Coherence and decay within Bose-Einstein condensates – beyond Bogoliubov N. Katz 1, E. Rowen 1, R. Pugatch 1, N. Bar-gill 1 and N. Davidson 1, I. Mazets.

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Presentation transcript:

Coherence and decay within Bose-Einstein condensates – beyond Bogoliubov N. Katz 1, E. Rowen 1, R. Pugatch 1, N. Bar-gill 1 and N. Davidson 1, I. Mazets 2 and G. Kurizki 2 )R. Ozeri and J. Steinhauer) 1. Department of Physics of Complex Systems, 2. Department of Chemical Physics, Weizmann Institute of Science, Rehovot 76100, Israel For more information – see my webpage:

Outline Weak Bogoliubov excitations Fringe spectroscopy Strong Excitations Spectrum of BEC oscillating in a lattice Time domain – suppression of dephasing Decay of these states Probing many-body correlation times (theory)

Experimental set-up 87 Rb atoms in the ground state. N 0 = 1-5x10 5 atoms. T ~ 0.3 T c ~ 100 nK ~95% of atoms in the ground state Chemical potential  /h = 2 – 4 kHz

Time of flight (absorption imaging) T>TcT=Tc T<Tc

TOF image of an excited condensate Bragg Spectroscopy J. Stenger et al., PRL 82, 4569 (1999) (Ketterle); M. Kozuma et al., PRL 82, 871(1999) (Phillips); J. Steinhauer et al., PRL 88, (2002) (Davidson).

Bogoliubov spectrum k(    E(  low k limit: Phonon regime high k limit: Free particle regime J. Steinhauer et al., PRL 88, (2002) (Davidson.

Excitation Spectrum: a roadmap

Can possibly observe single particle excitations! Fringe visibility: a spectroscopic tool Fringe visibility N. Katz, R.Ozeri, J. Steinhauer, N. Davidson, C. Tozzo and F. Dalfovo, PRL 93, (2004). Heterodyne detection – matter wave interference counting visibility

 /6  /2 ~~ ~12  Strong excitations at high momenta N. Katz, R. Ozeri, E. Rowen, E. Gershnabel and N. Davidson, Phys. Rev. A 70, (2004)

Strong excitation – splitting in spectrum pumpprobe E. Rowen, N. Katz, R. Ozeri, E. Gershnabel and N. Davidson, cond-mat/ (2004). time (μsec)frequency (kHz) For a dressed state view of atomic mode mixing – see Eitan Rowen’s poster (Mo-15)

Dynamics: decoherence vs. dephasing Decoherence+dephasing Momentum measurement Total momentum Excitation fraction Only dephasing Agrees with Gross-Pitaevskii!! Population measurement: Excitation fraction N. Katz, R. Ozeri, E. Rowen, E. Gershnabel and N. Davidson, Phys. Rev. A 70, (2004)

Suppression of mean field broadening Detuning (kHz) Gain mean-field Pay mean-field WeakStrong Suppression of mean field and Doppler broadening E0kE0k E0kE0k Excited population Result: Coherence enhanced by more than a factor of 10.

Collisions in the lattice experiment Bloch band model Stochastic GPE simulation Coupling to a nontrival continuum… E. Rowen, N. Katz, R. Ozeri, E. Gershnabel and N. Davidson, cond- mat/ (2004). A.A. Norie, R. J Ballagh and C.W. Gardiner, cond-mat/

Probing correlations - Raman Scheme: Excite off resonance (positive detuning Δ) Raman momentum states (q), Monitor the decay products of these states as a function of time Raman beams Off-resonance Raman excitation Decay products I. Mazets, G. Kurizki, N. Katz and N. Davidson, cond-mat/

Zeno effects in BEC

Observing Zeno effects Pair production rate Golden Rule result Modulated frequency

Summary - physics beyond Bogoliubov Heterodyne detection of few excitations Strong excitations – spectra and decay Many-body correlation time for Raman excitations

Dynamical instabilities (simulations) What happens when the Bragg pulse is at intermediate intensity (comparable to the mean-field)? A. Vardi and J. R. Anglin, Phys. Rev. Lett. 86, 568 (2001).