Date:10:00am, July 2, 2010
Venue:Conference Hall 322,Science Building
Title: Ultracold Molecules, Entangled Quantum Dynamics, and the Molecular Hubbard Hamiltonian
Speaker: Lincoln D. Carr, Associate Professor Department of Physics Colorado School of Mines
Abstract:An ultracold gas of heteronuclear alkali dimer molecules with hyperfine structure loaded into a one-dimensional optical lattice is investigated. The Hyperfine Molecular Hubbard Hamiltonian
(HMHH), an effective low-energy lattice Hamiltonian, is derived from first principles. The large permanent electric dipole moment of these molecules gives rise to long range dipole-dipole forces in a DC electric field and allows for transitions between rotational states in an AC microwave field. Additionally, a strong magnetic field can be used to control the hyperfine degrees of freedom independently of the rotational degrees of freedom. By tuning the angle between the DC electric and magnetic fields and the strength of the AC field it is possible to control the number of internal states involved in the dynamics as well as the degree of correlation between the spatial and internal degrees of freedom. The HMHH’s unique features have direct
experimental consequences such as quantum dephasing, tunable complexity, and the dependence of the phase diagram on the molecular state.
References:1. M. L. Wall and L. D. Carr, "The Hyperfine Molecular Hubbard Hamiltonian," Phys. Rev. A, in press, e-print arXiv:1003.0627 (2010)
2. M. L. Wall and L. D. Carr, "Emergent Time Scales in Entangled Quantum Dynamics of Ultracold Molecules in Optical Lattices," New J. Phys. v. 11, p. 055027 (2009)
3. L. D. Carr, David DeMille, Roman V. Krems, and Jun Ye, "Cold and Ultracold Molecules: Science, Technology, and Applications," New J. Phys. v. 11, p. 055049 (2009)