We present a new method for generating a regular train of ultrashort optical pulses in a prepared two-level medium. The train develops from incident monochromatic probe radiation travelling in a medium of atoms, which are in a quantum mechanical superposition of dressed internal states. In the frame of linear theory for the probe radiation, the energy of individual pulses is an exponentially growing function of atom density and of interaction cross section. Pulse repetition rate is determined by the pump field's generalized Rabi frequency and can be around 1 THz and greater.We also show that the terms, extra to the dipole approximation, endow the gas by a new property: non-saturating dependence of refractive index on dressing monochromatic field intensity. Contribution of these nonsaturating terms can be compatible with the main dipole approximation term contribution in the wavelength region of about ten micrometers (the range of CO 2 laser) or larger.
In current experiments with cold quantum gases in periodic potentials, interference fringe contrast is typically the easiest signal in which to look for effects of non-trivial many-body dynamics. In order better to calibrate such measurements, we analyse the background effect of thermal decoherence as it occurs in the absence of dynamical interparticle interactions. We study the effect of optical lattice potentials, as experimentally applied, on the condensed fraction of a non-interacting Bose gas in local thermal equilibrium at finite temperatures. We show that the experimentally observed decrease of the condensate fraction in the presence of the lattice can be attributed, up to a threshold lattice height, purely to ideal gas thermodynamics; conversely we confirm that sharper decreases in first-order coherence observed in stronger lattices are indeed attributable to many-body physics. Our results also suggest that the fringe visibility 'kinks' observed in F. Gerbier et al., Phys. Rev. Lett. 95, 050404 (2005) may be explained in terms of the competition between increasing lattice strength and increasing mean gas density, as the gaussian profile of the red-detuned lattice lasers also increases the effective strength of the harmonic trap.
We describe the parametric down conversion process in a two-level atomic gas, where the atoms are in a superposition state of relevant energy levels. This superposition results in splitting of the phase matching condition into three different conditions. Another, more important, peculiarity of the system under discussion is the nonsaturability of amplification coefficients with increasing pump wave intensity, under 'sideband' generation conditions.
The eigenstate problem of the Jaynes–Cummings model on the basis of a
complete Hamiltonian, including the centre-of-mass kinetic energy operator, is
considered. The energy spectrum and wavefunctions in the standing-wave (SW)
and counterpropagating-wave (CPW) cases are calculated and compared with
each other. It is shown that in the CPW case: (i) the atomic momentum
distribution is asymmetric; (ii) the concept of quasimomentum is not
applicable and instead the problem concerns the ordinary momentum;
(iii) atomic and photonic state distributions are self-consistent; and as a
consequence (iv) the mean number of photons in counterpropagating
travelling waves and mean atomic momentum are matched. Explicit analytic
expressions are proposed to describe the transition from counterpropagating
quantized waves to a standing wave. It is also shown that, if the recoil
energy is taken into account, the Doppleron resonance is split into two
branches, one of which diverges to Bragg-like resonance in high-order range.
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