Observation of the topological Anderson insulator in disordered atomic wires (1802.02109v1)

Abstract: Topology and disorder have deep connections and a rich combined influence on quantum transport. In order to probe these connections, we synthesized one-dimensional chiral symmetric wires with controllable disorder via spectroscopic Hamiltonian engineering, based on the laser-driven coupling of discrete momentum states of ultracold atoms. We characterize the system's topology through measurement of the mean chiral displacement of the bulk density extracted from quench dynamics. We find evidence for the topological Anderson insulator phase, in which the band structure of an otherwise trivial wire is driven topological by the presence of added disorder. In addition, we observed the robustness of topological wires to weak disorder and measured the transition to a trivial phase in the presence of strong disorder. Atomic interactions in this quantum simulation platform will enable future realizations of strongly interacting topological fluids.

• The paper presents the first experimental observation of a disorder-induced topological Anderson insulator phase, confirming long-standing theoretical predictions.
• It employs precise spectroscopic Hamiltonian engineering and mean chiral displacement measurements in synthetic AIII wires to quantify topological transitions.
• The study demonstrates that controlled disorder can drive transitions between topological and trivial phases, opening new avenues for engineered quantum states.

Observation of the Topological Anderson Insulator in Disordered Atomic Wires

The paper presents a comprehensive experimental observation of the topological Anderson insulator (TAI) in one-dimensional disordered atomic wires. The investigation leverages the concepts of topology and disorder, which have a profound combined influence on quantum transport, explored through a quantum simulation involving ultra-cold atoms. Utilizing spectroscopic Hamiltonian engineering, the researchers synthesized one-dimensional chiral symmetric wires with controllable disorder by manipulating the laser-driven coupling of discrete momentum states. The paper reports significant findings, including the detection of the TAI phase, a milestone that has evaded experimental realization owing to challenges in material systems and quantum simulators.

Experimental Design and Observations

The experiment measures the mean chiral displacement (MCD) post-quench dynamics to characterize the topology of this synthesized system. The primary focus is on observing how disorder modifies a band structure's topology, particularly demonstrating that disorder can induce topological phases within systems that are non-topological in the clean limit.

1. Topological to Trivial Transition: The experiment first demonstrates that topological wires, such as those based on the Su-Schrieffer-Heeger model showing chiral symmetry, are robust against weak disorder. With strong disorder, the system transitions from a topological to a trivial phase.
2. Trivial to Topological (TAI Phase): More intriguingly, they report the induction of a nontrivial topological band structure, the elusive TAI phase, via adding static disorder to an incipient non-topological system. This observation was made possible with synthetically controlled disorder in AIII-class wires, confirming theoretical predictions regarding the existence of such a phase in 1D systems.

The experimental setup involved quenching on precise tunnel couplings in synthetic lattices composed of ultracold atomic momentum states. By applying a sudden quench and measuring the resultant MCD dynamics, the team quantitatively deduced the winding number associated with the system's topology.

Numerical Simulations and Phase Transition

The results obtained exhibit agreement with numerical simulations, indicating the robustness and accuracy of the method. The experiments confirm the existence of a disorder-driven topological transition as depicted in the computed phase diagram for both BDI and AIII class wires.

In BDI wires, the phase transition from topological to trivial was demonstrated by observing the behavior of the MCD as disorder is incremented. Conversely, AIII wires showed that the inclusion of disorder at certain strengths could increase the MCD, consistent with predictions of the TAI phase. The deductions were validated against numerical simulations executed for long times and larger system sizes, displaying sharper transitions characteristic of topological phases.

Implications and Future Directions

The paper's findings imply potential pathways for robust implementations of topological quantum states in engineered disordered systems. The successful demonstration of the TAI phase suggests disorder as a tunable feature to drive and control topological phases, absent in classical condensed matter scenarios.

Looking forward, incorporating atomic interactions could lead to investigations of strongly correlated topological fluids, providing a more profound understanding of topological phases in interactive environments. Enabling studies on disorder-induced quantum criticality, atomic implementations could explore effects such as logarithmic delocalization and finer features of random-singlet transitions, enriching the knowledge of quantum phase transitions in systems with postulated topological protections.

In conclusion, this paper contributes a critical experimental observation of disordered topological phases, aligning with theoretical predictions and providing a versatile platform for future exploration in quantum physics and materials science. The ability to control topology via disorder in quantum simulations provides promising avenues for further explorations into novel quantum states and their applications.