163 research outputs found
Loading a continuous-wave atom laser by optical pumping techniques
Demonstrating that despite loss processes, Bose-Einstein condensates can be
formed in steady state is a prerequisite for obtaining a coherent beam of atoms
in a continuous-wave atom laser. In this paper we propose a method for loading
atoms into the thermal component of a Bose condensed cloud confined in a
magnetic trap. This method is aimed at allowing steady state dynamics to be
achieved. The proposed scheme involves loading atoms into the conservative
magnetic potential using the spontaneous emission of photons. We show that the
probability for the reabsorption of these photons may be small .Comment: 6 pages, 7 figure
Phase Separation in Bose-Fermi-Fermi Mixtures as a Probe of Fermi Superfluidity
We study the phase diagram of a mixture of Bose-Einstein condensate and a
two-component Fermi gas. In particular, we identify the regime where the
homogeneous system becomes unstable against phase separation. We show that,
under proper conditions, the phase separation phenomenon can be exploited as a
robust probe of Fermi superfluid
BCS-BEC crossover in the strongly correlated regime of ultra-cold Fermi gases
We study BCS-BEC crossover in the strongly correlated regime of two component rotating Fermi gases. We predict that the strong correlations induced by rotation will have the effect of modifying the crossover region relative to the non-rotating situation. We show via the two particle correlation function that the crossover smoothly connects the s-wave paired fermionic fractional quantum Hall state to the bosonic Laughlin stat
BCS-BEC crossover in a strongly correlated Fermi gas
We study the BCS-BEC crossover in the strongly correlated regime of an
ultra-cold rotating two component Fermi gas. Strong correlations are shown to
generate an additional long-range interaction which results in a modified
crossover region compared to the non-rotating situation. The two-particle
correlation function reveals a smooth crossover between the s-wave paired
fermionic fractional quantum Hall state and the bosonic Laughlin state.Comment: 4 pages, 3 figure
Finite-Temperature Study of Bose-Fermi Superfluid Mixtures
Ultra-cold atom experiments offer the unique opportunity to study mixing of
different types of superfluid states. Our interest is in superfluid mixtures
comprising particles with different statistics- Bose and Fermi. Such scenarios
occur naturally, for example, in dense QCD matter. Interestingly, cold atomic
experiments are performed in traps with finite spatial extent, thus critically
destabilizing the occurrence of various homogeneous phases. Critical to this
analysis is the understanding that the trapped system can undergo phase
separation, resulting in a unique situation where phase transition in either
species (bosons or fermions) can overlap with the phase separation between
possible phases. In the present work, we illustrate how this intriguing
interplay manifests in an interacting 2-species atomic mixture - one bosonic
and another fermionic with two spin components - within a realistic trap
configuration. We further show that such interplay of transitions can render
the nature of the ground state to be highly sensitive to the experimental
parameters and the dimensionality of the system.Comment: 9 pages, 7 figures; Accepted for publication in Phys. Rev.
Unconventional Spin Density Waves in Dipolar Fermi Gases
The conventional spin density wave (SDW) phase (Overhauser, 1962), as found
in antiferromagnetic metal for example (Fawcett 1988), can be described as a
condensate of particle-hole pairs with zero angular momentum, ,
analogous to a condensate of particle-particle pairs in conventional
superconductors. While many unconventional superconductors with Cooper pairs of
finite have been discovered, their counterparts, density waves with
non-zero angular momenta, have only been hypothesized in two-dimensional
electron systems (Nayak, 2000). Using an unbiased functional renormalization
group analysis, we here show that spin-triplet particle-hole condensates with
emerge generically in dipolar Fermi gases of atoms (Lu, Burdick, and
Lev, 2012) or molecules (Ospelkaus et al., 2008; Wu et al.) on optical lattice.
The order parameter of these exotic SDWs is a vector quantity in spin space,
and, moreover, is defined on lattice bonds rather than on lattice sites. We
determine the rich quantum phase diagram of dipolar fermions at half-filling as
a function of the dipolar orientation, and discuss how these SDWs arise amidst
competition with superfluid and charge density wave phases.Comment: 5 pages, 3 figure
Signatures of Strong Correlations in One-Dimensional Ultra-Cold Atomic Fermi Gases
Recent success in manipulating ultra-cold atomic systems allows to probe
different strongly correlated regimes in one-dimension. Regimes such as the
(spin-coherent) Luttinger liquid and the spin-incoherent Luttinger liquid can
be realized by tuning the inter-atomic interaction strength and trap
parameters. We identify the noise correlations of density fluctuations as a
robust observable (uniquely suitable in the context of trapped atomic gases) to
discriminate between these two regimes. Finally, we address the prospects to
realize and probe these phenomena experimentally using optical lattices.Comment: 4 pages, 2 figure
Shear Thickening Behaviour of Composite Propellant Suspension under Oscillatory Shear
Composite propellant suspensions consist of highly filled polymeric system wherein solid particles of different sizes and shapes are dispersed in a polymeric matrix. The rheological behaviour of a propellant suspension is characterised by viscoplasticity and shear rate and time dependant viscosity. The behaviour of composite propellant suspension has been studied under amplitude sweep test where tests were performed by continuously varying strain amplitude (strain in %, γ) by keeping the frequency and temperature constant and results are plotted in terms of log γ (strain amplitude) vs logGʹ and logGʺ (Storage modulus and loss modulus, respectively). It is clear from amplitude sweep test that dynamic moduli and complex viscosity show marked increase at critical strain amplitude after a plateau region, infering a shear thickening behaviour
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