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Main Authors: Bouvier, Tomás Fernández, Jantunen, Ville, Vihuri, Saana, Cazalilla, Alvaro López, Djurabekova, Flyura
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2408.07363
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author Bouvier, Tomás Fernández
Jantunen, Ville
Vihuri, Saana
Cazalilla, Alvaro López
Djurabekova, Flyura
author_facet Bouvier, Tomás Fernández
Jantunen, Ville
Vihuri, Saana
Cazalilla, Alvaro López
Djurabekova, Flyura
contents Quantum information technologies hold immense promise, with quantum computers poised to revolutionize problem-solving capabilities. Among the leading contenders are solid-state spin-qubits, particularly those utilizing the spin of phosphorous donors (31 P ). While significant progress has been made in enhancing quantum coherence and qubit control, challenges persist, notably in achieving precise and scalable P placement in Si substrate. This paper investigates by means of molecular dynamics the use of molecular PF2 ions for implantation, aiming to reduce placement uncertainty while maintaining detection efficiency. We examine energy transfer, molecule integrity, implantation profiles, electronic signal components, and stable damage. Among other things we find that the assumption that the molecule only breaks apart immediately due to the presence of an a-SiO2 layer on the surface of the crystal and that the intensity of the electronic signal from ion-solid interactions does not correlate necessarily with the penetration depth of P.
format Preprint
id arxiv_https___arxiv_org_abs_2408_07363
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Insights on molecular P implantation for scalable spin-qubit arrays
Bouvier, Tomás Fernández
Jantunen, Ville
Vihuri, Saana
Cazalilla, Alvaro López
Djurabekova, Flyura
Computational Physics
Quantum Physics
Quantum information technologies hold immense promise, with quantum computers poised to revolutionize problem-solving capabilities. Among the leading contenders are solid-state spin-qubits, particularly those utilizing the spin of phosphorous donors (31 P ). While significant progress has been made in enhancing quantum coherence and qubit control, challenges persist, notably in achieving precise and scalable P placement in Si substrate. This paper investigates by means of molecular dynamics the use of molecular PF2 ions for implantation, aiming to reduce placement uncertainty while maintaining detection efficiency. We examine energy transfer, molecule integrity, implantation profiles, electronic signal components, and stable damage. Among other things we find that the assumption that the molecule only breaks apart immediately due to the presence of an a-SiO2 layer on the surface of the crystal and that the intensity of the electronic signal from ion-solid interactions does not correlate necessarily with the penetration depth of P.
title Insights on molecular P implantation for scalable spin-qubit arrays
topic Computational Physics
Quantum Physics
url https://arxiv.org/abs/2408.07363