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Main Authors: Goss, Noah, Suri, Nishchay, Marinelli, Brian, Chen, Larry, Hashim, Akel, Anand, Sajant, Morvan, Alexis, Naik, Ravi K., Rrapaj, Ermal, Santiago, David I., de Jong, Wibe, Yao, Norman Y., Moore, Joel E., Siddiqi, Irfan
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.14293
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author Goss, Noah
Suri, Nishchay
Marinelli, Brian
Chen, Larry
Hashim, Akel
Anand, Sajant
Morvan, Alexis
Naik, Ravi K.
Rrapaj, Ermal
Santiago, David I.
de Jong, Wibe
Yao, Norman Y.
Moore, Joel E.
Siddiqi, Irfan
author_facet Goss, Noah
Suri, Nishchay
Marinelli, Brian
Chen, Larry
Hashim, Akel
Anand, Sajant
Morvan, Alexis
Naik, Ravi K.
Rrapaj, Ermal
Santiago, David I.
de Jong, Wibe
Yao, Norman Y.
Moore, Joel E.
Siddiqi, Irfan
contents Periodically driven quantum many-body systems can spontaneously break discrete time-translation symmetry, realizing discrete time crystals. To date, both experimental and theoretical efforts have largely focused on the simplest case of spontaneous period-doubling in $\mathbb{Z}_2$ discrete time crystals realized with qubits. This owes, in part, to the challenge of stabilizing eigenstate order in higher discrete symmetry ($\mathbb{Z}_n$) time crystals, due to the presence of richer domain wall physics. Here, we demonstrate the realization of a $\mathbb{Z}_3$ discrete time crystal by implementing a Floquet chiral clock model in a chain of 15 superconducting qutrits. Unlike the conventional Ising setting, our system features a tunable chiral angle that governs domain-wall dynamics, spectral degeneracies, and crucially, the stability of time-crystalline order. Using disordered nearest-neighbor chiral interactions, we observe robust subharmonic period tripling that persists across a wide range of drive strengths and is independent of initial state. Finally, we highlight the special role that chirality plays in our $\mathbb{Z}_3$ discrete time crystal -- in its absence, the system's Floquet dynamics exhibit a marked initial state dependence governed by domain wall degeneracies. Our results establish native qudit hardware as a powerful platform to access a broader landscape of non-equilibrium phases.
format Preprint
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institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A Qutrit Time Crystal Stabilized with Native Chiral Interactions
Goss, Noah
Suri, Nishchay
Marinelli, Brian
Chen, Larry
Hashim, Akel
Anand, Sajant
Morvan, Alexis
Naik, Ravi K.
Rrapaj, Ermal
Santiago, David I.
de Jong, Wibe
Yao, Norman Y.
Moore, Joel E.
Siddiqi, Irfan
Quantum Physics
Periodically driven quantum many-body systems can spontaneously break discrete time-translation symmetry, realizing discrete time crystals. To date, both experimental and theoretical efforts have largely focused on the simplest case of spontaneous period-doubling in $\mathbb{Z}_2$ discrete time crystals realized with qubits. This owes, in part, to the challenge of stabilizing eigenstate order in higher discrete symmetry ($\mathbb{Z}_n$) time crystals, due to the presence of richer domain wall physics. Here, we demonstrate the realization of a $\mathbb{Z}_3$ discrete time crystal by implementing a Floquet chiral clock model in a chain of 15 superconducting qutrits. Unlike the conventional Ising setting, our system features a tunable chiral angle that governs domain-wall dynamics, spectral degeneracies, and crucially, the stability of time-crystalline order. Using disordered nearest-neighbor chiral interactions, we observe robust subharmonic period tripling that persists across a wide range of drive strengths and is independent of initial state. Finally, we highlight the special role that chirality plays in our $\mathbb{Z}_3$ discrete time crystal -- in its absence, the system's Floquet dynamics exhibit a marked initial state dependence governed by domain wall degeneracies. Our results establish native qudit hardware as a powerful platform to access a broader landscape of non-equilibrium phases.
title A Qutrit Time Crystal Stabilized with Native Chiral Interactions
topic Quantum Physics
url https://arxiv.org/abs/2605.14293