000 09921nam a2200805 i 4500
001 9780750323369
003 IOP
005 20230516170302.0
006 m eo d
007 cr cn |||m|||a
008 230109s2022 enka fob 000 0 eng d
020 _a9780750323369
_qebook
020 _a9780750323352
_qmobi
020 _z9780750323345
_qprint
020 _z9780750323376
_qmyPrint
024 7 _a10.1088/978-0-7503-2336-9
_2doi
035 _a(CaBNVSL)thg00083522
035 _a(OCoLC)1358413931
040 _aCaBNVSL
_beng
_erda
_cCaBNVSL
_dCaBNVSL
050 4 _aQC446.2
_b.R378 2022eb
072 7 _aPHK
_2bicssc
072 7 _aSCI022000
_2bisacsh
082 0 4 _a621.36/94
_223
100 1 _aRapoport, Yuriy,
_eauthor.
_970714
245 1 0 _aWaves in nonlinear layered metamaterials, gyrotropic and plasma media /
_cYuriy Rapoport, Vladimir Grimalsky.
264 1 _aBristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) :
_bIOP Publishing,
_c[2022]
300 _a1 online resource (various pagings) :
_billustrations (some color).
336 _atext
_2rdacontent
337 _aelectronic
_2isbdmedia
338 _aonline resource
_2rdacarrier
490 1 _a[IOP release $release]
490 1 _aIOP ebooks. [2022 collection]
500 _a"Version: 20221201"--Title page verso.
504 _aIncludes bibliographical references.
505 0 _aPage dedicated to Professor Allan D Boardman -- 1. Introductory chapter -- 1.1. Metamaterials : the discovery of 2000th -- 1.2. Characteristic features of the media and wave phenomena in metamaterials and the main approaches to their modeling -- 1.3. Purpose, tasks, and structure of the book
505 8 _a2. Metamaterials with active metaparticles. Absolute and convective instability in the active metamaterials -- 2.1. Artificial molecules (AMs) and their individual polarizations -- 2.2. Possibility of the existence of active metamaterials with spatial amplification and negative phase behavior -- 2.3. Nonlinear homogenization out of the frames of the perturbation method and constitutional (material) nonlinear relationships -- 2.4. Conclusions
505 8 _a3. General method of the derivation of nonlinear evolution equations for layered structures (NEELS) with the volume and surface nonlinearities -- 3.1. A method for the derivation of the nonlinear evolution equations for the waves in layered structures with bi-anisotropic metamaterials -- 3.2. Method NEELS for the giant resonance generation of the second harmonic of surface plasmons and the contribution of the surface and volume nonlinearities -- 3.3. Method NEELS for nonlinear electromagnetic and MSWs in the layered dielectric-ferromagnetic media with spatial dispersion and auxiliary boundary conditions -- 3.4. Conclusions to chapter 3
505 8 _a4. Application of the nonlinear evolution equations for layered structures (NEELS) method to the layered nonlinear passive gyrotropic and plasma-like structures with volume and surface nonlinearities -- 4.1. Application of method NEELS for the giant resonance generation of the second harmonic of surface plasmons and contribution of the surface and volume nonlinearities -- 4.2. Vortex structures on the backward volume magnetostatic waves in ferrite films -- 4.3. Formation and propagation of the bullets in the gyrotropic waveguides accounting for higher-order nonlinearities -- 4.4. Application of the method NEELS for the propagation of the waves in the linear waveguide Earth-Ionosphere -- 4.5. Conclusions to chapter 4
505 8 _a5. Controllable propagation and reflection of electromagnetic waves in layered gyrotropic metamaterial media -- 5.1. The problems under consideration -- 5.2. The magnetooptic control of spatial and spatio-temporal solitons in metamaterial waveguides -- 5.3. Stationary equations and spatial solitons in the presence of the higher-order effect : nonlinear diffraction -- 5.4. Non-stationary equations and spatial-temporal solitons in the presence of higher-order effects : nonlinear diffraction and dispersion, Raman interaction, and linear third-order dispersion. Generalization of NEELS method -- 5.5. New types of surface magnetic polaritons and reflection of electromagnetic waves in metamaterial-dielectric systems -- 5.6. Conclusions
505 8 _a6. Parametric interactions of the nonlinear waves in active layered metamaterials and gyrotropic structures -- 6.1. Wave structures in layered active gyrotropic media with parametric interaction -- 6.2. Nonlinear waves in the layered bi-anisotropic metamaterials -- 6.3. Parametric interactions and phase conjugation on active two-dimensional chiral metamaterial surfaces with linear and nonlinear Huygens sources -- 6.4. Conclusions to chapter 6
505 8 _a7. Formation propagation, and control of bullets in metamaterial waveguides with higher-order nonlinear effects and magnetooptic interaction -- 7.1. Introduction -- 7.2. Instabilities of bullets in the metamaterial waveguides with the influence of the higher-order nonlinear effects -- 7.3. Stabilization of bullets in periodical and magnetooptic metamaterial waveguides -- 7.4. Conclusions for chapter 7
505 8 _a8. Giant double-resonant second harmonic generation in the multilayered dielectric-graphene metamaterials -- 8.1. Introduction -- 8.2. Basic equations -- 8.3. Double resonant reflection and nonlinear scattering into second harmonic : simulations -- 8.4. Discussion and conclusions
505 8 _a9. Nonlinear transformation optics and field concentration -- 9.1. Introduction to metamaterial transformations and geometrical optics mapping onto full-wave nonlinear solutions. Impact of nonlinear wave transformations on the design of realistic devices -- 9.2. Inhomogeneous dielectric permittivity and the wave equation -- 9.3. 'Ordinary' geometrical optics -- 9.4. New CGO techniques -- 9.5. Formulas of CGO for the particular system shown in figure 9.1 -- 9.6. Electromagnetic field inside an internal nonlinear region r [less than or equal to] Rc -- 9.7. Matching 'full-wave' and 'CGO' solutions and possible applications -- 9.8. Superfocusing combining linear and nonlinear media to create new forms of energy capture and field concentration -- 9.9. Conclusions
505 8 _a10. Wave processes in controlled and active metamaterials and plasma-like media in the presence of resonance and strong nonlinearity -- 10.1. Conditions for transition to the mode of strong nonlinearity during the generation of a giant localized surface plasmonic second harmonic -- 10.2. Nonlinear electromagnetic waves in metamaterial field concentrators -- 10.3. Nonlinear switching effect when electromagnetic waves pass through a multilayer resonant system 'dielectric-graphene' -- 10.4. Conclusions
505 8 _a11. Nonlinear stationary and non-stationary diffraction in active planar anisotropic hyperbolic metamaterial -- 11.1. Introduction -- 11.2. Basic equations. Two approaches : with and without an averaging -- 11.3. Details of the structure and requirements for materials -- 11.4. Results of simulations -- 11.5. The limiting case of the stationary NSE -- 11.6. The discussion and main results
505 8 _a12. Analytical models of formation of nonlinear dissipative wave structures in active quantum hyperbolic planar resonant metamaterials in IR range -- 12.1. General description of the problem -- 12.2. Theoretical approach to modeling of modern nonlinear active hyperbolic metamaterials. Ginzburg-Landau equation -- 12.3. Details of the structure of the active hyperbolic metamaterial -- 12.4. The model of a two-level active medium and equations for nonlinear EMW in planar active resonant hyperbolic medium -- 12.5. Example of numerical modeling -- 12.6. Conclusions
505 8 _a13. Rogue waves in metamaterial waveguides -- 13.1. Introduction -- 13.2. Simulations -- 13.3. Conclusions to chapter 13 and future trends
505 8 _a14. Waves in nonlinear layered metamaterials, gyrotropic and plasma media. The main results of the book and the proposed directions for future research -- 14.1. The main results obtained in the previous chapters.
520 3 _aThe purpose is to give a wide, tutorial-driven, presentation of the theory of wave processes occurring in layered nonlinear metamaterials (MMs), gyrotropic and plasma media.
521 _aElectromagnetics and nonlinear wave phenomena.
530 _aAlso available in print.
538 _aMode of access: World Wide Web.
538 _aSystem requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
545 _aYuriy Rapoport graduated from Taras Shevchenko National University of Kyiv, Ukraine and is now Leading research fellow at the same University, Faculty of Physics, and also with the University of Warmia and Mazury, Olsztyn, Poland. Volodymyr Grimalsky graduated from T. Shevchenko Kiev State University (KSU), former USSR (now Taras Shevchenko National University of Kyiv, Ukraine), in 1982 with the honorous diploma on theoretical physics. Now he is with the Autonomous University of State Morelos, Cuernavaca, Mexico.
588 0 _aTitle from PDF title page (viewed on January 9, 2023).
650 0 _aNonlinear optics
_xMaterials.
_96813
650 0 _aNonlinear waves.
_93824
650 0 _aMetamaterials.
_910489
650 0 _aGyrotrons.
_970715
650 0 _aPlasma (Ionized gases)
_911207
650 7 _aElectricity, electromagnetism & magnetism.
_2bicssc
_970716
650 7 _aSCIENCE / Physics / Electromagnetism.
_2bisacsh
_98223
700 1 _aGrimalsky, Vladimir,
_eauthor.
_970717
710 2 _aInstitute of Physics (Great Britain),
_epublisher.
_911622
776 0 8 _iPrint version:
_z9780750323345
_z9780750323376
830 0 _aIOP (Series).
_pRelease 22.
_970718
830 0 _aIOP ebooks.
_p2022 collection.
_970719
856 4 0 _uhttps://iopscience.iop.org/book/mono/978-0-7503-2336-9
942 _cEBK
999 _c82893
_d82893