Abstract
Applying time-periodic modulations is routinely used to control and design synthetic matter in quantum-engineered settings. In lattice systems, this approach is explored to engineer band structures with non-trivial topological properties, but also to generate exotic interaction processes. A prime example is density-assisted tunneling, by which the hopping amplitude of a particle between neighboring sites explicitly depends on their respective occupations. Here, we show how density-assisted tunneling can be tailored in view of simulating the effects of strain in synthetic graphene-type systems. Specifically, we consider a mixture of two atomic species on a honeycomb optical lattice: one species forms a Bose-Einstein condensate in an anisotropic harmonic trap, whose inhomogeneous density profile induces an effective uniaxial strain for the second species through density-assisted tunneling processes. In direct analogy with strained graphene, the second species experiences a pseudo-magnetic field, hence exhibiting relativistic Landau levels and the valley Hall effect. Our proposed scheme introduces a unique platform for the investigation of strain-induced gauge fields, opening the door to future studies of their possible interplay with quantum fluctuations and collective excitations.
Highlights
Applying time-periodic modulations is routinely used to control and design synthetic matter in quantum-engineered settings
One of the key methods to realize synthetic gauge potentials in quantum-engineered systems consists in driving the system periodically in time[35,36,37], a general scheme known as Floquet engineering[38]; in this driven-lattice context, tunneling matrix elements acquire welldesigned complex phase factors, known as Peierls phase factors, mimicking the Aharonov–Bohm effect caused by an external magnetic field
An exciting scenario, which has become more concrete and realistic over the last few years, concerns the realization of dynamical gauge fields in cold gases, namely, engineered gauge fields that experience a back-action from the matter degrees of freedom[52,53,54,55,56,57,58,59]
Summary
Applying time-periodic modulations is routinely used to control and design synthetic matter in quantum-engineered settings. Atoms form a weakly interacting BEC and where quantum fluctuations can be neglected; we note that such fluctuations could potentially affect the correlated hopping in Eq (14), but leave the study of this interesting effect for future work.
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