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Research PaperResearchia:202607.09079

Fidelity Analysis of Adiabatically Driven Donor Spins as Two-Qubit and Ququart Systems

Brian Michon

Abstract

Donor spin systems host a native Hilbert space whose dimension exceeds that of a qubit, meaning they can be used as qudits. Here we study a \ce{Si{:}P} donor spin system through leakage-aware randomized benchmarking (RB) of native ququart $\mathcal{C}_4$ and encoded two-qubit $\mathcal{C}_2^{\otimes 2}$ Clifford groups. We implement adiabatic ramps to operate electron dipole spin resonance (EDSR) pulses at the ionization point, where the electron is shared halfway between the donor and the inter...

Submitted: July 9, 2026Subjects: Quantum Physics; Quantum Computing

Description / Details

Donor spin systems host a native Hilbert space whose dimension exceeds that of a qubit, meaning they can be used as qudits. Here we study a \ce{Si{:}P} donor spin system through leakage-aware randomized benchmarking (RB) of native ququart C4\mathcal{C}_4 and encoded two-qubit C2βŠ—2\mathcal{C}_2^{\otimes 2} Clifford groups. We implement adiabatic ramps to operate electron dipole spin resonance (EDSR) pulses at the ionization point, where the electron is shared halfway between the donor and the interface, and to operate electron spin resonance (ESR) pulses near the interface, motivated by the sensitivity of the effective magnetic field to charge noise at the ionization point. By placing the electron near the ionization point only during EDSR control and using sufficiently long displacement ramp durations, leakage outside the computational basis is strongly suppressed, which is crucial for optimized qudit control. We find in our analysis based on leakage RB that C4\mathcal{C}_4 consistently achieves ∼40\sim 40--50%50\% lower (lower-bound) error rates Ξ΅PTLB\varepsilon^{\mathrm{LB}}_\mathrm{PT} with respect to C2βŠ—2\mathcal{C}_2^{\otimes 2}, due to its reduced circuit complexity. These results indicate that donor spin qudits benefit from genuine qudit operation as opposed to imposed encoded qubit operation.


Source: arXiv:2607.07586v1 - http://arxiv.org/abs/2607.07586v1 PDF: https://arxiv.org/pdf/2607.07586v1 Original Link: http://arxiv.org/abs/2607.07586v1

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Date:
Jul 9, 2026
Topic:
Quantum Computing
Area:
Quantum Physics
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