Photoconductive imaging in a photon scanning tunnelling microscope capable of point‐contact current sensing using a conductive fibre probe

Iwata, Futoshi; Someya, D.; Sakaguchi, Hiroshi; Igasaki, Yasuhiro; Kitao, Michihiko; Kubo, Takashi; Sasaki, Akira

doi:10.1046/j.1365-2818.2001.00883.x

Cited by 3 publications

(1 citation statement)

References 18 publications

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“…This is small compared to the lateral dimension of the current collection region (80 nm), and therefore, the wetting layer signal also contributes to the current at nominally on-dot positions. Note that the collection region on semiconductor samples is different to organic materials, where the limiting length scale for the resolution is given by the tip size or by the lateral diffusion length of charge carriers [19].…”

Section: Resultsmentioning

confidence: 99%

High resolution photocurrent imaging by atomic force microscopy on the example of single buried InAs quantum dots

Madl¹,

Brezna²,

Klang³

et al. 2010

Semicond. Sci. Technol.

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Conductive atomic force microscopy in combination with an optical setup is a useful tool for obtaining spectrally and spatially resolved photocurrent information on photoactive nanostructures. We have demonstrated photocurrent mapping under ambient conditions using sub-surface InAs quantum dots (QDs) as an example, whereby the QDs appear as dark areas in the photocurrent signal. Spectrally resolved measurements of on-dot and off-dot areas show distinct differences, confirming the existence of QDs at the detected position.

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Section: Resultsmentioning

confidence: 99%

High resolution photocurrent imaging by atomic force microscopy on the example of single buried InAs quantum dots

Madl¹,

Brezna²,

Klang³

et al. 2010

Semicond. Sci. Technol.

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Current‐sensing scanning near‐field optical microscopy using a metal probe for nanometre‐scale observation of electrochromic films

Iwata

Mikage

Sakaguchi

et al. 2003

Journal of Microscopy

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SummaryA novel technique for scanning near-field optical microscopy capable of point-contact current-sensing was developed in order to investigate the nanometre-scale optical and electrical properties of electrochromic materials. An apertureless bentmetal probe was fabricated in order to detect optical and current signals at a local point on the electrochromic films. The near-field optical properties could be observed using the local field enhancement effect generated at the edge of the metal probe under p -polarized laser illumination. With regard to electrical properties, current signal could be detected with the metal probe connected to a high-sensitive current amplifier. Using the current-sensing scanning near-field optical microscopy, the surface topography, optical and current images of coloured WO 3 thin films were observed simultaneously. Furthermore, nanometre-scale electrochromic modification of local bleaching could be performed using the current-sensing scanning near-field optical microscopy. The current-sensing scanning near-field optical microscopy has potential use in various fields of nanometre-scale optoelectronics.

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IWATA¹

2007

Electrochemistry

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Photoconductive imaging in a photon scanning tunnelling microscope capable of point‐contact current sensing using a conductive fibre probe

Cited by 3 publications

References 18 publications

High resolution photocurrent imaging by atomic force microscopy on the example of single buried InAs quantum dots

High resolution photocurrent imaging by atomic force microscopy on the example of single buried InAs quantum dots

Current‐sensing scanning near‐field optical microscopy using a metal probe for nanometre‐scale observation of electrochromic films

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