量子环中量子比特内的电子概率密度分布

任保友; 高宽云; 赵翠兰

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量子环中量子比特内的电子概率密度分布

论文 | 更新时间：2020-08-12

- 量子环中量子比特内的电子概率密度分布
- Probability Density Distribution of Electron in Quantum Bit of Quantum Ring
- 发光学报 2008年29卷第2期页码：248-252
- 作者机构：
  
  内蒙古民族大学, 物理与电子信息学院,内蒙古通辽,028043
- 作者简介：
- 基金信息：
  
  国家自然科学基金(10347004)();内蒙古高校科研基金(NJ05074)资助项目()
- DOI：
  中图分类号： O472.4;O469
- 收稿日期：2007-08-25，
  
  修回日期：2007-11-24，
  
  纸质出版日期：2008-03-20
- 稿件说明：
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任保友, 高宽云, 赵翠兰. 量子环中量子比特内的电子概率密度分布[J]. 发光学报, 2008,29(2): 248-252

REN Bao-you, GAO Kuan-yun, ZHAO Cui-lan. Probability Density Distribution of Electron in Quantum Bit of Quantum Ring[J]. Chinese Journal of Luminescence, 2008,29(2): 248-252
任保友, 高宽云, 赵翠兰. 量子环中量子比特内的电子概率密度分布[J]. 发光学报, 2008,29(2): 248-252 DOI：

REN Bao-you, GAO Kuan-yun, ZHAO Cui-lan. Probability Density Distribution of Electron in Quantum Bit of Quantum Ring[J]. Chinese Journal of Luminescence, 2008,29(2): 248-252 DOI：

摘要

通过较精确地求解能量本征方程获得量子环中量子比特内的电子概率密度分布。对InAs量子环的数值计算表明:电子概率密度分布与电子的坐标(半径、高度

角度)及时间有关。当其中三个变量给定时

电子概率密度随另一个变量的变化规律分别为:随半径的增大做非周期性振荡;随高度的变化而变化

在半高处出现的概率最大;随角度作周期变化

在角度等于π处出现的概率最大;随时间作周期性振荡。

Abstract

Quantum computing combines computer science with quantum mechanics and is a fast growing research field. In recent years

the outlines of all kinds of achieving quantum computation were devised. In 1999

the suggestion of superconductive electronic charge was designed by Nakamura in Japan

a nanometer-scale superconducting electrode connected to a reservoir via a Josephson junction constitutes an artificial two-level electronic system:a single-Cooper-pair box. In 2001

the plan of geometrical quantum computation was framed by Duan L M

et al

the elementary unit of quantum computer is the quantum bit(quanbit). In 2002

based on an idea that spatial separation of charge states will enhance quantum coherence

Li X Q

et al

. propose a scheme for a quantum computation with the quantum bit constructed from two coupled quantum dots. In 2003

based on the analytical solution to the time-dependent Schdinger equation

Cen L X

et al

. evaluate the holonomic quantum computation beyond the adiabatic limit. Low dimensional nanostructures has attracted much attention due to their unique electronic and optical properties as well as potential applications in making electronic and optoelectronic devices. Quantum rings (QRs) stand as an alternative to quantum dots(QDs) as zero-dimensional structures. QRs were extensively applied in optoelectronics

microelectronics and quantum communication because its characteristic electronic shell structure

magnetic field response and transport properties. The potential power of quantum ring is based on the ability of quantum systems to be in a superposition of its basic states. Probability density distribution of electron in quantum bit of quantum ring was studied by solving precisely the time-independent Schr-dinger equation. The numerical calculation for InAs quantum rings was carried

the material parameters are μ=0.024m0

m0 is mass of free electron

the inner/outer radius of quantum rings is 20/40 nm. The numerical results indicate that probability density distribution of electron has something to do with coordinate and time. When time t

angle φ and height z are given

it does non-periodicity oscillates with increasing radius ρ. When time

angle and radius are given

it increasing firstly and falling secondly with increasing height and achieves maximum if

/2. When time

height and radius are given

it raises firstly and declines with increasing angle and achieves maximum if φ=π. And probability density distribution of electron in quantum bit of quantum ring does periodicity oscillating with time.

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Keywords

references

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