Gerry Williger
Title: The GALEX Extragalactic Spectral Database
We present results from a project to categorize and collect complementary multiband data for approximately 11,000 extragalactic sources in 211 GALEX spectroscopic fields which overlap the Sloan Digital Sky Survey (SDSS). The project yields a useful searchable database for the scientific exploitation of GALEX UV spectra (R~100-200) of extragalactic sources. For all extragalactic sources (known or classified by us) with GALEX spectra, we have assembled complementary images and photometry in FUV+NUV from GALEX, in ugriz from the SDSS, in JHK from the Two Micron All Sky Survey (2MASS) and in W1-W4 from the Wide-field Infrared Survey Explorer (WISE), and created spectral energy distributions (SEDs). We have also logged SIMBAD and SDSS object classification, redshift and angular size information, and provide some indication of spectral data quality, since it largely varies across the sample and even across the wavelength range of individual spectra, owing to the grism observing strategy (Bianchi et al. 2018, Astrophys. Space Sci., 363, 56).
The UV spectral database consists of 1820 quasars, 2274 star-forming galaxies, 6327 quiescent spirals and 386 ellipticals. The mean redshifts for quasars, star-forming galaxies, quiescent spirals and ellipticals are 0.99, 0.07, 0.35 and 0.05 respectively. We will show representative spectra, SEDs and color-magnitude diagrams. The database (Pritchard et al., in preparation) will be made publicly available from the Mikulski Archive for Space Telescopes (STScI’s MAST) as a High-Level Science Product (HLSP), as well as from Vizier.
Yuri Fujii
Title: Formation of satellite systems around Jupiter and Saturn
Satellite systems around Jupiter and Saturn have different characteristics. The Saturnian system is dominated by a giant moon, Titan, which holds over 95% of the total mass of Saturnian moons. On the other hand, the Jovian system has four large moons in a compact orbital area, and inner three, Io, Europa and Ganymede, are known to be in resonant orbits. Previous studies have shown that the specific resonance can be obtained if there is some structure, such as inner cavity, in the satellite forming circum-Jovian disk. However, the mechanism making such a structure is poorly understood. We estimated the strengths of planetary magnetic fields for Jupiter and Saturn that are generated by dynamo process by calculating the thermal evolution of them. Saturn’s magnetic field is too weak to open a gap between Saturn and the circum-Saturnian disk, thus the moons in the inner orbits fall onto Saturn due to inward orbital migration. Our models show there are cases where a moon in an outer orbit evacuated into “safety zone” and survived till the disk dispersal. In the case of Jupiter, its strong enough magnetic fields generate magnetosphere around it, and moons migrating toward Jupiter stop at the outer edge of the magnetosphere during a certain period of the disk evolution. Our results suggest that Io, Europa and Ganymede should be captured into resonance while there exists a cavity around Jupiter and evolve as a system after the magnetosphere has vanished. We believe our scenario can explain the difference of Jovian and Saturnian moon systems.
Jerzy Kubacki
Title: Improving the mechanism of resistive switching in SrTiO3 based on the study on electronic structure of iron-doped thin films
Strontium titanate (STO) is promising for electronic applications, especially in the thin film form. In general, it has dielectric properties with the energy gap of 3.6 eV, however it was found that its electrical properties can be tuned by iron doping. The thin films with various nominal content of Fe admixture were grown by pulsed laser deposition method. The crystal structure and quality of surface of obtained samples were tested by low-energy electron diffraction and atomic force microscopy. Synchrotron radiation was used to analyse the occupied and un-occupied electronic states. A relation was found between iron doping and a modification of sub-surface region. Electroforming process performed in situ revealed, in addition to general suggested ionic description, an electron contribution to the resistive switching process in the STO perovskite.
Sean Giblin
Title: Towards measurement of coherence in a correlated system using Qubits
The technology that enables our lives is underpinned by our understanding of condensed matter systems, which describes the behaviour of 1023 electrons. The classical limit of such systems is predicated upon fundamental quantum states and consequently, significant effort is spent exploring the quantum properties to enhance our understanding, look for emergent quantum behaviour and deliver future industrial output. However, a significant weakness exists in our ability to probe directly these fundamental quantum fluctuations and coherence in bulk systems. To overcome this weakness, we propose to couple magnetic properties of a bulk condensed matter systems to a qubit via a cavity. We will be able to prepare coherent and entangled states in the qubit and measure directly the decoherence of the magnetic state in question. This submission explores the concepts behind quantum transduction of a magnetic system and provides a basic methodology.
Richard McCracken
Title: Hunting for exoplanets with a fine-toothed comb
Astrocombs are broadband, high-repetition rate optical frequency combs that are used for the calibration of astronomical spectrographs. Their precision and accuracy make astrocombs a critical technology that will enable ground-breaking observations in the fields of exoplanets, cosmology, and fundamental physics. The conflicting requirements of resolvable comb line spacing (usually >10 GHz), broadband spectral coverage (from below 400 to above 2400 nm) and compatibility with low-maintenance operation represents a significant technical challenge. In this talk I will present an overview of these instruments and will highlight our work on developing broadband astrocombs for the Southern African Large Telescope (SALT) and the upcoming Extremely Large Telescope (ELT).
Ricardo Schiavon
Title: On the origin of all Galactic globular clusters — the living and the dead
Globular clusters (GCs) are among the most enigmatic systems ever studied in Astrophysics. After decades of observational and theoretical work, there still are important gaps in our understanding of their nature. I use data from APOGEE, Gaia, and the literature to investigate the origin and fate of Galactic GCs. I will show evidence that the Milky Way has destroyed the vast majority of its original GC system, and that all galaxies have done pretty much the same, in qualitative agreement with theoretical predictions. I will present a new method to distinguish accreted stellar populations from those formed in situ, based solely on their chemical compositions. On the basis of this new classification scheme, I will argue that most of the Milky Way surviving GCs have an accreted origin, whereas those that were destroyed were predominantly formed in situ, again in agreement with theoretical predictions.
Stephen Lynch
Title: Rydberg Excitons: Artificial Atoms in Crystals
Bohr’s theory of the hydrogen atom published in 1913 provided an elegant derivation of Rydberg’s phenomenological formula for spectral emission lines. This was one of the defining events that kick-started the development of quantum mechanics. Excitons are bound electron-hole pairs, commonly found in semiconductor crystals. They behave very much like Bohr atom analogues, and they can be described by similar physics. Cuprous oxide (Cu2O) is one of the oldest known semiconductor materials, and it has long been known that cuprous oxide crystals exhibit an extraordinary exciton spectrum, which is markedly different for other semiconductors. Recently, Rydberg excitons with principal quantum numbers up to n = 30 and Bohr radii nearing 1 micron have been observed in this material. The existence of these gigantic quantum objects unlocks the potential for a whole range of disruptive quantum technologies, that were previously unfeasible. This introductory talk, pitched at a level accessible to an enthusiastic physics undergraduate student, will explore some of the recent discoveries that we have made in this fast-developing research field.
Andrew Blain
Title: The most extreme objects and the interstellar medium
Both the very top end of the historical galaxy luminosity function, as highlighted over the whole sky via follow-up of the WISE survey, and gamma-ray bursts provide some of the most unusual and extreme conditions regions in the universe. Investigating their nature should provide insight into the conditions for more regular regions of the interstellar medium, and the formation of stars in regions that are more typical of the Universe as a whole.
Dimitri Gadotti
Title: Formation and evolution of bulges and bars in disc galaxies
The central kpc of disc galaxies is a busy place, where many structures overlap and evolve at a relatively fast pace. These central structures, such as bulges and bars, hold, however, key information on the formation and evolution of their host galaxies. And as most galaxies show non-axisymmetric structures such as bars, understanding their formation and impact on galaxy evolution is crucial. Fortunately, recently developed observational facilities have helped enormously in clarifying the sometimes confusing picture of the central kpc. In this talk, I will first review how this picture has evolved to include nuclear discs and box/peanuts alongside classical bulges as the main central components in disc galaxies. Next, I will discuss recent results from the TIMER team with MUSE, including unprecedented estimates of bar ages and how they compare with a complementary approach using JWST. The corresponding implications on our understanding of galaxy formation and evolution, including bar-driven processes and the hierarchical growth of galaxies, will be summarised.
Joseph Barker
Title: Metadynamics calculations of the effect of thermal spin fluctuations on skyrmion stability
The stability of magnetic skyrmions has been investigated in the past, but mostly in the absence of thermal fluctuations. However, thermal spin fluctuations modify the magnetic properties (exchange stiffness, Dzyaloshinskii-Moriya interaction (DMI) and anisotropy) that define skyrmion stability. Thermal magnons also excite internal skrymion dynamics, deforming the skyrmion shape. Entropy has also been shown to modify skyrmion lifetimes in experiments, but is absent or approximated in previous studies. Here we use metadynamics to calculate the free energy surface of a magnetic thin film in terms of the topological charge and magnetization. We identify the free energy minima corresponding to different spin textures and the lowest energy paths between the ferromagnetic and single skyrmion states. We show that at low temperatures the lowest free energy barrier is a skyrmion collapse process. However, this energy barrier increases with temperature. An alternative path, where a singularity forms on the skrymion edge, has a larger free energy barrier at low temperatures but decreases with increasing temperature and eventually becomes the lowest energy barrier. (https://arxiv.org/abs/2310.03169)
Clare Dobbs
Title: The formation of clusters and associations in spiral galaxies
I will present simulations of cluster formation in regions taken from galaxy scale simulations, including photoionization and supernovae feedback. We simulate regions with different densities, and from different galactic environments. In all our simulations, clusters undergo mergers and splits during their formation. More massive clusters form in regions of spiral arms with stronger converging flows, and in bars and inner spiral arm regions. In inter-arm or outer galaxy regions, we tend to see looser groups more characteristic of associations. In all simulations, the most massive clusters are formed by mergers. Feedback has a greater impact on cluster formation at lower densities, where star formation occurs over a longer timescale. In our lowest density case, the resulting clusters (in terms of number, mass) are very different with and without feedback, and one of our simulations forms an association which has a similar size, mass and morphology to the Orion OB1 association. We also show that photoionizing feedback is necessary to produce clusters with the observed cluster mass relation. Initial results with magnetic fields show that magnetic fields can have a strong impact on cluster formation, depending on field strength. We also compare our simulations with the observed Crutcher relation. Lastly, we place our simulated clusters into the GAIA catalogue and try to re-identify them. We find that the spatial properties of clusters are surprisingly robust even at relatively large distances and when relatively few members of the original cluster are observed. However dynamical measurements tend to be much less reliable.
James Mullaney
Title: The Climate of Black Hole Growth
Over the past 30 years, it has become increasingly clear that all massive galaxies contain, at their centers, a supermassive black hole. Over the same period of time, many astronomers have come to the conclusion that the energy released when these black holes accrete matter plays a key role in shaping their host galaxies. As such, understanding what causes supermassive black hole accretion is thought to be fundamental to our understanding of galaxy formation and evolution. Unfortunately, while accretion events are long lasting compared to human timescales, they are extremely short-lived on galactic timescales, making the identification of causal relationships between host and accretion very challenging. In this seminar, I will talk about how a statistical approach can help to uncover the causes of supermassive black hole accretion.
Joe Lyman
Title: Transient astrophysics with the Gravitational wave Optical Transient Observer (GOTO)
Beginning in 2017, with the discovery of GW170817, we moved to the era of gravitational-wave multi-messenger astronomy. This single source, caused by the merging of two neutron stars, was detected both as a gravitational-wave source by the LIGO/Virgo interferometers, and as a multi-wavelength electromagnetic astrophysical transient. In this talk I will briefly recap ground-breaking results from GW170817, and
the scientific potential from observing more multi-messenger events, as motivation for the GOTO project. I will present our telescope array GOTO, designed to search the skies for fast-evolving transients. I’ll show our developments for optimising recovery of multi-messenger events, and introduce some intriguing transient discoveries from a pilot classification programme on La Palma – GOTO-FAST.
Zoë Henderson
Title: Glass Surfaces on the Nanoscale: Surface Analysis at NSG Pilkington
As a member of the NSG Group, Pilkington United Kingdom Limited is one of the leading glass suppliers in the UK, producing glass for the architectural and automotive industries as well as producing glass for creative technology applications. Within Research and Development (R&D), the Surface Analysis team provide analytical expertise and technical support for the company in both R&D projects and commercial products. This talk will aim to take the audience through the glass manufacture process, production methods, and look at how probing nanoscale phenomena with surface analysis techniques supports R&D and the wider business.
Steve Longmore
Title: Early results from the ALMA Large Program, ACES (“ALMA Central Molecular Zone Exploration Survey”)
The extreme environment and relative proximity to Earth make the centre of our Galaxy a unique astrophysical laboratory. The gas properties, radiation field, cosmic ray ionisation rate, etc., are more similar to those in the centre of other galaxies, starbursts and high-z galaxies than the Solar neighbourhood. It is the only such extreme environment in which it is possible to resolve down to size scales of individual forming stars and link the small-scale physics of star formation and feedback with the galactic-scale
processes that together drive the evolution of galaxies. In this talk I will present early results from the ALMA Large Program, ACES (“ALMA Central Molecular Zone Exploration Survey”), which uses ALMA’s combination of sensitivity, resolution, and image fidelity to derive the gas properties from cloud scales down to the size scale of individual forming stars across the inner 100pc of the Galaxy. I will then present initial results from a JWST program to uncover and derive the properties of the previously hidden Young Stellar Object population in Galactic Centre molecular clouds. Finally, I will describe a proposed open Treasury Program of the inner 100pc of the Galaxy with JWST to measure the spatially resolved star formation history, identify recently formed massive stars and candidate Young Stellar Objects down to ∼1 Msun and constrain the 3D structure of the molecular gas, the Nuclear Stellar Disk, and the Nuclear Star Cluster.
Ziri Younsi
Title: Studying Black Holes on Event Horizon-Scales
Black holes possess gravitational fields so strong that not even light can escape their event horizons. For more than a century, black holes were predicted to exist, but direct observational confirmation remained elusive. In April 2019 the Event Horizon Telescope Collaboration (EHTC) published the first ever “image” of a supermassive black hole in the M87 galaxy. In May 2022 the EHTC subsequently published an image of the Galactic Centre supermassive black hole.
In this talk I will present an overview of black hole physics and radiation processes occurring near event horizons, together with an introduction to the EHT. I will discuss how these and other complimentary observations may provide important insights into the properties of black holes and the physical processes occurring in their surrounding environments. Finally, I will touch upon some of the exciting future prospects for these novel new studies of black holes.
Alex Hall
Title: Testing the concordance cosmological model with Euclid
The Lambda-CDM model of cosmology has proven an immensely successful description of our Universe, accounting for a wide range of astrophysical phenomena. At the same time, the model is deeply unsatisfying because it requires Dark Energy and Dark Matter, neither of which are understood at a fundamental level. Dark Energy measurements in particular are vastly at odds with vacuum energy predictions, potentially indicating the need for new fundamental physics. These questions have motivated Euclid, the European Space Agency’s flagship Dark Energy mission. Euclid was launched in July 2023 and is shortly due to start a galaxy survey covering almost the entire accessible extragalactic sky. In the talk, I will describe the Euclid project, its core cosmology probes Weak Lensing and Galaxy Clustering, and discuss what our understanding of the large-scale Universe might look like at the end of its nominal 6-year mission.
Pavel Kroupa
Title: The first star clusters and the formation of super-massive black holes therein
The most massive galaxies started to form earliest and on the shortest time. At their centres the formation began with the first ultra-massive star clusters, weighing 10^7-10^10 Msun. This mass depends on the mass of the post-Big-Bang gas cloud that later (on the downsizing time-scale) evolves to the early-type galaxy or bulge. I will discuss the physical and dynamical processes in these clusters, which, due to the low metallicity, form with top-heavy stellar initial mass functions, and how the formation of the surrounding spheroidal galaxy dictates their evolution. For spheroid masses larger than a few 10^9 Msun, the central cluster implodes to a SMBH seed which can continue to grow as long as the spheroid keeps forming on the downsizing time-scale. The result of these events is the present-day observed strong correlation between the SMBH mass and its hosting spheroid. This theory also explains the existence of quasars at redshifts larger than 9