Quantum dynamical calculations of ultracold collisions induced by nonlinearly chirped light

J. L. Carini; J. A. Pechkis; C. E. Rogers; P. L. Gould; S. Kallush; R. Kosloff

doi:10.1103/PhysRevA.85.013424

Quantum dynamical calculations of ultracold collisions induced by nonlinearly chirped light

J. L. Carini^*
, J. A. Pechkis
, C. E. Rogers
, P. L. Gould
, S. Kallush
, R. Kosloff

^*Corresponding author for this work

Institute of Chemistry

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

10 Scopus citations

Abstract

We describe quantum dynamical calculations of ultracold 85Rb trap-loss collisions induced by pulses of light whose frequency is chirped on the nanosecond time scale. The chirped light excites the ground-state collisional wave function to the long-range attractive potential and escape from the trap is modeled by an absorbing boundary at short range. Both positive and negative chirps are considered and various chirp shapes and detunings are examined. For positive chirps, the loss rates are rather independent of the chirp shape. Negative chirps, on the other hand, show a dependence on chirp shape for detunings where collisional flux can be coherently returned to the ground state. These trends are consistent with the results of a recent experiment.

Original language	English
Article number	013424
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	85
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.85.013424
State	Published - 31 Jan 2012

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title = "Quantum dynamical calculations of ultracold collisions induced by nonlinearly chirped light",

abstract = "We describe quantum dynamical calculations of ultracold 85Rb trap-loss collisions induced by pulses of light whose frequency is chirped on the nanosecond time scale. The chirped light excites the ground-state collisional wave function to the long-range attractive potential and escape from the trap is modeled by an absorbing boundary at short range. Both positive and negative chirps are considered and various chirp shapes and detunings are examined. For positive chirps, the loss rates are rather independent of the chirp shape. Negative chirps, on the other hand, show a dependence on chirp shape for detunings where collisional flux can be coherently returned to the ground state. These trends are consistent with the results of a recent experiment.",

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AU - Carini, J. L.

AU - Pechkis, J. A.

AU - Rogers, C. E.

AU - Gould, P. L.

AU - Kallush, S.

AU - Kosloff, R.

PY - 2012/1/31

Y1 - 2012/1/31

N2 - We describe quantum dynamical calculations of ultracold 85Rb trap-loss collisions induced by pulses of light whose frequency is chirped on the nanosecond time scale. The chirped light excites the ground-state collisional wave function to the long-range attractive potential and escape from the trap is modeled by an absorbing boundary at short range. Both positive and negative chirps are considered and various chirp shapes and detunings are examined. For positive chirps, the loss rates are rather independent of the chirp shape. Negative chirps, on the other hand, show a dependence on chirp shape for detunings where collisional flux can be coherently returned to the ground state. These trends are consistent with the results of a recent experiment.

AB - We describe quantum dynamical calculations of ultracold 85Rb trap-loss collisions induced by pulses of light whose frequency is chirped on the nanosecond time scale. The chirped light excites the ground-state collisional wave function to the long-range attractive potential and escape from the trap is modeled by an absorbing boundary at short range. Both positive and negative chirps are considered and various chirp shapes and detunings are examined. For positive chirps, the loss rates are rather independent of the chirp shape. Negative chirps, on the other hand, show a dependence on chirp shape for detunings where collisional flux can be coherently returned to the ground state. These trends are consistent with the results of a recent experiment.

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Quantum dynamical calculations of ultracold collisions induced by nonlinearly chirped light

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