A Quantum Gas Microscope for the Kagome lattice
Lead Research Organisation:
UNIVERSITY OF CAMBRIDGE
Department Name: Physics
Abstract
We propose to develop novel microscopy technique for optical lattices, and to build the first Quantum Gas Microscope for the Kagome lattice in order to study the rich physics of frustration, flat bands, and novel strongly-correlated states.
During the last twenty years, ultracold atoms in optical lattices have emerged as clean and versatile model systems to study the many-body physics of interacting particles in periodic potentials. In particular, Quantum Gas Microscopes enable the observation and manipulation of lattice gases with single-site resolution.
Strong geometric frustration can prevent ordering and give rise to extensive degeneracies that enable novel strongly correlated phenomena. The paradigmatic example is the Kagome lattice, where destructive interferences between hopping paths give rise to a perfectly flat band and non-trivial spin liquid states.
In this project, we will employ Mott insulators and negative temperature states as gateways into the flat band and explore the complex phase diagrams and non-equilibrium dynamics of bosons, fermions, and bose-fermi mixtures in the Kagome lattice.
We will develop a novel microscopy technique based on e.g. the sequential imaging of sublattices. This technique can be directly adapted to many other bichromatic superlattices, providing access to crucial local quantities including local densities, spin textures, density fluctuations, and spin correlations with single-site resolution.
During the last twenty years, ultracold atoms in optical lattices have emerged as clean and versatile model systems to study the many-body physics of interacting particles in periodic potentials. In particular, Quantum Gas Microscopes enable the observation and manipulation of lattice gases with single-site resolution.
Strong geometric frustration can prevent ordering and give rise to extensive degeneracies that enable novel strongly correlated phenomena. The paradigmatic example is the Kagome lattice, where destructive interferences between hopping paths give rise to a perfectly flat band and non-trivial spin liquid states.
In this project, we will employ Mott insulators and negative temperature states as gateways into the flat band and explore the complex phase diagrams and non-equilibrium dynamics of bosons, fermions, and bose-fermi mixtures in the Kagome lattice.
We will develop a novel microscopy technique based on e.g. the sequential imaging of sublattices. This technique can be directly adapted to many other bichromatic superlattices, providing access to crucial local quantities including local densities, spin textures, density fluctuations, and spin correlations with single-site resolution.
Organisations
Publications
Nixon G
(2024)
Individually tunable tunnelling coefficients in optical lattices using local periodic driving
in Quantum Science and Technology
| Description | Cambridge Festival 2023 |
| Form Of Engagement Activity | A talk or presentation |
| Part Of Official Scheme? | No |
| Geographic Reach | Regional |
| Primary Audience | Public/other audiences |
| Results and Impact | Broadly 150 members of general public attended evening lecture and discussion on "The universe in an atom: atoms as quantum sensors for fundamental physics" as part of the Cambridge Festival. |
| Year(s) Of Engagement Activity | 2023 |
| URL | https://www.eventbrite.co.uk/e/the-universe-in-an-atom-atoms-as-quantum-sensors-for-fundamental-phys... |
| Description | Physics at Work |
| Form Of Engagement Activity | Participation in an activity, workshop or similar |
| Part Of Official Scheme? | No |
| Geographic Reach | National |
| Primary Audience | Schools |
| Results and Impact | Physics at Work aims to show 14-16yr olds the variety of careers to which study in Physics can lead and the range of practical problems that physics can be used to solve. This event is open to all schools and is free (there is a £10 per group refundable deposit). The exhibition is run in a similar way each year, based upon interaction between active scientific researchers and students. This will help to inform and spread the excitement of modern physics research to students who will soon be making career and examination choices, and is a vital component in encouraging the next generation of scientists. The Physics at Work Exhibition runs over three days, with two sessions on each day. This event is centred around approximately 25 exhibitors and is held at the Cavendish Laboratory in Cambridge. Some of the exhibitors are from research groups within the Cavendish Laboratory and the others are from industry, including companies such as Rolls-Royce Plc., Domino Printing Services and the AWE. Each half-day session typically has a capacity for about 450 students. The students are split into small groups of around 15 and are accompanied by a teacher as they follow a route defined by the organisers. Each small group, with its teacher, visits six exhibits over a period of about three hours, including a short break halfway through. Each exhibit usually consists of a short presentation, practical demonstrations, an opportunity for hands-on involvement and time for asking questions. A booklet of information is provided to support the exhibition, allowing teachers to bring ideas back into their lessons later in the year. This structured approach has developed over time and allows the students to engage thoroughly with the science on display. |
| Year(s) Of Engagement Activity | 2022,2023 |
| URL | https://outreach.phy.cam.ac.uk/programme/physicsatwork |