Optical properties of porous-system-based nanocomposites

L.A. Golovan, V.Yu. Timoshenko, P.K. Kashkarov
Lomonosov Moscow State University, Faculty of Physics, Leninskie Gory 1 build. 2, Moscow, 119991, Russian Federation

We consider the optical properties of semiconductor-insulator and insulator-insulator nanocomposites, including porous materials such as silicon, gallium phosphide, aluminum oxide, and structures based on them. The main focus is on the effect of form birefringence, which is caused by the anisotropy of pores in the materials under study. The applicability of the effective medium model for describing the optical properties of nanocomposites is discussed. The effects of light localization due to the scattering of light in such inhomogeneous media are analyzed.

PACS: 42.25.Hz, 42.25.Lc, 42.65.−k, 78.55.Mb (all)
DOI: 10.1070/PU2007v050n06ABEH006257
URL: https://ufn.ru/en/articles/2007/6/b/
Web of Science

000249986100002
Scopus

2-s2.0-35248821276
ADS NASA

2007PhyU...50..595G
Citation: Golovan L A, Timoshenko V Yu, Kashkarov P K "Optical properties of porous-system-based nanocomposites" Phys. Usp. 50 595–612 (2007)

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Оригинал: Головань Л А, Тимошенко В Ю, Кашкаров П К «Оптические свойства нанокомпозитов на основе пористых систем» УФН 177 619–638 (2007); DOI: 10.3367/UFNr.0177.200706b.0619

References (128) Cited by (138) Similar articles (20) ↓

D.I. Sementsov, A.M. Shutyi “Nonlinear regular and stochastic dynamics of magnetization in thin-film structures” 50 793–818 (2007)
A.M. Zheltikov “Holey fibers” 43 1125–1136 (2000)
G.N. Makarov “Cluster temperature. Methods for its measurement and stabilization” 51 319–353 (2008)
A.P. Vinogradov, A.V. Dorofeenko et al “Surface states in photonic crystals” 53 243–256 (2010)
A.A. Shklyaev, M. Ichikawa “Extremely dense arrays of germanium and silicon nanostructures” 51 133–161 (2008)
M.V. Rybin, M.F. Limonov “Resonance effects in photonic crystals and metamaterials (100th anniversary of the Ioffe Institute)” 62 823–838 (2019)
R.S. Berry, B.M. Smirnov “Phase transitions in various kinds of clusters” 52 137–164 (2009)
F.Kh. Mirzoev, V.Ya. Panchenko, L.A. Shelepin “Laser control processes in solids” 39 1–29 (1996)
V.G. Veselago “The electrodynamics of substances with simultaneously negative values of ε and μ” 10 509–514 (1968)
A.A. Ivanov, M.V. Alfimov, A.M. Zheltikov “Femtosecond pulses in nanophotonics” 47 687–704 (2004)
V.I. Balykin, P.N. Melentiev “Optics and spectroscopy of a single plasmonic nanostructure” 61 133–156 (2018)
V.V. Egorov, M.V. Alfimov “Theory of the J-band: from the Frenkel exciton to charge transfer” 50 985–1029 (2007)
A.V. Eletskii, A.A. Knizhnik et al “Electrical characteristics of carbon nanotube doped composites” 58 209–251 (2015)
A.V. Eletskii “Mechanical properties of carbon nanostructures and related materials” 50 225–261 (2007)
A.M. Brodskii, M.I. Urbakh “The effect of the microscopic structure of metal surfaces on their optical properties” 25 810–832 (1982)
D.F. Smirnov, A.S. Troshin “New phenomena in quantum optics: photon antibunching, sub-Poisson photon statistics, and squeezed states” 30 851–874 (1987)
E.M. Dianov, A.M. Prokhorov “Lasers and fiber optics” 29 166–178 (1986)
S.I. Yakovlenko “Absorption of powerful resonance radiation accompanying collisional line broadening” 25 216–230 (1982)
S.M. Arakelyan, G.A. Lyakhov, Yu.S. Chilingaryan “Nonlinear optics of liquid crystals” 23 245–268 (1980)
V.V. Klimov “Control of the emission of elementary quantum systems using metamaterials and nanometaparticles” 64 990–1020 (2021)

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