Spontaneous formation of one-dimensional Rydberg crystals in an ultracold gas

T.H.P. van der Weerden; S.J.J.M.F. Kokkelmans; E.J.D. Vredenbregt

Spontaneous formation of one-dimensional Rydberg crystals in an ultracold gas

T.H.P. van der Weerden, S.J.J.M.F. Kokkelmans, E.J.D. Vredenbregt

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Rydberg atoms have experimentally interestingproperties such as strong long-range Van der Waals interactions and the dipole blockade effect. In optical lattices the blockade effect ensures that only one Rydberg excitation per site is allowed, effectively creating a Rydberg crystal. We theoretically show that it is also possible for a one-dimensional Rydberg crystal to spontaneously form in a random ensemble of atoms, e.g. a magneto-optical trap. This is done using an
existing Monte Carlo model [1] to simulate the excitation dynamics inside the intersection of two lasers for a two-step excitation scheme. With a blue-detuned laser for the upper transition, the first Rydberg excitation will occur after a relatively long time. That first Rydberg atom will then seed further Rydberg excitations, as the blockade effect shifts atoms at a certain distance into
resonance. If two dimensions of the laser intersection are smaller than the blockade radius, a one-dimensional Rydberg crystal will form.

Originele taal-2	Engels
Pagina's	64-64
Aantal pagina's	1
Status	Gepubliceerd - 11 okt. 2016
Evenement	40th Annual Meeting of the section Atomic Molecular and Optical Physics - Conference Center De Werelt , Lunteren, Nederland Duur: 11 okt. 2016 → 12 okt. 2016 Congresnummer: 40

Congres

Congres	40th Annual Meeting of the section Atomic Molecular and Optical Physics
Land/Regio	Nederland
Stad	Lunteren
Periode	11/10/16 → 12/10/16

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P71

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title = "Spontaneous formation of one-dimensional Rydberg crystals in an ultracold gas",

abstract = "Rydberg atoms have experimentally interestingproperties such as strong long-range Van der Waals interactions and the dipole blockade effect. In optical lattices the blockade effect ensures that only one Rydberg excitation per site is allowed, effectively creating a Rydberg crystal. We theoretically show that it is also possible for a one-dimensional Rydberg crystal to spontaneously form in a random ensemble of atoms, e.g. a magneto-optical trap. This is done using anexisting Monte Carlo model [1] to simulate the excitation dynamics inside the intersection of two lasers for a two-step excitation scheme. With a blue-detuned laser for the upper transition, the first Rydberg excitation will occur after a relatively long time. That first Rydberg atom will then seed further Rydberg excitations, as the blockade effect shifts atoms at a certain distance intoresonance. If two dimensions of the laser intersection are smaller than the blockade radius, a one-dimensional Rydberg crystal will form.",

author = "{van der Weerden}, T.H.P. and S.J.J.M.F. Kokkelmans and E.J.D. Vredenbregt",

note = "P71; 40th Annual Meeting of the section Atomic Molecular and Optical Physics ; Conference date: 11-10-2016 Through 12-10-2016",

year = "2016",

month = oct,

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language = "English",

pages = "64--64",

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T1 - Spontaneous formation of one-dimensional Rydberg crystals in an ultracold gas

AU - van der Weerden, T.H.P.

AU - Kokkelmans, S.J.J.M.F.

AU - Vredenbregt, E.J.D.

N1 - Conference code: 40

PY - 2016/10/11

Y1 - 2016/10/11

N2 - Rydberg atoms have experimentally interestingproperties such as strong long-range Van der Waals interactions and the dipole blockade effect. In optical lattices the blockade effect ensures that only one Rydberg excitation per site is allowed, effectively creating a Rydberg crystal. We theoretically show that it is also possible for a one-dimensional Rydberg crystal to spontaneously form in a random ensemble of atoms, e.g. a magneto-optical trap. This is done using anexisting Monte Carlo model [1] to simulate the excitation dynamics inside the intersection of two lasers for a two-step excitation scheme. With a blue-detuned laser for the upper transition, the first Rydberg excitation will occur after a relatively long time. That first Rydberg atom will then seed further Rydberg excitations, as the blockade effect shifts atoms at a certain distance intoresonance. If two dimensions of the laser intersection are smaller than the blockade radius, a one-dimensional Rydberg crystal will form.

AB - Rydberg atoms have experimentally interestingproperties such as strong long-range Van der Waals interactions and the dipole blockade effect. In optical lattices the blockade effect ensures that only one Rydberg excitation per site is allowed, effectively creating a Rydberg crystal. We theoretically show that it is also possible for a one-dimensional Rydberg crystal to spontaneously form in a random ensemble of atoms, e.g. a magneto-optical trap. This is done using anexisting Monte Carlo model [1] to simulate the excitation dynamics inside the intersection of two lasers for a two-step excitation scheme. With a blue-detuned laser for the upper transition, the first Rydberg excitation will occur after a relatively long time. That first Rydberg atom will then seed further Rydberg excitations, as the blockade effect shifts atoms at a certain distance intoresonance. If two dimensions of the laser intersection are smaller than the blockade radius, a one-dimensional Rydberg crystal will form.

M3 - Poster

SP - 64

EP - 64

T2 - 40th Annual Meeting of the section Atomic Molecular and Optical Physics

Y2 - 11 October 2016 through 12 October 2016

ER -

Spontaneous formation of one-dimensional Rydberg crystals in an ultracold gas

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