about
Metamagnetics with rainbow colorsGold nanorod arrays as plasmonic cavity resonators.Negative index of refraction in optical metamaterials.Wavelength-tunable spasing in the visible.Liquid crystal clad near-infrared metamaterials with tunable negative-zero-positive refractive indices.Demonstration of Al:ZnO as a plasmonic component for near-infrared metamaterials.Unidirectional spaser in symmetry-broken plasmonic core-shell nanocavity.Hyperbolic metamaterials: new physics behind a classical problem.Plasmonics on the slope of enlightenment: the role of transition metal nitrides.Broadband Transformation Optics Devices.Holey-metal lenses: sieving single modes with proper phases.Homogenization of bi-anisotropic metasurfaces.Material parameter retrieval procedure for general bi-isotropic metamaterials and its application to optical chiral negative-index metamaterial design.Designs for optical cloaking with high-order transformations.The Ag dielectric function in plasmonic metamaterials.Engineering space for light via transformation optics.Engineered nonlinear materials using gold nanoantenna array.Patterned multilayer metamaterial for fast and efficient photon collection from dipolar emitters.Impedance-matched hyperlens.Experimental retrieval of the kinetic parameters of a dye in a solid film.Frequency-domain simulations of a negative-index material with embedded gain.Frequency-domain modeling of TM wave propagation in optical nanostructures with a third-order nonlinear response.Controlling the Polarization State of Light with Plasmonic Metal Oxide Metasurface.Finite-width plasmonic waveguides with hyperbolic multilayer cladding.Broadband high-efficiency half-wave plate: a supercell-based plasmonic metasurface approach.Light propagation through random hyperbolic media.Adiabatically tapered hyperbolic metamaterials for dispersion control of high-k waves.All-dielectric subwavelength metasurface focusing lens.Refractory plasmonics with titanium nitride: broadband metamaterial absorber.Optically active metasurface with non-chiral plasmonic nanoantennas.Electrical modulation of fano resonance in plasmonic nanostructures using graphene.Local heating with lithographically fabricated plasmonic titanium nitride nanoparticles.Ultrathin and multicolour optical cavities with embedded metasurfaces.Plasmonic metasurfaces for subtractive color filtering: optimized nonlinear regression modelsLoss-free and active optical negative-index metamaterialsComment on "Negative refractive index in artificial metamaterials"Drude relaxation rate in grained gold nanoantennasBroadband light bending with plasmonic nanoantennasMetal nanoslit lenses with polarization-selective designAnisotropic metamaterials emulated by tapered waveguides: application to optical cloaking
P50
Q28248767-3F6CB1E6-71C6-4334-AB52-12D3860CFE2CQ30544565-4A2DF1FE-C890-4ECD-925B-C1C9D690707BQ34481218-97FF86C2-58A1-4CA2-89FA-DBBF82E6E7FFQ34893597-27DB771B-D71B-4880-8022-5AC903252236Q34987292-71F669F8-13E5-43C1-AE92-2F632AA33AFEQ36061300-F460FAA3-3575-4189-9431-A107F42A3E03Q36593460-90200856-A38A-442D-AB7A-E81EDD61CA0CQ38115934-A77C1CFA-B7B1-4E6F-B10D-CF0DAA777BDFQ41230024-FF2EE15E-159B-412D-897D-A13B2B8A1720Q42243179-56AE32D4-7717-4464-A15C-90761B17139AQ44620380-A0C0FEF8-0590-45D0-838A-3ADD04EC29C8Q46196058-59C6BE84-2687-4368-A60D-5355E94E617AQ47416273-A3B29B04-8169-45E9-A2D7-F975DCBCA618Q47649663-5B5F60B6-2C63-46E4-B116-44B4100F58D8Q47652929-241B24E2-6A78-4D51-9831-DB0044D38C8CQ48009936-181EAB23-CF61-4AB8-9FD1-E32C981A9C25Q48240089-66E59079-D508-4792-B4A4-65E25A849120Q49680741-40535D98-EF2A-40E4-8320-32CF5A0A1D31Q50849482-90057F5A-1D72-4B37-A5CE-8EF93A1D5B36Q51530311-F5DD0953-5E3B-4923-8C31-C293B27A70C8Q51759675-5A43F31B-5610-46BC-B7FD-66548F3402D7Q51778916-0B2049DD-C8A7-4194-B676-587688EC8FABQ51781240-0FB7F2C4-C7E6-46D9-8472-263E59B4B6A7Q53237348-DDA26D4E-9329-435A-91F1-E771FCBE8376Q53287662-334E35E3-6261-4CC7-8B62-4AC483892B1CQ53337191-A0215146-E351-4C23-9B53-A64DD51C503AQ53375083-9B3DDE6D-D697-4D74-8136-11AFD58CFAC5Q53391332-F57364EA-6851-4DFC-881A-36FF1EDFC189Q53409650-7AA15372-EE8D-4E7C-BF72-6A4406EDFC3EQ53494932-12C9925D-5CC6-44B5-8A4E-C1AE8764911EQ54492339-7C1593FC-D551-4CB8-A461-5969F70BCC6DQ54532018-0D983990-9DE9-4CBA-AFCA-13FEAB6285F5Q55634292-9439B110-6772-4F39-AC30-339562647290Q57060933-01478741-04A6-4890-92C5-39B4D0311FF1Q59067995-417B019A-8D2B-440F-B139-BBEA20816A1CQ80423030-F4F557AE-D710-4D47-8C49-6467DB2CE6EBQ82766340-663452AB-5FAC-4420-81A6-EE8354FF6B59Q83120092-DEB22045-79C7-4960-8391-01AD53DEA3BFQ83423240-AE053FCA-5BD9-49AC-81A4-684D7CEBC0BBQ84054943-B23698BA-BFCD-4C93-8E7B-6270189E3657
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Alexander V. Kildishev
@ast
Alexander V. Kildishev
@en
Alexander V. Kildishev
@es
Alexander V. Kildishev
@nl
type
label
Alexander V. Kildishev
@ast
Alexander V. Kildishev
@en
Alexander V. Kildishev
@es
Alexander V. Kildishev
@nl
prefLabel
Alexander V. Kildishev
@ast
Alexander V. Kildishev
@en
Alexander V. Kildishev
@es
Alexander V. Kildishev
@nl
P1053
Q-8210-2017
P106
P1153
7004742932
P21
P31
P496
0000-0002-8382-8422