Physical Review X (May 2020)

Realization of a Density-Dependent Peierls Phase in a Synthetic, Spin-Orbit Coupled Rydberg System

  • Vincent Lienhard,
  • Pascal Scholl,
  • Sebastian Weber,
  • Daniel Barredo,
  • Sylvain de Léséleuc,
  • Rukmani Bai,
  • Nicolai Lang,
  • Michael Fleischhauer,
  • Hans Peter Büchler,
  • Thierry Lahaye,
  • Antoine Browaeys

DOI
https://doi.org/10.1103/PhysRevX.10.021031
Journal volume & issue
Vol. 10, no. 2
p. 021031

Abstract

Read online Read online

We experimentally realize a Peierls phase in the hopping amplitude of excitations carried by Rydberg atoms, and observe the resulting characteristic chiral motion in a minimal setup of three sites. Our demonstration relies on the intrinsic spin-orbit coupling of the dipolar exchange interaction combined with time-reversal symmetry breaking by a homogeneous external magnetic field. Remarkably, the phase of the hopping amplitude between two sites strongly depends on the occupancy of the third site, thus leading to a correlated hopping associated with a density-dependent Peierls phase. We experimentally observe this density-dependent hopping and show that the excitations behave as anyonic particles with a nontrivial phase under exchange. Finally, we confirm the dependence of the Peierls phase on the geometrical arrangement of the Rydberg atoms.