Synchronization of strongly interacting alkali-metal spins

Or Katz; Ofer Firstenberg

doi:10.1103/PhysRevA.98.012712

Synchronization of strongly interacting alkali-metal spins

Or Katz, Ofer Firstenberg

Department of Physics of Complex Systems

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

The spins of gaseous alkali-metal atoms are commonly assumed to oscillate at a constant hyperfine frequency, which for many years has been used to define a standard unit of time, the second. Indeed, under standard experimental conditions, the spins oscillate independently, only weakly perturbed and slowly decaying due to random spin-spin collisions. Here we consider a different, unexplored regime of very dense gas, where collisions, more frequent than the hyperfine frequency, dominate the dynamics. We find that the hyperfine oscillations become significantly longer lived, and their frequency becomes dependent on the state of the ensemble, manifesting strong nonlinear dynamics. We reveal that the nonlinearity originates from a many-body interaction which synchronizes the electronic spins, driving them into a single collective mode. The conditions for experimental realizations of this regime are outlined.

Original language	English
Article number	012712
Number of pages	8
Journal	Physical Review A
Volume	98
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.98.012712
State	Published - 25 Jul 2018

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title = "Synchronization of strongly interacting alkali-metal spins",

abstract = "The spins of gaseous alkali-metal atoms are commonly assumed to oscillate at a constant hyperfine frequency, which for many years has been used to define a standard unit of time, the second. Indeed, under standard experimental conditions, the spins oscillate independently, only weakly perturbed and slowly decaying due to random spin-spin collisions. Here we consider a different, unexplored regime of very dense gas, where collisions, more frequent than the hyperfine frequency, dominate the dynamics. We find that the hyperfine oscillations become significantly longer lived, and their frequency becomes dependent on the state of the ensemble, manifesting strong nonlinear dynamics. We reveal that the nonlinearity originates from a many-body interaction which synchronizes the electronic spins, driving them into a single collective mode. The conditions for experimental realizations of this regime are outlined.",

author = "Or Katz and Ofer Firstenberg",

note = "We thank O. Peleg, R. Shaham for helpful discussions and A. Tsinovoy for help in calculation of the chemical equilibrium coefficients. We acknowledge financial support by the Israel Science Foundation and ICORE, the European Research Council starting investigator grant Q-PHOTONICS 678674, the Minerva Foundation, the Sir Charles Clore research prize, and the Laboratory in Memory of Leon and Blacky Broder.",

year = "2018",

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doi = "10.1103/PhysRevA.98.012712",

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AU - Katz, Or

AU - Firstenberg, Ofer

N1 - We thank O. Peleg, R. Shaham for helpful discussions and A. Tsinovoy for help in calculation of the chemical equilibrium coefficients. We acknowledge financial support by the Israel Science Foundation and ICORE, the European Research Council starting investigator grant Q-PHOTONICS 678674, the Minerva Foundation, the Sir Charles Clore research prize, and the Laboratory in Memory of Leon and Blacky Broder.

PY - 2018/7/25

Y1 - 2018/7/25

N2 - The spins of gaseous alkali-metal atoms are commonly assumed to oscillate at a constant hyperfine frequency, which for many years has been used to define a standard unit of time, the second. Indeed, under standard experimental conditions, the spins oscillate independently, only weakly perturbed and slowly decaying due to random spin-spin collisions. Here we consider a different, unexplored regime of very dense gas, where collisions, more frequent than the hyperfine frequency, dominate the dynamics. We find that the hyperfine oscillations become significantly longer lived, and their frequency becomes dependent on the state of the ensemble, manifesting strong nonlinear dynamics. We reveal that the nonlinearity originates from a many-body interaction which synchronizes the electronic spins, driving them into a single collective mode. The conditions for experimental realizations of this regime are outlined.

AB - The spins of gaseous alkali-metal atoms are commonly assumed to oscillate at a constant hyperfine frequency, which for many years has been used to define a standard unit of time, the second. Indeed, under standard experimental conditions, the spins oscillate independently, only weakly perturbed and slowly decaying due to random spin-spin collisions. Here we consider a different, unexplored regime of very dense gas, where collisions, more frequent than the hyperfine frequency, dominate the dynamics. We find that the hyperfine oscillations become significantly longer lived, and their frequency becomes dependent on the state of the ensemble, manifesting strong nonlinear dynamics. We reveal that the nonlinearity originates from a many-body interaction which synchronizes the electronic spins, driving them into a single collective mode. The conditions for experimental realizations of this regime are outlined.

U2 - 10.1103/PhysRevA.98.012712

DO - 10.1103/PhysRevA.98.012712

M3 - مقالة

SN - 2469-9926

VL - 98

JO - Physical Review A

JF - Physical Review A

IS - 1

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ER -

Synchronization of strongly interacting alkali-metal spins

Abstract

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