Marta Prada scite author profile

The Stark shift of the hyperfine coupling constant is investigated for a P donor in Si far below the ionization regime in the presence of interfaces using tight-binding and band minima basis approaches and compared to the recent precision measurements. In contrast with previous effective mass-based results, the quadratic Stark coefficient obtained from both theories agrees closely with the experiments. It is also shown that there is a significant linear Stark effect for an impurity near the interface, whereas, far from the interface, the quadratic Stark effect dominates. This work represents the most sensitive and precise comparison between theory and experiment for single donor spin control. Such precise control of single donor spin states is required particularly in quantum computing applications of single donor electronics, which forms the driving motivation of this work.

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Atomistic Simulation of Realistically Sized Nanodevices Using NEMO 3-D—Part II: Applications

Klimeck

Ahmed

Kharche

et al. 2007

IEEE Trans. Electron Devices

117

114

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Valley splitting in strained silicon quantum wells modeled with 2° miscuts, step disorder, and alloy disorder

et al. 2007

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Valley splitting ͑VS͒ in strained SiGe/ Si/ SiGe quantum wells grown on ͑001͒ and 2°miscut substrates is computed in a magnetic field. Calculations of flat structures significantly overestimate, while calculations of perfectly ordered structures underestimate experimentally observed VS. Step disorder and confinement alloy disorder raise the VS to the experimentally observed levels. Atomistic alloy disorder is identified as the critical physics, which cannot be modeled with analytical effective mass theory. NEMO-3D is used to simulate up to 10 6 atoms, where strain is computed in the valence-force field and electronic structure in the sp 3 d 5 s * model.

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Resonance Microwave Measurements of an Intrinsic Spin-Orbit Coupling Gap in Graphene: A Possible Indication of a Topological State

et al. 2019

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Marta Prada

Atomistic Simulation of Realistically Sized Nanodevices Using NEMO 3-D—Part I: Models and Benchmarks

High Precision Quantum Control of Single Donor Spins in Silicon

Atomistic Simulation of Realistically Sized Nanodevices Using NEMO 3-D—Part II: Applications

Valley splitting in strained silicon quantum wells modeled with 2° miscuts, step disorder, and alloy disorder

Resonance Microwave Measurements of an Intrinsic Spin-Orbit Coupling Gap in Graphene: A Possible Indication of a Topological State

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