Superresolution of near-field optical microscopy defined from properties of confined electromagnetic waves
- 1 June 1992
- journal article
- Published by Optica Publishing Group in Applied Optics
- Vol. 31 (16), 3036-3045
- https://doi.org/10.1364/ao.31.003036
Abstract
The experimental resolution that is obtained with a near-field microscope by optical tunneling detection is far beyond the Rayleigh criterion. We discuss the principal physical characteristics of this superresolution. Three different examples are presented. They show that the resolution increases as the collector width and collector-to-object distance decrease. It is interesting to note that, in the near-field microscope, as in all local probe microscopes, the resolution cannot be defined from the characteristics of the microscope only. In all tunnel devices the detector cannot be separated from the object. The superresolution that can be obtained results from this fact. This paper also points out the importance of evanescent waves in near-field optics and makes the connection between resolving power and evanescent fields.This publication has 23 references indexed in Scilit:
- Photon tunneling microscopyApplied Optics, 1990
- General principles of scanning tunneling optical microscopyOptics Letters, 1989
- Scanning tunneling optical microscopyOptics Communications, 1989
- New form of scanning optical microscopyPhysical Review B, 1989
- Near-field diffraction by a slit: implications for superresolution microscopyApplied Optics, 1986
- Optical characteristics of 0.1 μm circular apertures in a metal film as light sources for scanning ultramicroscopyJournal of Vacuum Science & Technology B, 1985
- Optical stethoscopy: Image recording with resolution λ/20Applied Physics Letters, 1984
- Microscopy and pattern generation with scanned evanescent wavesApplied Optics, 1984
- Super-resolution Aperture Scanning MicroscopeNature, 1972
- Resolving Power of Visible LightJournal of the Optical Society of America, 1956