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Autori principali: Vetter, Philipp J., Findler, Christoph, Verdú, Antonio, Kost, Matthias, Blinder, Rémi, Fuhrmann, Jens, Osterkamp, Christian, Lang, Johannes, Plenio, Martin B., Prior, Javier, Jelezko, Fedor
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2510.27374
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author Vetter, Philipp J.
Findler, Christoph
Verdú, Antonio
Kost, Matthias
Blinder, Rémi
Fuhrmann, Jens
Osterkamp, Christian
Lang, Johannes
Plenio, Martin B.
Prior, Javier
Jelezko, Fedor
author_facet Vetter, Philipp J.
Findler, Christoph
Verdú, Antonio
Kost, Matthias
Blinder, Rémi
Fuhrmann, Jens
Osterkamp, Christian
Lang, Johannes
Plenio, Martin B.
Prior, Javier
Jelezko, Fedor
contents Quantum simulation aims to recreate complex many-body phenomena in controlled environments, offering insights into dynamics that are otherwise difficult to model. Existing platforms, however, are often complex and costly to scale, typically requiring ultra-pure vacuum or low temperatures. Here, we realize a room-temperature quantum simulator using a thin ${}^{13}\text{C}$ nuclear spin layer in diamond. Nearby nitrogen-vacancy centers enable polarization, readout, and, combined with radio-frequency fields, coherent control of the nuclear spins. We demonstrate strong, tunable interactions among the nuclear spins and use the system to investigate discrete time-crystalline order. By combining ease of use with operation at ambient temperatures, our work opens new opportunities for investigating strongly correlated many-body effects.
format Preprint
id arxiv_https___arxiv_org_abs_2510_27374
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Room-Temperature Quantum Simulation with Atomically Thin Nuclear Spin Layers in Diamond
Vetter, Philipp J.
Findler, Christoph
Verdú, Antonio
Kost, Matthias
Blinder, Rémi
Fuhrmann, Jens
Osterkamp, Christian
Lang, Johannes
Plenio, Martin B.
Prior, Javier
Jelezko, Fedor
Quantum Physics
Quantum simulation aims to recreate complex many-body phenomena in controlled environments, offering insights into dynamics that are otherwise difficult to model. Existing platforms, however, are often complex and costly to scale, typically requiring ultra-pure vacuum or low temperatures. Here, we realize a room-temperature quantum simulator using a thin ${}^{13}\text{C}$ nuclear spin layer in diamond. Nearby nitrogen-vacancy centers enable polarization, readout, and, combined with radio-frequency fields, coherent control of the nuclear spins. We demonstrate strong, tunable interactions among the nuclear spins and use the system to investigate discrete time-crystalline order. By combining ease of use with operation at ambient temperatures, our work opens new opportunities for investigating strongly correlated many-body effects.
title Room-Temperature Quantum Simulation with Atomically Thin Nuclear Spin Layers in Diamond
topic Quantum Physics
url https://arxiv.org/abs/2510.27374