
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
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/06/Au_fields_crp-vo01bp.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/35.png)
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
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/06/ACS_AMI-2kuq896-1.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/pastedImage-3-15g9ax2.png)
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]
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/06/Untitled-1-12ddfjj-1.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/Fig_1-1u4i0pd-1024x768.png)
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]
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/07/N30.jpg)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/abstract-rz1tr4-e1463291612540.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/LRHIH_thumbnail_final-1d4qf4c.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/Gr_abstr-2lmr4ii.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/t1-1o4x6dk.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/ToC_picture_Crop-1fdlsi6.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/submitted-1alspeg-e1463292465729.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/07/N21.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/fig_TOC_400x400-wuurpp.png)
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
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/07/N19.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/07/N17-150x150.jpg)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![Viktoriia Babicheva](https://nanometa.unm.edu/wp-content/uploads/2019/07/N15-150x150.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/06/Thumbnail_cr-2k3l5pb-2.jpg)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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).
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]
![](https://nanometa.unm.edu/wp-content/uploads/2019/07/backgrnd_sqr.png)
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]