Coulomb Blockade and Few-Electron Energy Spectra of Quantum Rings

量子环的库仑封锁和少电子能谱

• 批准号: 0302222
• 负责人: Alexander Zaslavsky
• 金额: --
• 依托单位: Brown University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-05-01 至 2008-04-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0302222&HistoricalAwards=false
• 关键词: Coulomb; Blockade; Few; Electron; Energy

This Condensed Matter Physics project deals with nanoscale quantum conductors that have a circular, i. e., "ring" geometry. Ideal quantum rings have a number of fascinating properties: Ground-state persistent currents, strong Aharonov-Bohm interference effects, and an oscillatory dependence of the wavefunctions and all thermodynamic quantities on the enclosed magnetic flux, with period given by the flux quantum. This research will focus on the properties of individual and multiply-connected quantum rings in the few-electron and Coulomb blockade regime. The PI has recently discovered that inhomogeneous strain relaxation in sufficiently small Si/SiGe quantum dots leads to ring-like confinement. Additionally, tunneling measurements have confirmed the expected flux quantum periodicity. Given the control over device geometry, elliptical rings and coupled ring structures will be fabricated and few-carrier energy spectra, spin interactions, and Coulomb blockade effects will be measured as these rings are filled by carriers from zero carrier occupancy. The work will be coupled to state-of-the-art finite-element solid mechanics simulations. Experiment data will provide feedback on the interplay between electronic and mechanical properties in nanostructures. Graduate students involved in this research will acquire a full complement of skills, from deep-submicron fabrication, to low-temperature, low-signal measurements, to numerical simulation, which will prepare them for employment in academia, the semiconductor industry, or government. A teaching plan focusing on improved undergraduate teaching of core courses in the Electrical Engineering program is an integral part of this project. Ideal quantum rings, in which carriers follow circular orbits without scattering, have fascinating properties: Currents that flow without resistance, phase-interference effects, and the oscillatory dependence of carrier energies and wavefunctions on the enclosed magnetic flux. Quantum rings have also been suggested as possible building blocks for quantum computation. This research will focus on the properties of individual and multiply-connected quantum rings in the few-electron and Coulomb blockade regime, where the one carrier circling the ring affects the probability of another tunneling into the ring. The rings in question arise from the strain relaxation at the sidewalls of etched structures, making it possible to control the geometry (circular or elliptical) and the topology (single-ring or multiply-connected ring) of the system. Tunneling current measurements will study the carrier and spin interactions as these rings are filled by carriers from zero; the results will be compared to state-of-the-art finite-element strain simulations and our data will provide experimental feedback on the interplay between electronic and mechanical properties of nanostructures. Graduate students involved in this research will acquire a full complement of skills, preparing them for research jobs in academia, the semiconductor industry, or government. A teaching plan focusing on improved undergraduate teaching of core courses in the Electrical Engineering program is an integral part of the project.

这个凝聚态物理项目涉及具有圆形的纳米级量子导体，即。即“环”几何形状。 理想的量子环具有许多令人着迷的特性：基态持续电流、强阿哈罗诺夫-玻姆干涉效应，以及波函数和所有热力学量对封闭磁通量的振荡依赖性，周期由通量量子给出。 这项研究将重点关注少电子和库仑封锁体系中单个和多重连接量子环的性质。 PI 最近发现，足够小的 Si/SiGe 量子点中的不均匀应变弛豫会导致环状约束。 此外，隧道测量已经证实了预期的通量量子周期性。 考虑到对器件几何形状的控制，将制造椭圆环和耦合环结构，并且当这些环被来自零载流子占有率的载流子填充时，将测量少载流子能谱、自旋相互作用和库仑阻塞效应。 这项工作将与最先进的有限元固体力学模拟相结合。 实验数据将为纳米结构中电子和机械性能之间的相互作用提供反馈。 参与这项研究的研究生将获得从深亚微米制造到低温、低信号测量到数值模拟的全套技能，这将为他们在学术界、半导体行业或政府就业做好准备。 专注于改进电气工程专业核心课程本科教学的教学计划是该项目的组成部分。 理想的量子环，其中载流子遵循圆形轨道而不发生散射，具有令人着迷的特性：无阻力流动的电流、相位干涉效应以及载流子能量和波函数对封闭磁通量的振荡依赖性。 量子环也被建议作为量子计算的可能构建模块。 这项研究将重点关注少电子和库仑封锁状态下单个和多重连接量子环的特性，其中环绕环的一个载流子影响另一个隧道进入环的概率。 所讨论的环是由蚀刻结构侧壁处的应变松弛产生的，从而可以控制系统的几何形状（圆形或椭圆形）和拓扑（单环或多连接环）。 隧道电流测量将研究载流子和自旋相互作用，因为这些环从零开始被载流子填充；结果将与最先进的有限元应变模拟进行比较，我们的数据将为纳米结构的电子和机械性能之间的相互作用提供实验反馈。参与这项研究的研究生将获得全套技能，为他们在学术界、半导体行业或政府的研究工作做好准备。 专注于改进电气工程课程核心课程本科教学的教学计划是该项目的组成部分。