Theory of quantum systems

Determination of universal critical exponents using Lee-Yang theory

Physical Review Research American Physical Society (APS) 1:2 (2019) 023004

Authors:

Aydin Deger, Christian Flindt

Enhanced localization and protection of topological edge states due to geometric frustration

Physical Review B American Physical Society (APS) 100:12 (2019) 125123

Authors:

L Madail, S Flannigan, AM Marques, AJ Daley, RG Dias

Excitation Modes of Bright Matter-Wave Solitons.

Physical review letters 123:12 (2019) 123602

Authors:

Andrea Di Carli, Craig D Colquhoun, Grant Henderson, Stuart Flannigan, Gian-Luca Oppo, Andrew J Daley, Stefan Kuhr, Elmar Haller

Abstract:

We experimentally study the excitation modes of bright matter-wave solitons in a quasi-one-dimensional geometry. The solitons are created by quenching the interactions of a Bose-Einstein condensate of cesium atoms from repulsive to attractive in combination with a rapid reduction of the longitudinal confinement. A deliberate mismatch of quench parameters allows for the excitation of breathing modes of the emerging soliton and for the determination of its breathing frequency as a function of atom number and confinement. In addition, we observe signatures of higher-order solitons and the splitting of the wave packet after the quench. Our experimental results are compared to analytical predictions and to numerical simulations of the one-dimensional Gross-Pitaevskii equation.

Treelike Interactions and Fast Scrambling with Cold Atoms.

Physical review letters 123:13 (2019) 130601

Authors:

Gregory Bentsen, Tomohiro Hashizume, Anton S Buyskikh, Emily J Davis, Andrew J Daley, Steven S Gubser, Monika Schleier-Smith

Abstract:

We propose an experimentally realizable quantum spin model that exhibits fast scrambling, based on nonlocal interactions that couple sites whose separation is a power of 2. By controlling the relative strengths of deterministic, nonrandom couplings, we can continuously tune from the linear geometry of a nearest-neighbor spin chain to an ultrametric geometry in which the effective distance between spins is governed by their positions on a tree graph. The transition in geometry can be observed in quench dynamics, and is furthermore manifest in calculations of the entanglement entropy. Between the linear and treelike regimes, we find a peak in entanglement and exponentially fast spreading of quantum information across the system. Our proposed implementation, harnessing photon-mediated interactions among cold atoms in an optical cavity, offers a test case for experimentally observing the emergent geometry of a quantum many-body system.

Enhanced Superexchange in a Tilted Mott Insulator

(2019)

Authors:

Ivana Dimitrova, Niklas Jepsen, Anton Buyskikh, Araceli Venegas-Gomez, Jesse Amato-Grill, Andrew Daley, Wolfgang Ketterle