about
Local self-uniformity in photonic networks.Isotropic band gaps and freeform waveguides observed in hyperuniform disordered photonic solids.Designer disordered materials with large, complete photonic band gapsUnfolding the band structure of non-crystalline photonic band gap materials.Photonic band gap in isotropic hyperuniform disordered solids with low dielectric contrast.Unfolding the band structure of GaAsBi.Fast Assembly of Gold Nanoparticles in Large-Area 2D Nanogrids Using a One-Step, Near-Infrared Radiation-Assisted Evaporation Process.Freeform Phononic WaveguidesReciprocal space engineering with hyperuniform gold disordered surfacesHigh-Q photonic crystal cavities in all-semiconductor photonic crystal heterostructuresHyperuniform disordered phononic structuresHyperuniform plasmonic metasurfaces, controlling light with correlated disorderHigh-Qoptical cavities in hyperuniform disordered materialsFlexible Cavity and Waveguide Light Confinement in Hyperuniform Photonic SlabsHyperuniform photonic slabs for high-Q cavities and low-loss waveguidesLight Confinement in Hyperuniform Photonic Slabs: High-Q Cavities and Low-Loss WaveguidesSelectively reflective transparent sheetsHyperuniform disordered photonic band gap devices for silicon photonicsHyperuniform disordered photonic band gap silicon devices for optical interconnectsIsotropic band gaps, optical cavities, and freeform waveguides in hyperuniform disordered photonic solidsSilicon waveguides and filters in hyperuniform disordered photonic solids for the near-infraredNew designer dielectric metamaterial with isotropic photonic band gapOptical cavities and waveguides in hyperuniform disordered photonic solidsPublisher's Note: Optical cavities and waveguides in hyperuniform disordered photonic solids [Phys. Rev. B87, 165116 (2013)]Freeform wave-guiding at infrared regime in two dimensional disordered photonic bandgap materialsModelling the Auger Recombination rates of GaAs (1-x) Bi x alloysPhotonic Band Gaps and Unusual Photon Transport in Hyperuniform Disordered StructuresEffects of random link removal on the photonic band gaps of honeycomb networksExperimental observation of photonic bandgaps in hyperuniform disordered materialThermal emission from finite photonic crystalsComplete band gaps in two-dimensional photonic quasicrystalsNew classes of non-crystalline photonic band gap materialsProperties of thermal radiation in photonic crystalsThermal emission from finite photonic crystalsThermal radiation in photonic crystalsImproving solar cell efficiency using photonic band-gap materialsSingle photons on demand from tunable 3D photonic band-gap structuresSpin relaxation in lateral quantum dots: Effects of spin-orbit interactionNonlinear tuning of 3D photonic band-gap structures for single-photon on demand sourcesThree-Dimensional Photonic Band-Gap Structures For Single-Photon on Demand Sources
P50
Q30362384-0164B6D0-51DE-4FF9-947E-9A64FFD578E9Q30362384-360B82F5-9E2C-4716-95C5-210B08F9222CQ30440974-3C9771B3-19C2-4B99-99E1-AD7B19FFE2D1Q30440974-48252BC9-21E9-4E8E-B9E1-6CD3176135A2Q35013246-58EFA60A-65D8-48E0-81CB-A9130439E50CQ40626309-1738010C-D7A5-401F-BDD3-DBE2A5525DE0Q40626309-6FAB87B3-DAC2-4F27-A325-914860D65889Q43849350-6537E40C-49B4-44CF-9273-9F6B2C0FB868Q43849350-9DE0111A-FE23-4F72-A700-28815DC9D67BQ48032853-D4500A54-C6F5-4344-AA87-812401BB3E71Q51561736-26CE8ADA-B49E-47D7-831E-31E99E3C2797Q58468934-18BDC3FF-6DFA-49D2-A842-41FF8BFF48A2Q58468936-406D424E-F9CC-43DA-B040-7941DEC57CDAQ58468939-5D5B25BE-0C94-4A10-A350-89365DE1FC59Q58468941-DC76E9C7-9141-403B-9F54-CBDE33337806Q58468944-CE94B515-8AA5-4C2A-8132-3394A671072EQ58468948-16231727-415E-44F5-9CBA-856EDA72D1D8Q58468951-217CC5A6-2AB7-42E8-B305-1F5705929331Q58468959-D440846A-A577-4A62-BC50-E1BBA8A4BC4BQ58468961-F2F0A3B5-5B9C-4875-82B6-A75CE380CF91Q58468965-E9C0ED43-A76A-4FCA-901E-7715706DC3A0Q58468968-BFCB33AC-FF28-407A-8841-4C8147E18C95Q58468970-32511E72-F982-49FD-BEA2-DD8AF1919A42Q58468977-9C4A315A-3701-4334-9916-E40B6704B4BDQ58468979-0CF79211-2324-4390-8E2D-34E4B976447EQ58468981-DDA3FB6D-6550-4217-BD1B-941E6894B0C8Q58468984-7E72DDC5-3FF1-4CA2-98AA-4B7A4421E5A5Q58468986-1191E43A-2DDD-4F7D-8460-1ECDDF8E316BQ58468988-23E80D30-E6F5-4D8C-93CF-0F91621FA46DQ58468991-EE5FDF10-906E-48ED-85A5-5A0942019A1CQ58468995-592C2EBC-06C3-4AE7-B1B1-F59011B3D352Q58468998-6CAAC175-9E20-4082-9AC8-9BD8989B31ACQ58469000-A859F03D-3C95-4C0E-84C1-2B0994D88364Q58469002-6287016F-A1AE-4710-ABF2-14ACF83BC573Q58469005-FE7CFA42-03E1-407D-8DBC-36421E73CC48Q58469010-5AD911CE-E7E9-430D-ABCC-24C21CE79665Q58469012-9806C0DF-30E3-4AFE-AAFB-8D2BE1E87093Q58469015-FEE3BE36-D1A0-4370-86CC-A21CA41EC640Q58469017-87F4A9F4-E387-4AA0-960D-BDD745236EF7Q58469019-B4D5BDB7-E115-4547-A7F3-4AF13A026935
P50
description
onderzoeker
@nl
researcher ORCID ID = 0000-0001-6278-9164
@en
name
Marian Florescu
@ast
Marian Florescu
@en
Marian Florescu
@es
Marian Florescu
@nl
type
label
Marian Florescu
@ast
Marian Florescu
@en
Marian Florescu
@es
Marian Florescu
@nl
prefLabel
Marian Florescu
@ast
Marian Florescu
@en
Marian Florescu
@es
Marian Florescu
@nl
P108
P1053
E-9009-2010
P106
P1153
9844144600
P21
P31
P3829
P4012
P496
0000-0001-6278-9164