Imaging of current paths and defects in Al and TiSi interconnects on very-large-scale integrated-circuit chips using near-field optical-probe stimulation and resulting resistance change

K. Nikawa; T. Saiki; S. Inoue; M. Ohtsu

doi:10.1063/1.123451

Imaging of current paths and defects in Al and TiSi interconnects on very-large-scale integrated-circuit chips using near-field optical-probe stimulation and resulting resistance change

K. Nikawa, T. Saiki, S. Inoue, M. Ohtsu

Research output: Contribution to journal › Article › peer-review

20 Citations (Scopus)

Abstract

The optical-beam-induced resistance-change-detection (OBIRCH) method has been improved by using a near-field optical probe as the heat source instead of a laser beam. The near-field OBIRCH method has two advantages over the conventional one: (1) its spatial resolution is higher (50 vs 400 nm) and (2) the optical-probe-induced resistance change caused by heating can be observed using a metallized probe without interference from a photocurrent created by electron-hole-pair generation. In the conventional-OBIRCH method, the laser beam creates not only a resistance change, but also a photocurrent that can mask the resistance change signals.

Original language	English
Pages (from-to)	1048-1050
Number of pages	3
Journal	Applied Physics Letters
Volume	74
Issue number	7
DOIs	https://doi.org/10.1063/1.123451
Publication status	Published - 1999 Feb 15
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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abstract = "The optical-beam-induced resistance-change-detection (OBIRCH) method has been improved by using a near-field optical probe as the heat source instead of a laser beam. The near-field OBIRCH method has two advantages over the conventional one: (1) its spatial resolution is higher (50 vs 400 nm) and (2) the optical-probe-induced resistance change caused by heating can be observed using a metallized probe without interference from a photocurrent created by electron-hole-pair generation. In the conventional-OBIRCH method, the laser beam creates not only a resistance change, but also a photocurrent that can mask the resistance change signals.",

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AU - Saiki, T.

AU - Inoue, S.

AU - Ohtsu, M.

PY - 1999/2/15

Y1 - 1999/2/15

N2 - The optical-beam-induced resistance-change-detection (OBIRCH) method has been improved by using a near-field optical probe as the heat source instead of a laser beam. The near-field OBIRCH method has two advantages over the conventional one: (1) its spatial resolution is higher (50 vs 400 nm) and (2) the optical-probe-induced resistance change caused by heating can be observed using a metallized probe without interference from a photocurrent created by electron-hole-pair generation. In the conventional-OBIRCH method, the laser beam creates not only a resistance change, but also a photocurrent that can mask the resistance change signals.

AB - The optical-beam-induced resistance-change-detection (OBIRCH) method has been improved by using a near-field optical probe as the heat source instead of a laser beam. The near-field OBIRCH method has two advantages over the conventional one: (1) its spatial resolution is higher (50 vs 400 nm) and (2) the optical-probe-induced resistance change caused by heating can be observed using a metallized probe without interference from a photocurrent created by electron-hole-pair generation. In the conventional-OBIRCH method, the laser beam creates not only a resistance change, but also a photocurrent that can mask the resistance change signals.

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Imaging of current paths and defects in Al and TiSi interconnects on very-large-scale integrated-circuit chips using near-field optical-probe stimulation and resulting resistance change

Abstract

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