about
Whispering-gallery-bottle microcavities: the three-dimensional etalon.Fabrication and study of bent and coiled free silica nanowires: Self-coupling microloop optical interferometer.Whispering gallery modes in a microfiber coil with an n-fold helical symmetry:classical dynamics, stochasticity, long period gratings, and wave parametric resonance.Optical microbubble resonator.Mode localization and the Q-factor of a cylindrical microresonator.Radius variation of optical fibers with angstrom accuracy.Fiber coupling to BaTiO3 glass microspheres in an aqueous environment.Surface nanoscale axial photonics: robust fabrication of high-quality-factor microresonators.Photo-induced SNAP: fabrication, trimming, and tuning of microresonator chains.Theory of SNAP devices: basic equations and comparison with the experiment.SNAP: fabrication of long coupled microresonator chains with sub-angstrom precision.Nanobump microresonator.Kerr nonlinear switching in a hybrid silica-silicon microspherical resonator.Tunable photonic elements at the surface of an optical fiber with piezoelectric core.Fabrication of surface nanoscale axial photonics structures with a femtosecond laser.Bottle microresonator broadband and low-repetition-rate frequency comb generator.Optical bottle versus acoustic bottle and antibottle resonators.Microscopic optical buffering in a harmonic potential.A SNAP coupled microresonator delay line.Multiple mode conversion and beam shaping with superimposed long period gratings.Surface nanoscale axial photonics at a capillary fiber.Surface nanoscale axial photonics at a capillary fiber: publisher's note.Optimization of optical ring resonator devices for sensing applications.Uniform coil optical resonator and waveguide: transmission spectrum, eigenmodes, and dispersion relation.Optimum intermediate fibers for reducing interconnection loss: exact solution.Radiation loss of a nanotaper: Singular Gaussian beam model.Optical fiber microcoil resonators.Slow light optofluidics: a proposal.Discovery of parabolic microresonators produced via fiber taperingKerr nonlinear switching in a core-shell microspherical resonator fabricated from the silicon fiber platformTunable SNAP microresonators via internal ohmic heatingLasing microbottlesOptical frequency combs generated mechanicallySurface nanoscale axial optomechanicsMiniature optical delay lines and buffersPermanent matching of coupled optical bottle resonators with better than 016 GHz precisionPrecise optical characterization of SNAP structures with a reference fiberNanobump microresonators at the fiber surfaceStrong localization of whispering gallery modes in an optical fiber via asymmetric perturbation of the translation symmetrySurface Nanoscale Axial Photonics Sensors
P50
Q31035560-A843192E-CF2C-4F8D-9193-6790C1908284Q33456787-EB89691A-633B-4AD7-B4D2-09266FB5877AQ33533137-2EE2B202-3277-402F-842B-E499F3601598Q33549152-BC95D0CF-4F02-4552-B719-AD2CA6F54471Q33633814-035B74E4-DC74-4498-9D21-E9CA6EC58572Q33760494-6C04C27C-ED65-48E0-B297-01D7F31C8B66Q33978190-209501B7-74F9-4900-AF24-8760ABF2EC97Q34104936-7712085A-19AB-4B61-AA20-4865EA0F2806Q34260883-CEA7DAF4-E6C8-403A-A486-A122906731DAQ34434271-1391FBD4-768B-4ED5-97F4-1ED2009CDD33Q34521303-901E0D1B-713D-4AE1-BA5D-05E4FD31F81BQ35592220-9D4141F8-0D38-47AC-8BA3-63560A1D79A1Q35697742-40A8A4A4-CE13-416E-B9D4-4528022A2B79Q36017305-587AB4C2-3539-4E3F-B3DA-8F4CBC808F11Q36052880-E93489D0-F326-47C9-8575-88251DC611EBQ36209275-CCFB94D7-913D-4A9E-9CB6-F9FBB0DC14FAQ36293643-609028E8-33B3-4694-9829-BE95E62B2274Q36392904-EC24AB2D-A04E-4EA3-A069-D1D549DAF059Q44290893-46CCBEC3-BD73-4050-86B9-39BCD66DB131Q47665718-732C27CF-14B8-4A7C-AB87-6D827BBE64E2Q47927490-C545A2EE-D697-4D7F-BA8C-9C31DEEE173AQ50028626-4E7676E2-81A5-41C4-9DBC-6BBCEEDF48C3Q50920428-A3B29BE7-936D-498B-9CF1-13BDDE9EC4FCQ51451956-E0A52C48-AC6F-4988-AFCC-14A0A653AA9DQ51922046-0C0DBF87-EC0A-4996-A264-BFA3B812C2CFQ51922173-E666B05E-58CB-4F87-985F-CF6AEBF262C2Q51997586-41510F52-86C0-4FB2-8838-4EFDC6ACBDACQ53400120-BBA686AA-0B17-44BC-8441-791A29B898F3Q57465125-8823CE08-66DD-4802-93F5-B3BEAB6A3325Q57701382-0CA5FA6D-E480-45D4-A999-34E483A21102Q61159098-ACA847D8-9EF7-4CFD-A238-4E6C3A68CFF4Q63382463-5204C04B-0CD2-4A05-96B4-89C0899FF0B8Q63382464-D441B013-A43F-4BE6-B168-52CD2968B435Q63382465-42D9E3F8-7038-44DE-9ABD-D45FBE90C671Q63382467-E7144EDB-5ECF-45AD-A4FD-9B7FE679690EQ63382468-5E46D661-1262-4C50-93E9-210464441271Q63382469-D57FE0D8-7D92-4042-80FC-BFE85512F844Q63382470-AEC37188-0BB9-4C5A-A3ED-9174065256A8Q63382473-7818A675-B572-4A2D-818B-84E26BF9E818Q63382474-4EDC1F5E-E175-4816-8EC5-B0B6AB1A3653
P50
description
onderzoeker
@nl
researcher ORCID ID = 0000-0001-7289-3547
@en
name
M Sumetsky
@ast
M Sumetsky
@nl
Misha Sumetsky
@en
Misha Sumetsky
@es
type
label
M Sumetsky
@ast
M Sumetsky
@nl
Misha Sumetsky
@en
Misha Sumetsky
@es
altLabel
M Sumetsky
@en
prefLabel
M Sumetsky
@ast
M Sumetsky
@nl
Misha Sumetsky
@en
Misha Sumetsky
@es
P214
P106
P1153
6701736064
P21
P214
P31
P496
0000-0001-7289-3547
P7859
lccn-n2010079409