Quantum systems engineering

Non-stationary dynamics and dissipative freezing in squeezed superradiance

(2019)

Authors:

Carlos Sánchez Muñoz, Berislav Buča, Joseph Tindall, Alejandro González-Tudela, Dieter Jaksch, Diego Porras

Bosonic fractional quantum hall states on a finite cylinder

Physical Review A American Physical Society 99 (2019) 033603

Authors:

Paolo Rosson, Michael Lubasch, Martin Kiffner, Dieter Jaksch

Abstract:

We investigate the ground-state properties of a bosonic Harper-Hofstadter model with local interactions on a finite cylindrical lattice with filling fraction ν = 1/2. We find that our system supports topologically ordered states by calculating the topological entanglement entropy, and its value is in good agreement with the theoretical value for the ν = 1/2 Laughlin state. By exploring the behavior of the density profiles, edge currents, and singleparticle correlation functions, we find that the ground state on the cylinder shows all signatures of a fractional quantum Hall state even for large values of the magnetic flux density. Furthermore, we determine the dependence of the correlation functions and edge currents on the interaction strength. We find that depending on the magnetic flux density, the transition toward Laughlin-like behavior can be either smooth or it can happen abruptly for some critical interaction strength

Discrete time crystal in globally driven interacting quantum systems without disorder

Physical Review A American Physical Society (APS) 99:3 (2019) 033618

Authors:

Chi Yu, Jirawat Tangpanitanon, Alexander W Glaetzle, Dieter Jaksch, Dimitris G Angelakis

Manipulating quantum materials with quantum light

Physical Review B American Physical Society 99:8 (2019) 085116

Authors:

Martin Kiffner, Jonathan Coulthard, Frank Schlawin, Arzhang Ardavan, Dieter Jaksch

Abstract:

We show that the macroscopic magnetic and electronic properties of strongly correlated electron systems can be manipulated by coupling them to a cavity mode. As a paradigmatic example we consider the Fermi-Hubbard model and find that the electron-cavity coupling enhances the magnetic interaction between the electron spins in the ground-state manifold. At half filling this effect can be observed by a change in the magnetic susceptibility. At less than half filling, the cavity introduces a next-nearest-neighbor hopping and mediates a long-range electron-electron interaction between distant sites. We study the ground-state properties with tensor network methods and find that the cavity coupling can induce a phase characterized by a momentum-space pairing effect for electrons.

Ultracold molecules for quantum simulation: rotational coherences in CaF and RbCs

Quantum Science and Technology IOP Publishing 4:1 (2018) 014010

Authors:

JA Blackmore, L Caldwell, PD Gregory, EM Bridge, R Sawant, J Aldegunde, Jordi Mur Petit, Dieter Jaksch, JM Hutson, BE Sauer, SL Cornish

Abstract:

Polar molecules offer a new platform for quantum simulation of systems with long-range interactions, based on the electrostatic interaction between their electric dipole moments. Here, we report the development of coherent quantum state control using microwave fields in $^{40}$Ca$^{19}$F and $^{87}$Rb$^{133}$Cs molecules, a crucial ingredient for many quantum simulation applications. We perform Ramsey interferometry measurements with fringe spacings of $\sim 1~\rm kHz$ and investigate the dephasing time of a superposition of $N=0$ and $N=1$ rotational states when the molecules are confined. For both molecules, we show that a judicious choice of molecular hyperfine states minimises the impact of spatially varying transition-frequency shifts across the trap. For magnetically trapped $^{40}$Ca$^{19}$F we use a magnetically insensitive transition and observe a coherence time of 0.61(3)~ms. For optically trapped $^{87}$Rb$^{133}$Cs we exploit an avoided crossing in the AC Stark shifts and observe a maximum coherence time of 0.75(6)~ms.