Scanning Photo-Induced Impedance Microscopy - Resolution studies and polymer characterization
Scanning Photo-Induced Impedance Microscopy - Resolution studies and polymer characterization
Scanning Photo-Induced Impedance Microscopy (SPIM) is an impedance imaging technique that is based on photocurrent measurements at field-effect structures. The material under investigation is deposited onto a semiconductor-insulator substrate. A thin metal film or an electrolyte solution with an immersed electrode serves as the gate contact. A modulated light beam focused into the space charge region of the semiconductor produces a photocurrent, which is directly related to the local impedance of the material. The absolute impedance of a polymer film can be measured by calibrating photocurrents using a known impedance in series with the sample. Depending on the wavelength of light used, charge carriers are not only generated in the focus but also throughout the bulk of the semiconductor. This can have adverse effects on the lateral resolution. Two-photon experiments were carried out to confine charge carrier generation to the spacecharge layer. The lateral resolution of SPIM is also limited by the lateral diffusion of charge carriers in the semiconductor. This problem can be solved by using thin silicon layers as semiconductor substrates. A resolution of better than 1 mu m was achieved using silicon on sapphire (SOS) substrates with a I l.Lm thick silicon layer.
ADDRESSABLE POTENTIOMETRIC SENSOR, SPATIAL-RESOLUTION, LATERAL RESOLUTION, SPECTROSCOPY, LAPS
1423-1430
Krause, S
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Moritz, W
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Talabani, H
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Xu, M
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Sabot, A
265126fc-398d-48c3-b7a2-2ed967769bdd
Ensell, G
5ed85009-4be4-4850-b95c-fbb367b67d15
January 2006
Krause, S
f3dacc4b-ffb9-4341-b3e5-7527e6991f43
Moritz, W
561deb09-f7f6-4a63-9b3b-2b95307ddd0c
Talabani, H
68c9b091-5dfc-41ca-b05c-1ee11910ec15
Xu, M
7806250a-951d-425f-81c5-4a1a58142a16
Sabot, A
265126fc-398d-48c3-b7a2-2ed967769bdd
Ensell, G
5ed85009-4be4-4850-b95c-fbb367b67d15
Krause, S, Moritz, W, Talabani, H, Xu, M, Sabot, A and Ensell, G
(2006)
Scanning Photo-Induced Impedance Microscopy - Resolution studies and polymer characterization.
Electrochimica Acta, 51 (8-9), .
Abstract
Scanning Photo-Induced Impedance Microscopy (SPIM) is an impedance imaging technique that is based on photocurrent measurements at field-effect structures. The material under investigation is deposited onto a semiconductor-insulator substrate. A thin metal film or an electrolyte solution with an immersed electrode serves as the gate contact. A modulated light beam focused into the space charge region of the semiconductor produces a photocurrent, which is directly related to the local impedance of the material. The absolute impedance of a polymer film can be measured by calibrating photocurrents using a known impedance in series with the sample. Depending on the wavelength of light used, charge carriers are not only generated in the focus but also throughout the bulk of the semiconductor. This can have adverse effects on the lateral resolution. Two-photon experiments were carried out to confine charge carrier generation to the spacecharge layer. The lateral resolution of SPIM is also limited by the lateral diffusion of charge carriers in the semiconductor. This problem can be solved by using thin silicon layers as semiconductor substrates. A resolution of better than 1 mu m was achieved using silicon on sapphire (SOS) substrates with a I l.Lm thick silicon layer.
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Krause_2006.pdf
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Published date: January 2006
Keywords:
ADDRESSABLE POTENTIOMETRIC SENSOR, SPATIAL-RESOLUTION, LATERAL RESOLUTION, SPECTROSCOPY, LAPS
Organisations:
Nanoelectronics and Nanotechnology
Identifiers
Local EPrints ID: 263602
URI: http://eprints.soton.ac.uk/id/eprint/263602
ISSN: 0013-4686
PURE UUID: ffe912c7-174d-46c8-a9db-8a479929c89f
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Date deposited: 23 Feb 2007
Last modified: 14 Mar 2024 07:35
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Contributors
Author:
S Krause
Author:
W Moritz
Author:
H Talabani
Author:
M Xu
Author:
A Sabot
Author:
G Ensell
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