Astronomy and Astrophysics at Edinburgh
Lead Research Organisation:
University of Edinburgh
Department Name: Sch of Physics and Astronomy
Abstract
An astonishing feature of modern astrophysical research is that we have in principle a chain of explanation that stretches from processes on cosmological scales of billions of light years, down to the creation of stars, planets around the stars and life on the planets. In a sense, this process is almost a closed loop: the early Universe was once of sub-nuclear scale, so that quantum mechanical uncertainty is bound to seed fluctuations in density, which eventually collapse under gravity to make astronomical structures. This is the same physics of the very small that governs the formation of the atoms out of which we are all made.
But unanswered questions abound at all stages of this process. Our theories of the early Universe and explanations of its current expansion rest on the concept that empty space can have weight: the so-called "dark energy". We need to study its properties and understand its origin. In so doing, we often assume that Einstein's relativity describes gravity correctly on all scales, but can we test this? If the standard theory is correct, dark matter is required, and we are driven to follow the processes by which it clumps, and by which the gas within these clumps evolves and eventually collapses to form stars and massive black holes. New large telescopes on the ground, together with observing platforms in space such as the Hubble and Spitzer Space Telescopes, allow us to see this process in action and compare the observations with detailed computer simulations. Nearer to home, we can dissect galaxies such as our own Milky Way into individual stars, for the most detail view of how they were assembled. And finally we can study how planets arise around these stars, both from new instruments that can detect the presence of "exo-planets" and by computer simulations of how they may be created within the discs of gas and dust left over from star formation. Ultimately, one can refine the search to planets potentially capable of supporting life, and ask how life might arise within these early planetary systems.
Research in astronomy at Edinburgh attacks all of these connected questions. Progress is rapid, driven by technological breakthroughs in observational facilities and computing power, and our understanding is evolving rapidly. Major progress, even if not final answers, can be expected within a few years. This is an exciting time for our understanding of the full history and structure of our Universe and our place within it.
But unanswered questions abound at all stages of this process. Our theories of the early Universe and explanations of its current expansion rest on the concept that empty space can have weight: the so-called "dark energy". We need to study its properties and understand its origin. In so doing, we often assume that Einstein's relativity describes gravity correctly on all scales, but can we test this? If the standard theory is correct, dark matter is required, and we are driven to follow the processes by which it clumps, and by which the gas within these clumps evolves and eventually collapses to form stars and massive black holes. New large telescopes on the ground, together with observing platforms in space such as the Hubble and Spitzer Space Telescopes, allow us to see this process in action and compare the observations with detailed computer simulations. Nearer to home, we can dissect galaxies such as our own Milky Way into individual stars, for the most detail view of how they were assembled. And finally we can study how planets arise around these stars, both from new instruments that can detect the presence of "exo-planets" and by computer simulations of how they may be created within the discs of gas and dust left over from star formation. Ultimately, one can refine the search to planets potentially capable of supporting life, and ask how life might arise within these early planetary systems.
Research in astronomy at Edinburgh attacks all of these connected questions. Progress is rapid, driven by technological breakthroughs in observational facilities and computing power, and our understanding is evolving rapidly. Major progress, even if not final answers, can be expected within a few years. This is an exciting time for our understanding of the full history and structure of our Universe and our place within it.
Planned Impact
Details of our Pathways to Impact are provided in the separate 2-page attachment. In brief, we carry out an extensive programme of public engagement and knowledge transfer, implemented in collaboration with the UK ATC, and our own Wide Field Astronomy Unit. Much stems directly from the research activities that are the subject of this application.
Our work in knowledge transfer and exploitation is exemplified by the case study of MOPED and the resulting spin-out company Blackford Analysis. MOPED (Massively Optimised Parameter Estimation and Data compression) is a unique process that employs a massive data compression step, enabling very rapid analysis without compromising accuracy. The MOPED algorithm was designed at the IfA by Prof. Alan Heavens and Dr Benjamin Panter to solve problems in cosmology, but has since been successfully applied to a number of medical applications, the most obvious being the ability of MOPED to speed up 3-D MRI image reconstruction to the point where it would no longer be necessary to immobilize children with a general anaesthetic for MRI scans. A spin-out company, Blackford Analysis Ltd, started trading in August 2010, has received significant investment, and now employs 9 people in the UK (sited at ROE, allowing continued academic interaction), developing very rapid image alignment tools for the medical imaging market. There has been direct user-engagement in the medical imaging field, through researchers, clinicians and industry luminaries, as well as MRI scanner manufacturers and PACS vendors. Recently Blackford Analysis has expanded its work into applications in other areas, securing a two-year consultancy contract with Rolls Royce worth £65,000, and identifying further commercial applications of MOPED in security imaging and in the oil and gas industries.
The case of Blackford Analysis exemplifies how novel techniques developed for astronomical research can be effectively applied to have a major impact in wider society. We plan to replicate this success through the University of Edinburgh's involvement in the new Higgs Centre for Innovation (to be completed at ROE by spring 2016). The Higgs Centre aims to ensure that further technologies, algorithms, and techniques from any of ATC instrumentation, IfA research, or WFAU data handling are effectively transferred to industry through close interactions between our academics/PDRAs and the public and private sectors (with the potential to create of further spinout companies from the STFC incubator). We are also taking the Big Data initiative, and interaction with the commercial sector, very seriously. (i) We have a long tradition of designing and developing new data centre facilities in active collaboration with local companies, who then use their experience with other commercial customers. (ii) As part of leading a proposal for UK participation in LSST, we are working with STFC to identify BIS infrastructure funding to work with industry. (iii) We are currently advertising for a new position specialising in novel data handling techniques.
We are also involved in a particularly vigorous programme of Public Outreach, Engagement & Education, under the auspices of the ROE Visitor Centre (www.roe.ac.uk/vc; jointly funded by the University and STFC) that draws directly on the cutting-edge research supported by our STFC Consolidated grant. Within the UK university sector, this programme is unusual in its breadth and scope, extending well beyond the normal expectation of public talks, press releases and media interviews. This is in part because university staff, PDRAs and students have the opportunity to work collaboratively with Visitor Centre Staff, but is also due to the unique advantages afforded by the ROE site, with its unusual combination of front-line astronomical research, world-leadiing instrument development, and astronomical history/heritage. Further details of activities and impact are provided in the Pathways to Impact attachment.
Our work in knowledge transfer and exploitation is exemplified by the case study of MOPED and the resulting spin-out company Blackford Analysis. MOPED (Massively Optimised Parameter Estimation and Data compression) is a unique process that employs a massive data compression step, enabling very rapid analysis without compromising accuracy. The MOPED algorithm was designed at the IfA by Prof. Alan Heavens and Dr Benjamin Panter to solve problems in cosmology, but has since been successfully applied to a number of medical applications, the most obvious being the ability of MOPED to speed up 3-D MRI image reconstruction to the point where it would no longer be necessary to immobilize children with a general anaesthetic for MRI scans. A spin-out company, Blackford Analysis Ltd, started trading in August 2010, has received significant investment, and now employs 9 people in the UK (sited at ROE, allowing continued academic interaction), developing very rapid image alignment tools for the medical imaging market. There has been direct user-engagement in the medical imaging field, through researchers, clinicians and industry luminaries, as well as MRI scanner manufacturers and PACS vendors. Recently Blackford Analysis has expanded its work into applications in other areas, securing a two-year consultancy contract with Rolls Royce worth £65,000, and identifying further commercial applications of MOPED in security imaging and in the oil and gas industries.
The case of Blackford Analysis exemplifies how novel techniques developed for astronomical research can be effectively applied to have a major impact in wider society. We plan to replicate this success through the University of Edinburgh's involvement in the new Higgs Centre for Innovation (to be completed at ROE by spring 2016). The Higgs Centre aims to ensure that further technologies, algorithms, and techniques from any of ATC instrumentation, IfA research, or WFAU data handling are effectively transferred to industry through close interactions between our academics/PDRAs and the public and private sectors (with the potential to create of further spinout companies from the STFC incubator). We are also taking the Big Data initiative, and interaction with the commercial sector, very seriously. (i) We have a long tradition of designing and developing new data centre facilities in active collaboration with local companies, who then use their experience with other commercial customers. (ii) As part of leading a proposal for UK participation in LSST, we are working with STFC to identify BIS infrastructure funding to work with industry. (iii) We are currently advertising for a new position specialising in novel data handling techniques.
We are also involved in a particularly vigorous programme of Public Outreach, Engagement & Education, under the auspices of the ROE Visitor Centre (www.roe.ac.uk/vc; jointly funded by the University and STFC) that draws directly on the cutting-edge research supported by our STFC Consolidated grant. Within the UK university sector, this programme is unusual in its breadth and scope, extending well beyond the normal expectation of public talks, press releases and media interviews. This is in part because university staff, PDRAs and students have the opportunity to work collaboratively with Visitor Centre Staff, but is also due to the unique advantages afforded by the ROE site, with its unusual combination of front-line astronomical research, world-leadiing instrument development, and astronomical history/heritage. Further details of activities and impact are provided in the Pathways to Impact attachment.
Organisations
Publications
Habouzit M
(2021)
Supermassive black holes in cosmological simulations I: M BH - M ? relation and black hole mass function
in Monthly Notices of the Royal Astronomical Society
Haines C
(2017)
The VIMOS Public Extragalactic Redshift Survey (VIPERS) Downsizing of the blue cloud and the influence of galaxy size on mass quenching over the last eight billion years?
in Astronomy & Astrophysics
Hale C
(2019)
LOFAR observations of the XMM-LSS field
in Astronomy & Astrophysics
Hall A
(2019)
A Bayesian method for combining theoretical and simulated covariance matrices for large-scale structure surveys
in Monthly Notices of the Royal Astronomical Society
Hall A
(2020)
Towards determining the neutrino mass hierarchy: weak lensing and galaxy clustering forecasts with baryons and intrinsic alignments
in Monthly Notices of the Royal Astronomical Society
Hall C
(2017)
Identifying and analysing protostellar disc fragments in smoothed particle hydrodynamics simulations
in Monthly Notices of the Royal Astronomical Society
Hall C
(2019)
The Temporal Requirements of Directly Observing Self-gravitating Spiral Waves in Protoplanetary Disks with ALMA
in The Astrophysical Journal
Hall C
(2018)
Is the spiral morphology of the Elias 2-27 circumstellar disc due to gravitational instability?
in Monthly Notices of the Royal Astronomical Society
Hall C
(2016)
Directly observing continuum emission from self-gravitating spiral waves
in Monthly Notices of the Royal Astronomical Society
Hamadouche M
(2022)
A combined VANDELS and LEGA-C study: the evolution of quiescent galaxy size, stellar mass, and age from z = 0.6 to z = 1.3
in Monthly Notices of the Royal Astronomical Society
Hamaus N
(2022)
Euclid : Forecasts from redshift-space distortions and the Alcock-Paczynski test with cosmic voids
in Astronomy & Astrophysics
Hambly Nigel
(2017)
Get ready for Gaia: cool white dwarfs in common proper motion with Tycho stars
in ArXiv e-prints
Han J
(2015)
Galaxy And Mass Assembly (GAMA): the halo mass of galaxy groups from maximum-likelihood weak lensing
in Monthly Notices of the Royal Astronomical Society
Hand N
(2015)
First measurement of the cross-correlation of CMB lensing and galaxy lensing
in Physical Review D
Hang Q
(2021)
Galaxy clustering in the DESI Legacy Survey and its imprint on the CMB
in Monthly Notices of the Royal Astronomical Society
Hardcastle M
(2019)
Radio-loud AGN in the first LoTSS data release The lifetimes and environmental impact of jet-driven sources
in Astronomy & Astrophysics
Hardcastle M
(2016)
LOFAR/H-ATLAS: a deep low-frequency survey of the Herschel -ATLAS North Galactic Pole field
in Monthly Notices of the Royal Astronomical Society
Harnois-Déraps J
(2016)
CFHTLenS and RCSLenS cross-correlation with Planck lensing detected in fourier and configuration space
in Monthly Notices of the Royal Astronomical Society
Harnois-Déraps J
(2017)
KiDS-450: tomographic cross-correlation of galaxy shear with Planck lensing
in Monthly Notices of the Royal Astronomical Society
Harnois-Déraps J
(2015)
Baryons, neutrinos, feedback and weak gravitational lensing
in Monthly Notices of the Royal Astronomical Society
Harrison C
(2017)
The KMOS Redshift One Spectroscopic Survey (KROSS): rotational velocities and angular momentum of z ˜ 0.9 galaxies?
in Monthly Notices of the Royal Astronomical Society
Harrison C. M.
(2017)
The KMOS Redshift One Spectroscopic Survey (KROSS): rotational velocities and angular momentum of z~0.9 galaxies
in ArXiv e-prints
Harrison Christopher M.
(2015)
IGMtransmission: Transmission curve computation
in Astrophysics Source Code Library
Harwood JJ
(2016)
FR II radio galaxies at low frequencies - I. Morphology, magnetic field strength and energetics.
in Monthly notices of the Royal Astronomical Society
Hassan S
(2020)
Testing galaxy formation simulations with damped Lyman-a abundance and metallicity evolution
in Monthly Notices of the Royal Astronomical Society
Hathi N
(2016)
The VIMOS Ultra Deep Survey: Ly a emission and stellar populations of star-forming galaxies at 2 < z < 2.5
in Astronomy & Astrophysics
Hatsukade B
(2018)
ALMA twenty-six arcmin2 survey of GOODS-S at one millimeter (ASAGAO): Source catalog and number counts
in Publications of the Astronomical Society of Japan
Hattab M
(2019)
A case study of hurdle and generalized additive models in astronomy: the escape of ionizing radiation
in Monthly Notices of the Royal Astronomical Society
Hawken A
(2017)
The VIMOS Public Extragalactic Redshift Survey Measuring the growth rate of structure around cosmic voids?
in Astronomy & Astrophysics
Hawken A. J.
(2016)
The VIMOS Public Extragalactic Redshift Survey: Measuring the growth rate of structure around cosmic voids
in ArXiv e-prints
Haworth T
(2016)
Grand Challenges in Protoplanetary Disc Modelling
in Publications of the Astronomical Society of Australia
Hayatsu N
(2017)
ALMA deep field in SSA22: Blindly detected CO emitters and [C ii ] emitter candidates
in Publications of the Astronomical Society of Japan
Haywood R
(2018)
An Accurate Mass Determination for Kepler-1655b, a Moderately Irradiated World with a Significant Volatile Envelope
in The Astronomical Journal
Heald G
(2015)
The LOFAR Multifrequency Snapshot Sky Survey (MSSS) I. Survey description and first results
in Astronomy & Astrophysics
Heesen V
(2019)
Calibrating the relation of low-frequency radio continuum to star formation rate at 1 kpc scale with LOFAR
in Astronomy & Astrophysics
Heesen V
(2018)
LOFAR reveals the giant: a low-frequency radio continuum study of the outflow in the nearby FR I radio galaxy 3C 31
in Monthly Notices of the Royal Astronomical Society
Henry Todd J.
(2016)
The Census of Objects within 10 Parsecs
in American Astronomical Society Meeting Abstracts #227
Herrera Ruiz N
(2017)
The faint radio sky: VLBA observations of the COSMOS field
in Astronomy & Astrophysics
Herrera Ruiz N
(2018)
VLBA+GBT observations of the COSMOS field and radio source counts at 1.4 GHz
in Astronomy & Astrophysics
Heymans C
(2015)
Sky Survey Casts Light on the Dark Universe
in Physics
Heywood I
(2017)
ATCA detections of massive molecular gas reservoirs in dusty, high- z radio galaxies
in Monthly Notices of the Royal Astronomical Society
Hildebrandt H
(2020)
KiDS+VIKING-450: Cosmic shear tomography with optical and infrared data
in Astronomy & Astrophysics
Hildebrandt H
(2016)
RCSLenS: The Red Cluster Sequence Lensing Survey
in Monthly Notices of the Royal Astronomical Society
Hildebrandt H
(2017)
KiDS-450: cosmological parameter constraints from tomographic weak gravitational lensing
in Monthly Notices of the Royal Astronomical Society
Hill R
(2018)
High-resolution SMA imaging of bright submillimetre sources from the SCUBA-2 Cosmology Legacy Survey
in Monthly Notices of the Royal Astronomical Society
Hirst P
(2020)
Long-term NIR variability in the UKIDSS Ultra Deep Survey: a new probe of AGN activity at high redshift
in Monthly Notices of the Royal Astronomical Society
Hoang D
(2018)
Radio observations of the double-relic galaxy cluster Abell 1240
in Monthly Notices of the Royal Astronomical Society