Dipolar Bose-Hubbard model
Ethan Lake, Michael Hermele, T. Senthil
Abstract
We study a simple model of interacting bosons on a $d$-dimensional cubic lattice whose dynamics conserves both total boson number and total boson dipole moment. This model provides a simple framework in which several remarkable consequences of dipole conservation can be explored. As a function of chemical potential and hopping strength, the model can be tuned between gapped Mott insulating phases and various types of gapless condensates. The condensed phase realized at large hopping strengths, which we dub a Bose-Einstein insulator, is particularly interesting: despite having a Bose condensate, it is insulating, and despite being an insulator, it is compressible.
Topics & Concepts
BosonMott insulatorPhysicsDipoleCondensed matter physicsBose–Hubbard modelGapless playbackBose–Einstein condensateHubbard modelInsulator (electricity)Lattice (music)Statistical physicsQuantum mechanicsSuperconductivityOptoelectronicsAcousticsCold Atom Physics and Bose-Einstein CondensatesQuantum many-body systemsQuantum, superfluid, helium dynamics