about
Single crystalline cylindrical nanowires - toward dense 3D arrays of magnetic vortices.The quantum effects of electromagnetic fluxesDevelopment of Aberration-Corrected Electron MicroscopyLongitudinal domain wall formation in elongated assemblies of ferromagnetic nanoparticles.Exploiting the speckle-correlation scattering matrix for a compact reference-free holographic image sensor.Aberration correction past and present.Progress in aberration-corrected high-resolution transmission electron microscopy using hardware aberration correction.High speed digital holography for density and fluctuation measurements (invited).Digital in-line holography for biological applicationsIndividual filamentous phage imaged by electron holography.Terahertz in-line digital holography of human hepatocellular carcinoma tissue.Three-part differential of unlabeled leukocytes with a compact lens-free imaging flow cytometer.Blood flow imaging in zebrafish by laser doppler digital holography.Spectral Interferometry with Electron MicroscopesDigital holographic interferometry employing Fresnel transform reconstruction for the study of flow shear stabilized Z-pinch plasmas.Shadow images for in-line holography in a STEM instrument.Three-dimensional surface topography of graphene by divergent beam electron diffraction.Imaging proteins at the single-molecule level.Observation of microdiffraction patterns with a dedicated STEM instrument.A general model for resolution of digital holographic microscopy.A novel method for identifying the order of interference using phase-shifting digital holography.Time-lapse lens-free imaging of cell migration in diverse physical microenvironments.Inverted Gabor holography principle for tailoring arbitrary shaped three-dimensional beams.Beating Darwin-Bragg losses in lab-based ultrafast x-ray experimentsComputer generated holograms for carbon nanotube arrays.Magnetic-flux quanta in superconducting thin films observed by electron holography and digital phase analysis.The possibilities of neural holographic processes within the brain.Bioholography--a new model of information processing.Charged hydrophobic colloids at an oil-aqueous phase interface.Phase imaging and nanoscale currents in phase objects imaged with fast electrons.Photography (article)Scanning Beam MethodsElectron-holographic interference microscopyDOCUMENTATION NOTESHolographic Polymer-Dispersed Liquid Crystals: Materials, Formation, and ApplicationsResolution Improvement in Stage-Scanning Electron Holography: Comparison with Conventional Electron HolographyReconstruction of Phase Objects by Holography
P2860
Q27324429-4B661F69-480B-4FED-9395-060C3C9EF1CAQ27346281-8F939631-5EDB-4351-A16B-C10F00B9DBD1Q29037973-8C6399DB-3913-4969-8BA9-D6C112B0BB4FQ30666081-C1F48348-113C-4E8F-A8CF-77A01CCB4626Q30827489-D77E36AB-C9DA-4748-B0CD-5B1B62EC1048Q31084344-39060235-4361-4039-AB49-35D609A76DECQ33283766-87F20F97-C049-4C06-BB48-F3EC94777359Q33733425-F8E96B55-FC31-4A5F-8CFE-A2E2B4DC171CQ33944472-17391E55-9C4C-482B-ADAF-92FE038DDEEFQ34004720-6FAB63AA-B3A0-4B6F-8572-92A18BF75C5FQ35080669-48B4DF30-A864-4AFD-BFC2-C1A21AE7F296Q35533545-34523FCA-5961-407B-AC42-9D93CA388623Q36011430-4EFEECD4-9079-4571-929D-C42536C86AEEQ36138710-97007D59-B96A-459B-AD8D-4619A1BC0C59Q36179584-D00D53ED-8504-4CF3-B03C-71A27BF50BA6Q36699661-17C96B3A-A7BF-496E-BB64-0F2EA40A5850Q37652018-99C5649B-1139-4E5B-9BA5-AB7850C8A9C9Q37658973-16CC4234-5E08-4328-9FA9-485B4813023BQ38619952-B719AAF7-5E11-4C3E-BDAD-28D03AE1EF36Q40303235-66229EC1-4603-4719-BB38-D0FCE71F1BB2Q40332215-0B42FBB9-8BAC-41AA-83C1-8A089696900BQ40391292-5653772F-B63F-4B8E-B881-C7302A1D5D05Q42114100-D80C4293-D24B-48C7-B42D-EC4AA38CD123Q42372638-7EEB3573-7942-46F9-8903-A23DE120B53EQ46080861-02DE0C72-E0B6-4833-A60B-09D753EC6338Q48597024-D1AF0AB4-3D9A-4F7B-A88F-B45B942D53A0Q48896080-85F26E92-0538-4C1C-9718-F95701B526A4Q49158723-AF117D28-957A-4241-9F32-927634D8936CQ51562938-D84E511C-2EB1-461C-A1F0-71250DA88A1BQ52411671-C869B792-F832-45A2-A1E2-CA66F805EDA6Q56422534-9D3BBD66-78AE-49AE-8A16-0F91D83672EDQ58020458-B02FAB50-2696-418C-A967-B1099AEDF9C7Q58296684-E0A5518D-0660-4652-B2DB-66A19681C846Q58630009-09997DF4-6453-441F-8E4C-568C0D3B1B89Q58644156-810CA01F-F50E-4A53-BD35-DCA0EF89158BQ58995025-5D147306-E2A9-458F-9A95-C47767284A5DQ59005421-D8EB8264-CDB0-49F1-B8C4-97D956679BBD
P2860
description
im Juli 1949 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в липні 1949
@uk
name
Microscopy by Reconstructed Wave-Fronts
@en
Microscopy by Reconstructed Wave-Fronts
@nl
type
label
Microscopy by Reconstructed Wave-Fronts
@en
Microscopy by Reconstructed Wave-Fronts
@nl
prefLabel
Microscopy by Reconstructed Wave-Fronts
@en
Microscopy by Reconstructed Wave-Fronts
@nl
P356
P1476
Microscopy by Reconstructed Wave-Fronts
@en
P2093
P304
P356
10.1098/RSPA.1949.0075
P577
1949-07-07T00:00:00Z