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Trapped Ion Quantum Computing
Valley splitting of single-electron Si MOS quantum dots
arXiv
Authors: John King Gamble, Patrick Harvey-Collard, N. Tobias Jacobson, Andrew D. Baczewski, Erik Nielsen, Leon Maurer, Inès Montaño, Martin Rudolph, M. S. Carroll, C. H. Yang, A. Rossi, A. S. Dzurak, Richard P. Muller
Year
2016
Paper ID
43011
Status
Preprint
Abstract Read
~2 min
Abstract Words
147
Citations
N/A
Abstract
Silicon-based metal-oxide-semiconductor quantum dots are prominent candidates for high-fidelity, manufacturable qubits. Due to silicon's band structure, additional low-energy states persist in these devices, presenting both challenges and opportunities. Although the physics governing these valley states has been the subject of intense study, quantitative agreement between experiment and theory remains elusive. Here, we present data from a new experiment probing the valley states of quantum dot devices and develop a theory that is in quantitative agreement with both the new experiment and a recently reported one. Through sampling millions of realistic cases of interface roughness, our method provides evidence that, despite radically different processing, the valley physics between the two samples is essentially the same. This work provides the first evidence that valley splitting can be deterministically predicted and controlled in metal oxide semiconductor quantum dots, a critical requirement for such systems to realize a reliable qubit platform.
Why This Paper Matters
- This paper contributes to the Trapped-Ion Quantum Computing research area in the Quantum Articles archive.
- It adds a 2016 reference point for readers tracking recent quantum research.
- Silicon-based metal-oxide-semiconductor quantum dots are prominent candidates for high-fidelity, manufacturable qubits.
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