Add to ORKGWe generalize the scope of Floquet engineering to include spatially-dependent modulations of an optical system. As an application, we show that we can transform large classes of Hamiltonians into one another by driving them in a time-periodic but spatially non-uniform manner. We propose several experimental realizations in 1D optical lattices, including freeing disordered lattices from Anderson localization, as well as effectively disconnecting all their sites. These techniques straightforwardly extend to more complex classes of systems
Electrons in a lattice exhibit time-periodic motion, known as Bloch oscillation, when subject to an ...
We show how second-order Floquet engineering can be employed to realize systems in which many-body l...
Shaking a lattice system, by modulating the location of its sites periodically in time, is a powerfu...
The concept of Floquet engineering is to subject a quantum system to time-periodic driving in such a...
We describe a method to generate a synthetic gauge potential for ultracold atoms held in an optical ...
Floquet engineering, the control of quantum systems using periodic driving, is an old concept in con...
A driven quantum system was recently studied in the context of nonequilibrium phase transitions and ...
Floquet engineering is a versatile tool that uses periodic driving of a quantum system to build nove...
When a d-dimensional quantum system is subjected to a periodic drive, it may be treated as a (d+1)-d...
We show that a quantum many-body system may be controlled by means of Floquet engineering, i.e., the...
A driven quantum system has been recently studied in the context of nonequilibrium phase transitions...
Ultracold atoms in optical lattices are a versatile tool for precisely-controlled quantum simulation...
When a physical system is subjected to a strong external multifrequency drive, its dynamics can be c...
With light-matter interaction extending into strong regime, as well as rapid development of laser te...
We demonstrate that the electronic structure of a material can be deformed into Floquet pseudobands ...
Electrons in a lattice exhibit time-periodic motion, known as Bloch oscillation, when subject to an ...
We show how second-order Floquet engineering can be employed to realize systems in which many-body l...
Shaking a lattice system, by modulating the location of its sites periodically in time, is a powerfu...
The concept of Floquet engineering is to subject a quantum system to time-periodic driving in such a...
We describe a method to generate a synthetic gauge potential for ultracold atoms held in an optical ...
Floquet engineering, the control of quantum systems using periodic driving, is an old concept in con...
A driven quantum system was recently studied in the context of nonequilibrium phase transitions and ...
Floquet engineering is a versatile tool that uses periodic driving of a quantum system to build nove...
When a d-dimensional quantum system is subjected to a periodic drive, it may be treated as a (d+1)-d...
We show that a quantum many-body system may be controlled by means of Floquet engineering, i.e., the...
A driven quantum system has been recently studied in the context of nonequilibrium phase transitions...
Ultracold atoms in optical lattices are a versatile tool for precisely-controlled quantum simulation...
When a physical system is subjected to a strong external multifrequency drive, its dynamics can be c...
With light-matter interaction extending into strong regime, as well as rapid development of laser te...
We demonstrate that the electronic structure of a material can be deformed into Floquet pseudobands ...
Electrons in a lattice exhibit time-periodic motion, known as Bloch oscillation, when subject to an ...
We show how second-order Floquet engineering can be employed to realize systems in which many-body l...
Shaking a lattice system, by modulating the location of its sites periodically in time, is a powerfu...