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Main Authors: Messelot, S., Leblanc, A., Tettekpoe, J. -S., Lefloch, F., Ficheux, Q., Renard, J., Dumur, É.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.10209
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author Messelot, S.
Leblanc, A.
Tettekpoe, J. -S.
Lefloch, F.
Ficheux, Q.
Renard, J.
Dumur, É.
author_facet Messelot, S.
Leblanc, A.
Tettekpoe, J. -S.
Lefloch, F.
Ficheux, Q.
Renard, J.
Dumur, É.
contents We investigate the coherence properties of parity-protected $\cos(2φ)$ qubits based on interferences between two Josephson elements in a superconducting loop. We show that qubit implementations of a $\cos(2φ)$ potential using a single loop, such as those employing semiconducting junctions, rhombus circuits, flowermon and KITE structures, can be described by the same Hamiltonian as two multi-harmonic Josephson junctions in a SQUID geometry. We find that, despite the parity protection arising from the suppression of single Cooper pair tunneling, there exists a fundamental trade-off between charge and flux noise dephasing channels. Using numerical simulations, we examine how relaxation and dephasing rates depend on external flux and circuit parameters, and we identify the best compromise for maximum coherence. With currently existing circuit parameters, the qubit lifetime $T_1$ can exceed milliseconds while the dephasing time $T_φ$ remains limited to only a few microseconds due to either flux or charge noise. Our findings establish practical limits on the coherence of this class of qubits and raise questions about the long-term potential of this approach.
format Preprint
id arxiv_https___arxiv_org_abs_2601_10209
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Coherence Limits in Interference-Based cos(2$φ$) Qubits
Messelot, S.
Leblanc, A.
Tettekpoe, J. -S.
Lefloch, F.
Ficheux, Q.
Renard, J.
Dumur, É.
Quantum Physics
Mesoscale and Nanoscale Physics
We investigate the coherence properties of parity-protected $\cos(2φ)$ qubits based on interferences between two Josephson elements in a superconducting loop. We show that qubit implementations of a $\cos(2φ)$ potential using a single loop, such as those employing semiconducting junctions, rhombus circuits, flowermon and KITE structures, can be described by the same Hamiltonian as two multi-harmonic Josephson junctions in a SQUID geometry. We find that, despite the parity protection arising from the suppression of single Cooper pair tunneling, there exists a fundamental trade-off between charge and flux noise dephasing channels. Using numerical simulations, we examine how relaxation and dephasing rates depend on external flux and circuit parameters, and we identify the best compromise for maximum coherence. With currently existing circuit parameters, the qubit lifetime $T_1$ can exceed milliseconds while the dephasing time $T_φ$ remains limited to only a few microseconds due to either flux or charge noise. Our findings establish practical limits on the coherence of this class of qubits and raise questions about the long-term potential of this approach.
title Coherence Limits in Interference-Based cos(2$φ$) Qubits
topic Quantum Physics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2601.10209