7 research outputs found
Magneto-optical Feshbach resonance: Controlling cold collision with quantum interference
We propose a method of controlling two-atom interaction using both magnetic
and laser fields. We analyse the role of quantum interference between magnetic
and optical Feshbach resonances in controlling cold collision. In particular,
we demonstrate that this method allows us to suppress inelastic and enhance
elastic scattering cross sections. Quantum interference is shown to modify
significantly the threshold behaviour and resonant interaction of ultracold
atoms. Furthermore, we show that it is possible to manipulate not only the
spherically symmetric s-wave interaction but also the anisotropic higher
partial-wave interactions which are particularly important for high temperature
superfluid or superconducting phases of matter.Comment: 7 pages 3 figures, some minor errors are corrected, Accepted in J.
Phys.
Precise determination of Li cold collision parameters by radio-frequency spectroscopy on weakly bound molecules
We employ radio-frequency spectroscopy on weakly bound Li molecules
to precisely determine the molecular binding energies and the energy splittings
between molecular states for different magnetic fields. These measurements
allow us to extract the interaction parameters of ultracold Li atoms based
on a multi-channel quantum scattering model. We determine the singlet and
triplet scattering lengths to be and (1
= 0.0529177 nm), and the positions of the broad Feshbach resonances in
the energetically lowest three wave scattering channels to be 83.41(15) mT,
69.04(5) mT, and 81.12(10) mT
Suppression of power-broadening in strong-coupling photoassociation in the presence of a Feshbach resonance
Photoassociation (PA) spectrum in the presence of a magnetic Feshbach
resonance is analyzed. Nonperturbative solution of the problem yields
analytical expressions for PA linewidth and shift which are applicable for
arbitrary PA laser intensity and magnetic field tuning of Feshbach Resonance.
We show that by tuning magnetic field close to Fano minimum, it is possible to
suppress power broadening at increased laser intensities. This occurs due to
quantum interference of PA transitions from unperturbed and perturbed
continuum. Line narrowing at high laser intensities is accompanied by large
spectral shifts. We briefly discuss important consequences of line narrowing in
cold collisions.Comment: 12 pages, 5 figure
Theory of Radio Frequency Spectroscopy Experiments in Ultracold Fermi Gases and Their Relation to Photoemission Experiments in the Cuprates
In this paper we present an overview of radio frequency (RF) spectroscopy in
the atomic Fermi superfluids. An ultimate goal is to suggest new directions in
the cold gas research agenda from the condensed matter perspective.Our focus is
on the experimental and theoretical literature of cold gases and photoemission
spectroscopy of the cuprates particularly as it pertains to areas of overlap.
This paper contains a systematic overview of the theory of RF spectroscopy,
both momentum integrated and momentum resolved. We discuss the effects of
traps, population imbalance, final state interactions over the entire range of
temperatures and compare theory and experiment. We show that this broad range
of phenomena can be accomodated within the BCS-Leggett description of BCS-BEC
crossover and that this scheme also captures some of the central observations
in photoemission experiments in the cuprates. In this last context, we note
that the key themes which have emerged in cuprate photoemission studies involve
characterization of the fermionic self energy, of the pseudogap and of the
effects of superconducting coherence (in passing from above to below the
superfluid transition temperature, ).These issues have a counterpart in
the cold Fermi gases and it would be most useful in future to use these atomic
systems to address these and the more sweeping question of how to describe that
anomalous superfluid phase which forms in the presence of a normal state
excitation gap.Comment: 23 pages, 22 figure
Formation and interactions of cold and ultracold molecules: new challenges for interdisciplinary physics
Progress on researches in the field of molecules at cold and ultracold
temperatures is reported in this review. It covers extensively the experimental
methods to produce, detect and characterize cold and ultracold molecules
including association of ultracold atoms, deceleration by external fields and
kinematic cooling. Confinement of molecules in different kinds of traps is also
discussed. The basic theoretical issues related to the knowledge of the
molecular structure, the atom-molecule and molecule-molecule mutual
interactions, and to their possible manipulation and control with external
fields, are reviewed. A short discussion on the broad area of applications
completes the review.Comment: to appear in Reports on Progress in Physic
Cold and Ultracold Molecules: Science, Technology, and Applications
This article presents a review of the current state of the art in the
research field of cold and ultracold molecules. It serves as an introduction to
the Special Issue of the New Journal of Physics on Cold and Ultracold Molecules
and describes new prospects for fundamental research and technological
development. Cold and ultracold molecules may revolutionize physical chemistry
and few body physics, provide techniques for probing new states of quantum
matter, allow for precision measurements of both fundamental and applied
interest, and enable quantum simulations of condensed-matter phenomena.
Ultracold molecules offer promising applications such as new platforms for
quantum computing, precise control of molecular dynamics, nanolithography, and
Bose-enhanced chemistry. The discussion is based on recent experimental and
theoretical work and concludes with a summary of anticipated future directions
and open questions in this rapidly expanding research field.Comment: 82 pages, 9 figures, review article to appear in New Journal of
Physics Special Issue on Cold and Ultracold Molecule