Coulomb blockade oscillations at room temperature in a Si quantum wire metal-oxide-semiconductor field-effect transistor fabricated by anisotropic etching on a silicon-on-insulator substrate

Ishikuro, Hiroki; Fujii, Tomoyuki; Saraya, Takuya; Hashiguchi, Gen; Hiramoto, Toshiro; Ikoma, Toshiaki

doi:10.1063/1.116645

Cited by 186 publications

(87 citation statements)

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“…These use either lithographically defined islands 3,4 or multipletunnel junctions created by material/structural disorder effects. 5,6 By contrast, polycrystalline silicon has been somewhat neglected for SET applications despite a greater flexibility of fabrication. Single-electron effects have been observed in devices using polysilicon, 7,8 but these rely on interlayer tunnelling rather than intrinsic polysilicon properties.…”

Section: ͓S0003-6951͑98͒02534-0͔mentioning

confidence: 99%

Single-electron effects in heavily doped polycrystalline silicon nanowires

Irvine

Durrani

Ahmed

et al. 1998

Applied Physics Letters

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Section: ͓S0003-6951͑98͒02534-0͔mentioning

confidence: 99%

Single-electron effects in heavily doped polycrystalline silicon nanowires

Irvine

Durrani

Ahmed

et al. 1998

Applied Physics Letters

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“…At low temperatures and low source-drain bias Si nanostructures do not follow regular MOSFET transconductance characteristics but show rather complex behavior, suggesting transport through multiply-connected dots. Even in devices with no intentionally defined dots (like Si quantum wires [1][2][3][4] or point contacts [5]) Coulomb blockade oscillations were reported. In the case of quantum wires, formation of tunneling barriers is usually attributed to fluctuations of the thickness of the wire or of the gate oxide.…”

mentioning

confidence: 99%

Double-dot charge transport in Si single-electron/hole transistors

Rokhinson

Guo

Chou

et al. 2000

Applied Physics Letters

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We studied transport through ultra-small Si quantum dot transistors fabricated from silicon-oninsulator wafers. At high temperatures, 4 K < T < 100 K, the devices show single-electron or single-hole transport through the lithographically defined dot. At T < 4 K, current through the devices is characterized by multidot transport. From the analysis of the transport in samples with double-dot characteristics, we conclude that extra dots are formed inside the thermally grown gate oxide which surrounds the lithographically defined dot.

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“…However, the CB oscillation can usually be observed only at temperatures below 77K as the tunnel barriers are not high enough to confine electrons at high temperatures. A surface roughness induced MTJ has also been reported for a very narrow MOS channel [14]. The CB oscillation was observed at room temperature for this structure.…”

Section: R Tmentioning

confidence: 70%

Single-Electron Charging Phenomena in Nano/Polycrystalline Silicon Point Contact Transistors

Mizuta

Furuta²,

Kamiya³

et al. 2003

SSP

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Abstract. This paper gives a review of our recent work investigating the physics of single-electron charging phenomena in nano/polycrystalline silicon nanostructures. We first provide a short overview on the research of silicon-based single-electron devices from the last decade. Various single-electron transistor structures are compared in terms of control of electron islands and tunnel barriers. We then study the single-electron charging phenomena in nano/polycrystalline silicon nanostructures. A novel point-contact transistor is introduced, which features an extremely short and narrow nano/poly-Si nanowire as the transistor's channel. This structure is suitable for studying how a grain smaller than 10 nm in size and a discrete grain boundary work as a charging island and a tunnel barrier, respectively. The relationships between structural and electrical parameters of grains/grain-boundaries and the resulting Coulomb blockade characteristics for the point contact transistors are investigated by applying various passivation processes. Finally, optimisation of grain and grain-boundary structures is discussed for improving the Coulomb blockade characteristics and realizing nano/poly-Si single-electron transistors operating at room temperature.

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Coulomb blockade oscillations at room temperature in a Si quantum wire metal-oxide-semiconductor field-effect transistor fabricated by anisotropic etching on a silicon-on-insulator substrate

Cited by 186 publications

References 1 publication

Single-electron effects in heavily doped polycrystalline silicon nanowires

Single-electron effects in heavily doped polycrystalline silicon nanowires

Double-dot charge transport in Si single-electron/hole transistors

Single-Electron Charging Phenomena in Nano/Polycrystalline Silicon Point Contact Transistors

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