about
Simultaneous real-time visible and infrared video with single-pixel detectors.Integrated 3D-printed reactionware for chemical synthesis and analysisParticle tracking stereomicroscopy in optical tweezers: control of trap shape.Mathieu beams as versatile light moulds for 3D micro particle assemblies.3D computational imaging with single-pixel detectors.Directed assembly of inorganic polyoxometalate-based micrometer-scale tubular architectures by using optical control.A multi-modal stereo microscope based on a spatial light modulator.A fast 3D reconstruction system with a low-cost camera accessory.A one-piece 3D printed flexure translation stage for open-source microscopy.Tracking Optical Welding through Groove Modes in Plasmonic Nanocavities.Tracking Optical and Electronic Behaviour of Quantum Contacts in Sub-Nanometre Plasmonic CavitiesSERS of Individual Nanoparticles on a Mirror: Size Does Matter, but so Does ShapeOptical trapping and binding.Fast full-color computational imaging with single-pixel detectors.Holographic tracking and sizing of optically trapped microprobes in diamond anvil cells.Facile Fabrication of Spherical Nanoparticle-Tipped AFM Probes for Plasmonic Applications.Monitoring morphological changes in 2D monolayer semiconductors using atom-thick plasmonic nanocavities.Watching individual molecules flex within lipid membranes using SERS.Independent polarisation control of multiple optical traps.Plasmonic nanohole electrodes for active color tunable liquid crystal transmissive pixels.Real time characterization of hydrodynamics in optically trapped networks of micro-particles.Increasing trap stiffness with position clamping in holographic optical tweezers.Optical trapping at gigapascal pressuresSpeeding up liquid crystal SLMs using overdrive with phase change reductionHolographic aberration correction: optimising the stiffness of an optical trap deep in the samplePosition clamping in a holographic counterpropagating optical trapTouching the microworld with force-feedback optical tweezersOptically trapped and driven paddle-wheelNear video-rate linear Stokes imaging with single-pixel detectorsOptically Induced Forces Imposed in an Optical Funnel on a Stream of Particles in Air or VacuumSingle-pixel infrared and visible microscopeForce sensing with a shaped dielectric micro-toolEfficient generation of Bessel beam arrays by means of an SLMOptimisation of a low cost SLM for diffraction efficiency and ghost order suppressionOptimizing the optical trapping stiffness of holographically trapped microrods using high-speed video trackingStereoscopic particle tracking for 3D touch, vision and closed-loop control in optical tweezersTweezers with a twistAn SLM-based Shack–Hartmann wavefront sensor for aberration correction in optical tweezersCalibration of optically trapped nanotoolsA spatial light phase modulator with an effective resolution of 4 mega-pixels
P50
Q27308944-BB93ABBC-7303-43AA-A175-5838397F0848Q28314888-62D08E58-1D75-4BA1-B977-A46296C787D0Q33621357-2C54326B-B6FB-452E-96E9-41BAFF479D77Q33774006-B134E811-208D-46C3-B5A7-016E426695DAQ34345528-39B645D6-280C-449B-8911-425D7265598AQ34480720-31B29C1A-926D-414D-A66A-F1FF4F501496Q34930641-070EECBB-CB3F-463E-B27C-68650742D7C2Q35701803-384059BE-B04B-4D69-83C7-6261DCE46BEEQ35941962-1EA78801-AF91-4A3E-93C3-AF01351F2B87Q36104995-24D2EEB9-1FA2-4480-A600-F6F944E16EB7Q36127219-8BFA8AFA-A2F1-4CA4-A1FE-04D25EB6F3AEQ37027603-4BD87A56-4A48-448E-8BC1-8A642466F50FQ38072800-DDA77F0B-80D7-4ABD-AF4C-3EAF040F62F7Q40142185-51FB1A04-C34E-432E-BC5A-EFDB97C55EC7Q40421349-A75062B8-B284-4C4E-9CE3-5AF27D41663BQ41764168-E860AACF-29C5-4D97-9BC4-715B8FBD4235Q42555930-FD9274BD-6E58-4E54-84C5-C68A2A0F1387Q42783872-8429427E-4F78-4354-A09A-2E572EBFEDF6Q43116900-ABAF80B7-279C-47C3-AB3B-EE3085B7BC36Q47924608-AE54AE9C-E46E-4241-AD84-9F0821A22BD0Q51712591-961C6275-67E9-4499-8C89-10F73CD0D35BQ53315914-45A49024-42AD-4308-B250-E3E71CAF8C47Q56890833-A52CDB7A-EBB2-41A2-ADE1-9BF15539CC54Q56890876-8BAB5AB7-BAC5-46FB-ADCA-8C75E5DED402Q56891591-E04CEB32-DC6D-47DC-964F-B076CC5C3F34Q56891951-628777F3-B25C-4929-8F06-84C9FFFF7770Q56893075-96FBCA79-6ECB-4186-A80B-20301ACAC91FQ57697979-BCC14BF4-CA28-4C3E-94F7-FC8AC385A1FEQ57891458-39D7BC84-B6BA-4BB0-977B-0A465618ADB9Q57891462-3D650F3E-7611-4A03-A223-353E1DB098E5Q57891581-16AF7CB0-1263-4E8E-860F-CE1BC1730DEBQ57891743-5CB09CFE-8E68-4976-86B0-26B6862B4D6EQ57891809-2A15387C-E47A-4B8E-ABF4-DF96DE4135A7Q57891872-109C4F4D-2E86-4D34-B57A-8F59417B3BEDQ57891880-0DDE6441-7D9D-4AD3-A159-16B5E93A46AAQ57891898-34E04E64-8F99-48F6-A989-B559B36AA773Q57891902-EE8463C6-BA8A-42E1-A499-961241AB3BD4Q57891925-34429CA6-6EE2-4951-889C-A0A9FD9535F5Q57891937-93BFDA08-B274-444E-88C5-B0A85E9964D0Q57892047-A645277F-E003-4B43-9784-26788B3A6E17
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Richard W. Bowman
@ast
Richard W. Bowman
@en
Richard W. Bowman
@es
Richard W. Bowman
@sl
type
label
Richard W. Bowman
@ast
Richard W. Bowman
@en
Richard W. Bowman
@es
Richard W. Bowman
@sl
prefLabel
Richard W. Bowman
@ast
Richard W. Bowman
@en
Richard W. Bowman
@es
Richard W. Bowman
@sl
P106
P1153
35253416600
P21
P31
P496
0000-0002-1531-8199