about
Optical label-free nanoplasmonic biosensing using a vertical-cavity surface-emitting laser and charge-coupled device.Ultrasensitive and label-free molecular-level detection enabled by light phase control in magnetoplasmonic nanoantennas.Multiscale conformal pattern transferMutually synchronized bottom-up multi-nanocontact spin-torque oscillators.Designer magnetoplasmonics with nickel nanoferromagnets.Nanoplasmon-enabled macroscopic thermal management.Highly directional bottom-up 3D nanoantenna for visible lightPolarizability and magnetoplasmonic properties of magnetic general nanoellipsoids.Enhanced nanoplasmonic optical sensors with reduced substrate effect.Solar Transparent Radiators by Optical Nanoantennas.Direct near-field optical imaging of higher order plasmonic resonances.Magnetic Control of the Chiroptical Plasmonic Surfaces.Magnetoplasmonic design rules for active magneto-optics.Gold-silica-gold nanosandwiches: tunable bimodal plasmonic resonators.Highly conformal fabrication of nanopatterns on non-planar surfaces.Ultrahigh sensitivity made simple: nanoplasmonic label-free biosensing with an extremely low limit-of-detection for bacterial and cancer diagnostics.Polarization conversion-based molecular sensing using anisotropic plasmonic metasurfaces.Plasmonic Nickel NanoantennasActive Magnetoplasmonic RulerTuning the Magneto-Optical Response of Nanosize Ferromagnetic Ni Disks Using the Phase of Localized PlasmonsModular assembly of two-dimensional metal-organic coordination networks at a metal surfaceReal-time single-molecule imaging of the formation and dynamics of coordination compoundsTwo-dimensional adatom gas bestowing dynamic heterogeneity on surfacesMetal-enhanced 1270 nm singlet oxygen phosphorescenceOxygen dissociation by concerted action of di-iron centers in metal-organic coordination networks at surfaces: modeling non-heme iron enzymesReal-space imaging of nanoplasmonic resonancesRefractometric sensing using propagating versus localized surface plasmons: a direct comparisonDisordered nanostructures by hole-mask colloidal lithography for advanced light trapping in silicon solar cellsColloidal lithography nanostructured Pd/PdO x core-shell sensor for ppb level H2S detection
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Q33525122-E12C9890-77F5-4728-AF29-B601A36DDFAEQ35121764-F3ED91AF-89B4-430D-8B57-630360E1C1BAQ37027379-6B77A2AD-3A07-452D-827E-A9F56C7C18EDQ39200139-706747D5-0B08-42E3-87E7-58626C0D72F7Q39805020-A27FDD19-68BF-4FD5-82FB-58CB9A473015Q40033565-C95B1F19-710B-49DA-AAE5-CE01F79149C8Q42014955-3B7E3ECC-6580-4950-813A-049AD3F0C204Q44984320-17DF7BC4-2811-4AB2-B80C-AFE3ECDFCF02Q45908325-CD5613ED-F81F-4FBA-917C-0A91AF69698AQ46075015-EF7339EA-E1DB-4B58-B95B-5B93D3F2DFBFQ47350024-AF95AE22-3614-44F6-BF0F-554FB64F3070Q48117446-8E722576-F6F8-4DD5-8DF9-99612DF041ABQ51007916-38F98083-C5D7-4E84-AE21-A98DCDBD4480Q51089341-28BF7C1D-FAA4-479D-BC0E-411F5E7EC15CQ51326710-1D92CCDF-8CE5-42A6-B3CE-AC5B8AEB2BD8Q51563257-689ECC11-579F-4172-9B5D-44B8539A447AQ53999591-B18396B4-EEF7-4826-8282-6B55AE8CAF19Q57656417-FE7AD52E-DE07-45B3-A27F-58A2AEBD2AF2Q67230611-00206752-4A52-496C-BFAA-67BE154EA63DQ67230845-187DDF26-71E5-4766-BCA1-61801D520D97Q73545110-15AA661F-9899-4A5F-A3E5-FC48B6538FA2Q78658087-9BFC09F7-1A18-465C-8997-61DD7F1BBD33Q81335191-B2547DAA-600E-4CF6-9EE3-E13F7FD79DC1Q81608935-A95DC607-C9D0-45ED-B56C-6948260DE5EDQ82094494-2F09F007-1287-4256-8B7C-572BD5B7C91EQ84292780-84DC8D21-F08A-4DA3-86F6-166CFCF8175FQ84752219-B45B874E-AF7E-4798-BEE4-66AD77BA7668Q87202757-142A77DB-8CAE-4C60-952B-C0E7DCFE733BQ88211197-7B5A20D3-46EF-45B7-9549-77AA742A23FB
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description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Alexandre Dmitriev
@ast
Alexandre Dmitriev
@en
Alexandre Dmitriev
@es
Alexandre Dmitriev
@nl
type
label
Alexandre Dmitriev
@ast
Alexandre Dmitriev
@en
Alexandre Dmitriev
@es
Alexandre Dmitriev
@nl
prefLabel
Alexandre Dmitriev
@ast
Alexandre Dmitriev
@en
Alexandre Dmitriev
@es
Alexandre Dmitriev
@nl
P214
P244
P106
P214
P244
no2012119501
P31
P496
0000-0002-2231-9333
P7859
lccn-no2012119501