NanoBridge technology for reconfigurable LSI

Toshitsugu Sakamoto; Shunichi Kaeriyama; Masayuki Mizuno; Kazuya Terabe; Tsuyoshi Hasegawa; Masakazu Aono

NanoBridge technology for reconfigurable LSI

Toshitsugu Sakamoto, Shunichi Kaeriyama, Masayuki Mizuno, Kazuya Terabe, Tsuyoshi Hasegawa, Masakazu Aono

Research output: Contribution to journal › Article

Abstract

We have investigated a NanoBridge technology for a high performance LSI that is reconfigurable. The NanoBridge comprises a solid electrolyte sandwiched betvveen two metals. The switch has two conducting states (ON/ OFF) that persist in the absence of a power supply. The distinctive advantages of this switch are its small size (<30nm) and low ON resistance (<100Ω). This paper proposes a three terminal NanoBridge, for which the control gate is separate from the current path. This innovative switch resolve the issues arising from large current during switching that occurs in a two-terminal NanoBridge.

Original language	English
Pages (from-to)	72-75
Number of pages	4
Journal	NEC Technical Journal
Volume	2
Issue number	1
Publication status	Published - 2007 Dec 1
Externally published	Yes

Keywords

FPGA
Reconfigurable
Solid electrolyte

ASJC Scopus subject areas

Information Systems
Materials Science(all)
Hardware and Architecture
Electrical and Electronic Engineering

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abstract = "We have investigated a NanoBridge technology for a high performance LSI that is reconfigurable. The NanoBridge comprises a solid electrolyte sandwiched betvveen two metals. The switch has two conducting states (ON/ OFF) that persist in the absence of a power supply. The distinctive advantages of this switch are its small size (<30nm) and low ON resistance (<100Ω). This paper proposes a three terminal NanoBridge, for which the control gate is separate from the current path. This innovative switch resolve the issues arising from large current during switching that occurs in a two-terminal NanoBridge.",

keywords = "FPGA, Reconfigurable, Solid electrolyte",

author = "Toshitsugu Sakamoto and Shunichi Kaeriyama and Masayuki Mizuno and Kazuya Terabe and Tsuyoshi Hasegawa and Masakazu Aono",

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T1 - NanoBridge technology for reconfigurable LSI

AU - Sakamoto, Toshitsugu

AU - Kaeriyama, Shunichi

AU - Mizuno, Masayuki

AU - Terabe, Kazuya

AU - Hasegawa, Tsuyoshi

AU - Aono, Masakazu

PY - 2007/12/1

Y1 - 2007/12/1

N2 - We have investigated a NanoBridge technology for a high performance LSI that is reconfigurable. The NanoBridge comprises a solid electrolyte sandwiched betvveen two metals. The switch has two conducting states (ON/ OFF) that persist in the absence of a power supply. The distinctive advantages of this switch are its small size (<30nm) and low ON resistance (<100Ω). This paper proposes a three terminal NanoBridge, for which the control gate is separate from the current path. This innovative switch resolve the issues arising from large current during switching that occurs in a two-terminal NanoBridge.

AB - We have investigated a NanoBridge technology for a high performance LSI that is reconfigurable. The NanoBridge comprises a solid electrolyte sandwiched betvveen two metals. The switch has two conducting states (ON/ OFF) that persist in the absence of a power supply. The distinctive advantages of this switch are its small size (<30nm) and low ON resistance (<100Ω). This paper proposes a three terminal NanoBridge, for which the control gate is separate from the current path. This innovative switch resolve the issues arising from large current during switching that occurs in a two-terminal NanoBridge.

KW - FPGA

KW - Reconfigurable

KW - Solid electrolyte

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