Carlo Barenghi

Institution Newcastle
Group None
Role None
About Carlo F Barenghi (Newcastle) is a Fellow of the American Physical Society (since 2009) and has a strong experimental track record working with classical fluids, 4He (helium I and helium II) and 3He at mK temperatures. As a theoretician, he has recently collaborated with experimentalists on flow visualization in quantum fluids: tracer particles in 4He and quasiparticles in 3He and atomic BECs.

Thomas Billam

Institution Newcastle
Group None
Role None
About Thomas Billam (Newcastle) is a cold atom theorist with expertise on stochastic simulations of ultracold Bose gases. Together with Ian Moss and Ruth Gregory, he has constructed simulations of 2D BEC systems to guide experimental probes of bubble nucleation.

Jonathan Braden

Institution CITA
Group None
Role None
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Sebastian Erne

Institution Technische Universität Wien
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Role None
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August Geelmuyden

Institution Nottingham
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Role None
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Ruth Gregory

Institution King's College London
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Role None
About Ruth Gregory (KCL) was awarded the IOP Maxwell Medal (2006) and a Royal Society Wolfson Merit Award (2011-2016). She also has a secondment with the Perimeter Institute (2010-20). RG has worked on classical and quantum theory of black holes in arbitrary dimensions, in particular perturbation theory and instabilities. The theoretical analysis of ringdown will draw on her experience with black hole perturbation theory and nonlinear systems.

Zoran Hadzibabic

Institution Cambridge
Group None
Role None
About Zoran Hadzibabic (Cambridge) is a Fellow of the American Physical Society (since 2017) and the recipient of the IOP-SFP Holweck Medal (2016). He is currently an EPSRC Established Career Fellow (2016-2021), an ERC Consolidator Grant holder (2016-2021), a Royal Society Wolfson Fellow (since 2019), and an ERC Advanced Grant holder (2021-2026). Zoran has an extensive track record on topics directly relevant for the development of a suitable FVD quantum simulator, which puts him in a unique position to tackle this ambitious goal. He has pioneered studies of homogeneous gases in ‘box traps’, which is essential for the present proposal.

Gregoire Ithier

Institution Royal Holloway
Group None
Role None
About Gregoire Ithier (RHUL) was awarded a Leverhulme Early Career Fellowship (2009-2011). Gregoire is an expert in the engineering of superconducting quantum circuits, and developed quantum limited detectors to measure and characterize superconducting quantum bits [32–34] and microwave cavities.

Alexander Jenkins

Institution UCL
Group None
Role None
About Alex Jenkins is a theorist with broad interests in cosmology, relativity, and gravitational physics. After obtaining his BA and MSci in Astrophysics at the University of Cambridge (2013–2017), he moved to King’s College London for a PhD in Theoretical Physics (2017–2021), before taking up his current role as a Postdoctoral Research Fellow at UCL. His research at King’s focused on the exciting new field of gravitational-wave astronomy, with an emphasis on using gravitational-wave observations to probe cosmology and fundamental physics, and this remains one of his core research interests. At UCL he is working on the False Vacuum Decay, using numerical simulations to better understand this fascinating process and its implications for the early Universe, as well as providing modelling support and theoretical predictions for the QSimFP programme.

Matthew Johnson

Institution Perimeter Institute
Group None
Role None
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Anthony Kent

Institution Nottingham
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About Anthony Kent (Nottingham) background is in low temperature physics. His Ph.D. was on 2D helium studied by NMR. He came to Nottingham nearly 38 years studying phonons in low dimensional structures, starting optical measurements at low temperatures. During the past 20 or so years he has been studying optomechanical effects at 100s of GHz to 1 THz including THz acoustic cavities and saser (sound amplification by stimulated emission of radiation). Relevant experimental techniques include ultra-fast pump-probe at low temperatures.

Friedrich Koenig

Institution St. Andrews
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Role None
About Friedrich Koenig (St. Andrews) is an expert on nonlinear fibre optics and quantum measurements. He experimentally demonstrated the first optical black hole analogues.

Jorma Louko

Institution Nottingham
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Role None
About Jorma Louko (Nottingham) is a theorist with long-standing expertise in curved spacetime quantum fields, including observers localised in space and time, accelerated motion, modified dispersions and entanglement.

Ian Moss

Institution Newcastle
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Role None
About Ian Moss (Newcastle) was an early pioneer in the study of the inflationary universe and cosmological bubble nucleation. Ian has expertise in stochastic methods and the time evolution of thermal early universe systems.

John Owers-Bradley

Institution Nottingham
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Role None
About John Owers-Bradley (Nottingham) is an experimentalist with a long-standing expertise in cryogenics and magnetic resonance. He has successfully carried out sub-kelvin experiments on the fundamental properties of liquid 3He (fermionic isotope of helium) and 3He-4He mixtures using dilution refrigeration.

Hiranya Peiris

Institution UCL
Group None
Role None
About Hiranya Peiris (UCL) is a Fellow of the American Physical Society (since 2016) and the recipient of the IOP Fred Hoyle Medal and Prize (2018), the Philip Leverhulme Prize (2009), an ERC Starting Grant (2013-2018), and an ERC Advanced Grant (2021-2026). Her contributions to our understanding of the early Universe have been recognised through shares of the Breakthrough Prize in Fundamental Physics (2018) and the Gruber Cosmology Prize (2012). Hiranya is an expert in cosmology, where her contribution to the field is distinguished by its combination of cosmological observations, fundamental theoretical physics, and advanced analysis methods.

Andrew Pontzen

Institution UCL
Group None
Role None
About Andrew Pontzen (UCL) holds a Royal Society University Research Fellowship (2013-2021) and an European Research Council Consolidator Grant (2019-2024). He received the Royal Astronomical Society Fowler Award (2016). Andrew is an expert on extracting physical insight from numerical simulations in cosmology, as well as comparing these simulations to observational constraints. His numerical codes have been cited in hundreds of publications across multiple fields of astronomy and cosmology.

Xavier Rojas

Institution Royal Holloway
Group None
Role None
About Xavier Rojas (RHUL) was awarded a Royal Society University Research Fellowship (2016-2021) to develop a programme on superfluid optomechanics. Xavier demonstrated prospects that nanofluidic confinement can offer to the study of quantum fluids, which includes the study of nanoscale acoustic Fabry-Pérot interferometers and superfluid nanomechanical resonators.

Joerg Schmiedmayer

Institution Technische Universität Wien
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Role None
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Theo Torres

Institution King's College London
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Role None
About Theo Torres (KCL) joined King’s after spending time as a postdoc at the University of Nottingham working on analogue models of compact gravitational objects. Prior to this, Theo was a member of the the Cosmology and Relativity Group at the University of Sheffield, where he worked on electromagnetic self-force in the Kerr metric. After o btaining a master’s degree in theoretical physics with a focus on black holes, cosmology, and quantum field theory, Theo followed the idea of logical positivism and investigated these subjects from an experimental point of view. As a PhD student at the University of Nottingham, he conducted experiments to mimic black hole physics in a wavetank, resulting in the observation of superradiance and light-ring mode oscillation around a vortex flow. Theo's aim is to use condensed matter systems in the form of analogue models of gravitational settings as a source of inspiration to deepen our understanding of classical and quantum fields in curved space-times.

Viktor Tsepelin

Institution Lancaster University
Group None
Role None
About Viktor Tsepelin (Lancaster) is a Reader, Head of Lancaster Low Temperature Physics, and formerly an EPSRC Advanced Research Fellow (2006-2011). His current interests are the creation, evolution and decay of quantum vortex tangles in superfluid 3He at zero temperature limit, probing turbulence in superfluids (3He and 4He) with micro-electromechanical (superconducting vibrating wires, quartz tuning forks) and nano-electromechanical devices (doubly-clamped beams). PhD (Aalto Univesity, 1996-2001) - optical detection of He4/He3 crystal growth.

William G. Unruh

Institution Vancouver
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Role None
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Silke Weinfurtner

Institution Nottingham
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Role None
About Silke Weinfurtner (Nottingham) holds a Royal Society University Research Fellowship (2013-2022), a recently awarded Leverhulme Trust Research Leaders Fellowship (2020-2025) and a visiting Fellowship at the Perimeter Institute, a leading centre in foundational theoretical physics (Canada). She was the first to successfully simulate Hawking radiation, superradiance and black hole ringdown in hydrodynamical systems. She developed several optical detection schemes, including high-sensitivity interferometers, for studying the dynamics of free fluid interfaces at room temperature and pressure. One led to a patent application (in review) for a High speed 3D air-fluid interface sensor with EnShape GmbH (Jena, Germany).

Patrik Švančara

Institution Nottingham
Group None
Role None
About Patrik Švančara is a low-temperature physicist. He is interested in the hydrodynamics of superfluids, especially He II, the superfluid phase of liquid helium-4. He obtained his PhD at the Charles University in Prague, Czech Republic, where he studied turbulence in He II experimentally, focusing on the flow visualisation and second sound attenuation techniques. He then joined the group of professor Weinfurtner at the University of Nottingham in late 2021 as a postdoctoral research fellow. His goal is to design and operate set-ups cooled down nearly to absolute zero temperature, in order to explore analog gravity systems in superfluid helium.