For applications, a field of particular importance is nonlinear frequency conversion , dealing with the generation of new optical frequencies in nonlinear processes. Another wide area is concerned with the effects of optical nonlinearities in various situations, e. Nonlinear fiber optics does partly deal with nonlinear frequency conversion e. Nonlinear interactions are also very important for many experiments in quantum optics.
Suggest additional literature! See also: nonlinearities , nonlinear polarization , nonlinear crystal materials , nonlinear frequency conversion , supercontinuum generation , quantum optics , fiber optics and other articles in the category nonlinear optics. If you like this article, share it with your friends and colleagues, e. Virtual Library.
Sponsoring this encyclopedia:. Sorry, we don't have an article for that keyword! Bibliography  R. Lightwave Technol. Express 21 25 ,  R. Sutherland, Handbook of Nonlinear Optics , 2nd edn. ACS Photonics 5 , — Li, Y. On-chip zero-index metamaterials. Photonics 9 , — Noginov, M. Transparent conductive oxides: plasmonic materials for telecom wavelengths. Stegeman, G.
Guo, P. From Wikipedia, the free encyclopedia. This is several orders of magnitude larger than that of most dielectric materials [ 17 ], [ 34 ], [ 73 ], [ ]. Nanophotonics 4 , 44—68 Optical time reversal from time-dependent epsilon-near-zero media. Bibcode : NatPh
Third order nonlinear integrated optics. Photonic chip based ultrafast optical processing based on high nonlinearity dispersion engineered chalcogenide waveguides. Laser Photonics Rev.
Reshef, O. Beyond the perturbative description of the nonlinear optical response of low-index materials. Maier, S. Plasmonics: Fundamentals and Applications. Springer, Derkachova, A. Dielectric function for gold in plasmonics applications: size dependence of plasmon resonance frequencies and damping rates for nanospheres. Plasmonics 11 , — Guo, P.
Large optical nonlinearity of ITO nanorods for sub-picosecond all-optical modulation of the full-visible spectrum. Degenerate optical nonlinear enhancement in epsilon-near-zero transparent conducting oxides. Express 8 , — Iyer, P. Ultrawide thermal free-carrier tuning of dielectric antennas coupled to epsilon-near-zero substrates. Tuning of plasmons in transparent conductive oxides by carrier accumulation.
Elim, H. Carrier concentration dependence of optical Kerr nonlinearity in indium tin oxide films. B 82 , — Quantification and impact of nonparabolicity of the conduction band of indium tin oxide on its plasmonic properties. Ultrafast switching of tunable infrared plasmons in indium tin oxide nanorod arrays with large absolute amplitude.
Photonics 10 , — Viscoelastic optical nonlocality of low-loss epsilon-near-zero nanofilms. Dinu, M. Third-order nonlinearities in silicon at telecom wavelengths. Kaipurath, R. Optically induced metal-to-dielectric transition in epsilon-near-zero metamaterials. Lee, Y. Strong nonlinear optical response in the visible spectral range with epsilon-near-zero organic thin films.
Vezzoli, S. Optical time reversal from time-dependent epsilon-near-zero media. Campione, S. B 87 , Kamandi, M. Giant field enhancement in longitudinal epsilon-near-zero films. B 95 , R Second-harmonic generation in longitudinal epsilon-near-zero materials. B 96 , Taliercio, T. Express 22 , — Vassant, S.
Berreman mode and epsilon near zero mode. Express 20 , — Directional perfect absorption using deep subwavelength low-permittivity films. B 90 , Newman, W. Ferrell—Berreman modes in plasmonic epsilon-near-zero media. ACS Photonics 2 , 2—7 Bello, F. Theory of epsilon-near-zero modes in ultrathin films. B 91 , Berini, P.
Long-range surface plasmon polaritons. Photonics 1 , — B 76 , Javani, M. Real and imaginary properties of epsilon-near-zero materials. Hamachi, Y. Slow light with low dispersion and nonlinear enhancement in a lattice-shifted photonic crystal waveguide. Monat, C. Four-wave mixing in slow light engineered silicon photonic crystal waveguides. Express 18 , — Material slow light and structural slow light: similarities and differences for nonlinear optics [Invited].
B 28 , A38—A44 Powell, D. Nonlinear control of tunneling through an epsilon-near-zero channel. B 79 , Marini, A. Self-organization of frozen light in near-zero-index media with cubic nonlinearity. Khurgin, J. Everything is slow light. Johnson, P. Optical constants of the noble metals.
B 6 , — B 9 , — Reutzel, M.
Excitation of two-photon photoemission where epsilon is near zero on Ag West, P. Searching for better plasmonic materials. Naik, G. Alternative plasmonic materials: beyond gold and silver. Oxides and nitrides as alternative plasmonic materials in the optical range. Express 1 , — Pradhan, A. Extreme tunability in aluminum doped zinc oxide plasmonic materials for near-infrared applications. Calzolari, A.
Nonlinear Optical Effects and Materials describes progress achieved in the field of nonlinear optics and nonlinear optical materials. Selected topics such as. The first € price and the £ and $ price are net prices, subject to local VAT. Prices indicated with * include VAT for books; the €(D) includes 7% for. Germany, the.
ACS Photonics 1 , — Riley, C. High-quality, ultraconformal aluminum-doped zinc oxide nanoplasmonic and hyperbolic metamaterials. Small 12 , — Guo, Q. A solution-processed ultrafast optical switch based on a nanostructured epsilon-near-zero medium. Wang, Y. Tunability of indium tin oxide materials for mid-infrared plasmonics applications. Express 7 , — Shkondin, E. Large-scale high aspect ratio Al-doped ZnO nanopillars arrays as anisotropic metamaterials.
Anopchenko, A. Field-effect tunable and broadband epsilon-near-zero perfect absorbers with deep subwavelength thickness.