Transport Spectroscopy of Donor/Quantum Dot Interactive System in Silicon Nano-Transistors

IF 4.4 Q1 OPTICS
Soumya Chakraborty, Pooja Yadav, Daniel Moraru, Arup Samanta
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引用次数: 0

Abstract

Donor-atom-based nano-devices in silicon represent a breakthrough for individual control of electrons at atomic scale. Here, a finite-bias characterization of electrical transport through such a device, fabricated on a silicon-on-insulator (SOI) wafer with low phosphorus (P) doping, is presented. In this device, multiple quasi-periodic current peaks are observed at low temperatures in the electrical transfer characteristics. Such behavior of the transport characteristics is generally observed in devices having high doping concentration or with selective doping in the channel region to form a multi-donor cluster quantum dot. However, in the present device donor–cluster formation is highly improbable owing to low doping concentration. The observed electrical transport characteristics of the device are explained with a model of two non-interacting donors coupled in series with an unintentionally larger quantum dot, likely formed within the channel due to roughness. Theoretical simulation is also presented here for such a circuit supporting the experimental observations.

Abstract Image

硅纳米晶体管中供体/量子点交互系统的传输光谱学
基于供体原子的硅纳米器件是在原子尺度上对电子进行单独控制的一个突破。本文介绍了在低磷(P)掺杂的绝缘体硅(SOI)晶片上制造的这种器件的电传输有限偏差特性。在该器件中,低温下的电传输特性可观察到多个准周期电流峰值。在高掺杂浓度或在沟道区选择性掺杂以形成多供体簇量子点的器件中,一般都能观察到这种传输特性。然而,在本器件中,由于掺杂浓度较低,极不可能形成供体簇。观察到的器件电气传输特性可以用两个非相互作用的供体与一个无意中较大的量子点串联耦合的模型来解释,该量子点可能是由于粗糙度而在沟道内形成的。本文还介绍了这种电路的理论模拟,以支持实验观察结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
7.90
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