Testing unconventional decoherence models with atoms in optical lattices

Abstract: Various models have been proposed in which the Schrödinger equation is modified to account for a decay of spatial coherences of massive objects. While optomechanical systems and matter-wave interferometry with large clusters are promising candidates to test these models, we here show that using available techniques for atoms in optical lattices, some of these models can be efficiently tested.In particular, we compare unconventional decoherence due to quantum gravity as introduced by Ellis and co-workers [Phys.… Show more

“…The master equation follows straightforwardly from taking the partial time derivative of Eq. (31). If only local interactions are induced within the open subsystem, the master equation takes the form…”

“…They are exploited to explore a wide range of phenomena. These include probing the time evolution of fundamental constants and searching for new forces [24][25][26][27][28], testing gravitationally induced decoherence [29][30][31], realizing macroscopic quantum superpositions [32] to probe so-called collapse models [33][34][35][36][37], and constraining models of dark matter and dark energy, using dielectric nanospheres levitated in laser beams [38,39], as well as atom-interferometry searches for fifth forces mediated by light scalar fields [40][41][42][43][44][45][46].…”

Open quantum dynamics induced by light scalar fields

“…The master equation follows straightforwardly from taking the partial time derivative of Eq. (31). If only local interactions are induced within the open subsystem, the master equation takes the form…”

“…They are exploited to explore a wide range of phenomena. These include probing the time evolution of fundamental constants and searching for new forces [24][25][26][27][28], testing gravitationally induced decoherence [29][30][31], realizing macroscopic quantum superpositions [32] to probe so-called collapse models [33][34][35][36][37], and constraining models of dark matter and dark energy, using dielectric nanospheres levitated in laser beams [38,39], as well as atom-interferometry searches for fifth forces mediated by light scalar fields [40][41][42][43][44][45][46].…”

Open quantum dynamics induced by light scalar fields