Rydberg soft matter
Lead Research Organisation:
University of Nottingham
Department Name: Sch of Physics & Astronomy
Abstract
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Organisations
Publications
Rotondo P
(2018)
Open quantum generalisation of Hopfield neural networks
in Journal of Physics A: Mathematical and Theoretical
Hickey J
(2016)
Signatures of many-body localisation in a system without disorder and the relation to a glass transition
in Journal of Statistical Mechanics: Theory and Experiment
Levi E
(2016)
Crystalline structures in a one-dimensional two-component lattice gas with 1/r a interactions
in Journal of Statistical Mechanics: Theory and Experiment
GutiƩrrez R
(2019)
Accelerated relaxation and suppressed dynamic heterogeneity in a kinetically constrained (East) model with swaps
in Journal of Statistical Mechanics: Theory and Experiment
GutiƩrrez R
(2016)
Front propagation versus bulk relaxation in the annealing dynamics of a kinetically constrained model of ultrastable glasses
in Journal of Statistical Mechanics: Theory and Experiment
Zhang C
(2020)
Submicrosecond entangling gate between trapped ions via Rydberg interaction.
in Nature
Gorniaczyk H
(2016)
Enhancement of Rydberg-mediated single-photon nonlinearities by electrically tuned Förster resonances.
in Nature communications
Ostmann M
(2017)
Non-adiabatic quantum state preparation and quantum state transport in chains of Rydberg atoms
in New Journal of Physics
Levi E
(2015)
Crystalline structures and frustration in a two-component Rydberg gas
in New Journal of Physics
Marcuzzi M
(2015)
Non-equilibrium universality in the dynamics of dissipative cold atomic gases
in New Journal of Physics
Buonaiuto G
(2019)
Dynamical creation and detection of entangled many-body states in a chiral atom chain
in New Journal of Physics
GutiƩrrez R
(2016)
Non-equilibrium fluctuations and metastability arising from non-additive interactions in dissipative multi-component Rydberg gases
in New Journal of Physics
Needham J
(2019)
Subradiance-protected excitation transport
in New Journal of Physics
Rose D
(2021)
A reinforcement learning approach to rare trajectory sampling
in New Journal of Physics
Bai Z
(2019)
Stable single light bullets and vortices and their active control in cold Rydberg gases
in Optica
Yan D
(2020)
Electromagnetically induced transparency of interacting Rydberg atoms with two-body dephasing.
in Optics express
Simonelli C.
(2017)
Experimental signatures of an absorbing-state phase transition in an open driven many-body quantum system
in Optics InfoBase Conference Papers
Garrahan J
(2018)
Aspects of non-equilibrium in classical and quantum systems: Slow relaxation and glasses, dynamical large deviations, quantum non-ergodicity, and open quantum dynamics
in Physica A: Statistical Mechanics and its Applications
Li Y
(2018)
Supersolidity of lattice bosons immersed in strongly correlated Rydberg dressed atoms
in Physical Review A
Ostmann M
(2019)
Localization in spin chains with facilitation constraints and disordered interactions
in Physical Review A
Bettles R
(2017)
Topological properties of a dense atomic lattice gas
in Physical Review A
Kouzelis A
(2020)
Dissipative quantum state preparation and metastability in two-photon micromasers
in Physical Review A
Lesanovsky I
(2019)
Dressed dense atomic gases
in Physical Review A
Niranjan A
(2020)
Landau-Zener transitions and adiabatic impulse approximation in an array of two Rydberg atoms with time-dependent detuning
in Physical Review A
Lan Z
(2016)
Quantum melting of two-component Rydberg crystals
in Physical Review A
| Description | We explored the analogy between soft matter systems, such as colloids, and Rydberg gases, and establish a basis for a quantum emulation of (augmented) soft matter systems using atomic gases, with the aim to break new ground in the understanding of non-equilibrium behaviour of many-body quantum systems. |
| Exploitation Route | Academic impact, through a major advance in our understanding of systems far-from equilibrium and ability to control the properties of complex materials. Technological impact, from the experimental part of the programme in Durham. Training, as we produced highly trained personnel at all levels. And Outreach. |
| Sectors | Other |