K. Nakajima et al., Development of a hybrid scanning near-field optical/tunneling microscope (SNOM/STM) system, JPN J A P 1, 38(6B), 1999, pp. 3949-3953
Scanning near-field optical microscope (SNOM) is hybridized with a Scanning
tunneling microscope (STM) to investigate nanoscopic optical phenomena in
both the near-field region and its proximity. The system is realized by int
roducing a doubly metal-coated optical fiber tip with an extremely small ap
erture (< 100 nm); where the metal is coated on the aperture to obtain a ha
lf-transparent conducting tip after the fabrication of an "aperture probe."
A simultaneous SNOM/STM observation is performed for an Au (111) surface,
where the evanescent field at the tip vicinity through the aperture is scat
tered by the local structures of the sample and the far-field component of
the scattered light is collected as an optical signal. The distance control
is carried out under the constant-current condition in order to separate t
he optical properties from surface topography. An optical resolution of lam
bda/100 and identical channel transport for both electrons and photons are
achieved. The intensity changes, as a function of the gap distance, are als
o measured in the far-field and the near-field regions and the proximity.