Project acronym AARTFAAC
Project Amsterdam-ASTRON Radio Transient Facility And Analysis Centre: Probing the Extremes of Astrophysics
Researcher (PI) Ralph Antoine Marie Joseph Wijers
Host Institution (HI) UNIVERSITEIT VAN AMSTERDAM
Call Details Advanced Grant (AdG), PE9, ERC-2009-AdG
Summary Some of the most extreme tests of physical law come from its manifestations in the behaviour of black holes and neutron stars, and as such these objects should be used as fundamental physics labs. Due to advances in both theoretical work and observational techniques, I have a major opportunity now to significantly push this agenda forward and get better answers to questions like: How are black holes born? How can energy be extracted from black holes? What is the origin of magnetic fields and cosmic rays in jets and shocks? Is their primary energy stream hadronic or magnetic? I propose to do this by exploiting the advent of wide-field radio astronomy: extreme objects are very rare and usually transient, so not only must one survey large areas of sky, but also must one do this often. I propose to form and shape a group that will use the LOFAR wide-field radio telescope to hunt for these extreme transients and systematically collect enough well-documented examples of the behaviour of each type of transient. Furthermore, I propose to expand LOFAR with a true 24/7 all-sky monitor to catch and study even the rarest of events. Next, I will use my experience in gamma-ray burst followup to conduct a vigorous multi-wavelength programme of study of these objects, to constrain their physics from as many angles as possible. This will eventually include results from multi-messenger astrophysics, in which we use neutrinos, gravity waves, and other non-electromagnetic messengers as extra diagnostics of the physics of these sources. Finally, I will build on my experience in modelling accretion phenomena and relativistic explosions to develop a theoretical framework for these phenomena and constrain the resulting models with the rich data sets we obtain.
Summary
Some of the most extreme tests of physical law come from its manifestations in the behaviour of black holes and neutron stars, and as such these objects should be used as fundamental physics labs. Due to advances in both theoretical work and observational techniques, I have a major opportunity now to significantly push this agenda forward and get better answers to questions like: How are black holes born? How can energy be extracted from black holes? What is the origin of magnetic fields and cosmic rays in jets and shocks? Is their primary energy stream hadronic or magnetic? I propose to do this by exploiting the advent of wide-field radio astronomy: extreme objects are very rare and usually transient, so not only must one survey large areas of sky, but also must one do this often. I propose to form and shape a group that will use the LOFAR wide-field radio telescope to hunt for these extreme transients and systematically collect enough well-documented examples of the behaviour of each type of transient. Furthermore, I propose to expand LOFAR with a true 24/7 all-sky monitor to catch and study even the rarest of events. Next, I will use my experience in gamma-ray burst followup to conduct a vigorous multi-wavelength programme of study of these objects, to constrain their physics from as many angles as possible. This will eventually include results from multi-messenger astrophysics, in which we use neutrinos, gravity waves, and other non-electromagnetic messengers as extra diagnostics of the physics of these sources. Finally, I will build on my experience in modelling accretion phenomena and relativistic explosions to develop a theoretical framework for these phenomena and constrain the resulting models with the rich data sets we obtain.
Max ERC Funding
3 499 128 €
Duration
Start date: 2010-10-01, End date: 2016-09-30
Project acronym CHOMP
Project A Complete History of Massive Proto-Galaxies
Researcher (PI) James Dunlop
Host Institution (HI) THE UNIVERSITY OF EDINBURGH
Call Details Advanced Grant (AdG), PE9, ERC-2009-AdG
Summary A key question in modern science is to explain how the present-day universe of galaxies evolved from the initial conditions measured in the micro-wave background at recombination. Over the next 5 years I propose to undertake a major program of research to address this issue, by discovering and studying directly the progenitors of today's massive galaxies during the first ~2 billion years of cosmic history, and hence performing critical tests of current theories of galaxy formation. It is now clear that to sample representative volumes of the high-redshift universe requires ultra-deep near-infrared, mid-infrared and sub-mm surveys covering over ~1 sq. degree. Until now this has not been possible, but this field is about to be revolutionized by the introduction of a new generation of wide-field facilities in the next year. Specifically, 2009 will see the commissioning of the new near-infrared VISTA survey telescope in Chile, the new SCUBA2 sub-mm camera on the JCMT in Hawaii, the far-infrared Herschel Space Observatory, and the near-infrared camera WFC3 in the Hubble Space Telescope. Now, through my leadership of the deepest of the new generation of wide-field infrared and submm surveys to be undertaken with these revolutionary new facilities, I am unusually well-placed to take an integrated approach to the study of galaxy formation/evolution reaching back, for the first time, into the epoch of re-ionisation, at redshifts z ~ 7 - 10. Through this application I request the level of support required to exploit these new and unique data in what is one of the most important and topical areas at the forefront of modern astronomical research. Investment in this research program will also help ensure that European astronomers are strongly positioned to exploit the James Webb Space Telescope (JWST), the Atacama Large Millimetre Array (ALMA), and future large telescopes (e.g. E-ELT) to study the physics of galaxy formation over virtually all of cosmic history.
Summary
A key question in modern science is to explain how the present-day universe of galaxies evolved from the initial conditions measured in the micro-wave background at recombination. Over the next 5 years I propose to undertake a major program of research to address this issue, by discovering and studying directly the progenitors of today's massive galaxies during the first ~2 billion years of cosmic history, and hence performing critical tests of current theories of galaxy formation. It is now clear that to sample representative volumes of the high-redshift universe requires ultra-deep near-infrared, mid-infrared and sub-mm surveys covering over ~1 sq. degree. Until now this has not been possible, but this field is about to be revolutionized by the introduction of a new generation of wide-field facilities in the next year. Specifically, 2009 will see the commissioning of the new near-infrared VISTA survey telescope in Chile, the new SCUBA2 sub-mm camera on the JCMT in Hawaii, the far-infrared Herschel Space Observatory, and the near-infrared camera WFC3 in the Hubble Space Telescope. Now, through my leadership of the deepest of the new generation of wide-field infrared and submm surveys to be undertaken with these revolutionary new facilities, I am unusually well-placed to take an integrated approach to the study of galaxy formation/evolution reaching back, for the first time, into the epoch of re-ionisation, at redshifts z ~ 7 - 10. Through this application I request the level of support required to exploit these new and unique data in what is one of the most important and topical areas at the forefront of modern astronomical research. Investment in this research program will also help ensure that European astronomers are strongly positioned to exploit the James Webb Space Telescope (JWST), the Atacama Large Millimetre Array (ALMA), and future large telescopes (e.g. E-ELT) to study the physics of galaxy formation over virtually all of cosmic history.
Max ERC Funding
2 317 255 €
Duration
Start date: 2010-04-01, End date: 2016-03-31
Project acronym CMR
Project Cosmic ray acceleration, magnetic field and radiation hydrodynamics
Researcher (PI) Anthony Raymond Bell
Host Institution (HI) THE CHANCELLOR, MASTERS AND SCHOLARS OF THE UNIVERSITY OF OXFORD
Call Details Advanced Grant (AdG), PE9, ERC-2009-AdG
Summary Diffusive shock acceleration is widely acknowledged as the most likely source of cosmic rays and high energy particles. The basic macroscopic theory of how cosmic rays gain energy during multiple shock crossings is well known, but the microphysics of the interaction between cosmic rays (CR) and the MHD background fluid remained poorly understood before the recent discovery of a new non-resonant instability by which the CR precursor could greatly amplify the ambient magnetic field. The aims of the project are: 1) to develop the first self-consistent non-linear simulation of the CR/MHD interaction; to calculate the magnitude of the saturated magnetic field and the maximum energy to which CR are accelerated. We will characterise the structure of the amplified magnetic field and compare it with x-ray observations of the time-evolving outer shock of supernova remnants (SNR). We will investigate the effect of various orientations of the shock relative to the ambient magnetic field, the effect of non-diffusive transport on the energy spectrum and CR escape from the SNR, and how these match observation. 2) to extend the simulation to relativistic shocks as found in gamma-ray bursts (GRB) and active galactic nuclei (AGN); to establish whether the non-resonant instability operates effectively at relativistic shock velocities, whether it explains the large magnetic field found in GRB, and determine the maximum CR energy achieved by relativistic shocks. 3) to investigate high density shocks in GRB, x-ray flashes (XRF) and supernovae (SN) where radiative processes, pair production and other particle/photon and particle/particle interactions are important. We shall investigate CR acceleration on SN shock breakout and very young SNR as a possible source of very high energy CR.
Summary
Diffusive shock acceleration is widely acknowledged as the most likely source of cosmic rays and high energy particles. The basic macroscopic theory of how cosmic rays gain energy during multiple shock crossings is well known, but the microphysics of the interaction between cosmic rays (CR) and the MHD background fluid remained poorly understood before the recent discovery of a new non-resonant instability by which the CR precursor could greatly amplify the ambient magnetic field. The aims of the project are: 1) to develop the first self-consistent non-linear simulation of the CR/MHD interaction; to calculate the magnitude of the saturated magnetic field and the maximum energy to which CR are accelerated. We will characterise the structure of the amplified magnetic field and compare it with x-ray observations of the time-evolving outer shock of supernova remnants (SNR). We will investigate the effect of various orientations of the shock relative to the ambient magnetic field, the effect of non-diffusive transport on the energy spectrum and CR escape from the SNR, and how these match observation. 2) to extend the simulation to relativistic shocks as found in gamma-ray bursts (GRB) and active galactic nuclei (AGN); to establish whether the non-resonant instability operates effectively at relativistic shock velocities, whether it explains the large magnetic field found in GRB, and determine the maximum CR energy achieved by relativistic shocks. 3) to investigate high density shocks in GRB, x-ray flashes (XRF) and supernovae (SN) where radiative processes, pair production and other particle/photon and particle/particle interactions are important. We shall investigate CR acceleration on SN shock breakout and very young SNR as a possible source of very high energy CR.
Max ERC Funding
900 024 €
Duration
Start date: 2010-05-01, End date: 2015-04-30
Project acronym COGS
Project Capitalizing on Gravitational Shear
Researcher (PI) Sarah Louise Bridle
Host Institution (HI) THE UNIVERSITY OF MANCHESTER
Call Details Starting Grant (StG), PE9, ERC-2009-StG
Summary Our Universe appears to be filled with mysterious ingredients: 25 per cent appears to be dark matter, perhaps an as-yet undiscovered particle, and 70 per cent seems to be a bizarre fluid, dubbed dark energy, for which there is no satisfactory theory. Solving the dark energy problem is the most pressing question in cosmology today. It is possible that dark energy does not exist at all, and instead Einstein s theory of General Relativity is flawed. Cosmologists hope to measure the properties of the dark energy using the next generation of cosmological observations, in which I am playing a leading role. I believe the most promising technique to crack the dark energy problem is gravitational shear, in which images of distant galaxies are distorted as they pass through the intervening dark matter distribution. Analysis of the distortions allows a map of the dark matter to be reconstructed; by examining the dark matter distribution we uncover the nature of the apparent dark energy. However to capitalize on the great potential of gravitational shear we must measure incredibly small image distortions in the presence of much larger image modifications that occur in the measurement process. I am proposing a fresh look at this problem using an inter-disciplinary approach in collaboration with computer scientists. This grant would enable my team to play a central role in the key results from the upcoming Dark Energy Survey. We would further capitalize on the gravitational shear signal by moving away from the current dark energy bandwagon by instead focusing on testing General Relativity using novel approaches. Our work will produce results which will lead the next Einstein to solve the biggest puzzle in cosmology, and arguably physics.
Summary
Our Universe appears to be filled with mysterious ingredients: 25 per cent appears to be dark matter, perhaps an as-yet undiscovered particle, and 70 per cent seems to be a bizarre fluid, dubbed dark energy, for which there is no satisfactory theory. Solving the dark energy problem is the most pressing question in cosmology today. It is possible that dark energy does not exist at all, and instead Einstein s theory of General Relativity is flawed. Cosmologists hope to measure the properties of the dark energy using the next generation of cosmological observations, in which I am playing a leading role. I believe the most promising technique to crack the dark energy problem is gravitational shear, in which images of distant galaxies are distorted as they pass through the intervening dark matter distribution. Analysis of the distortions allows a map of the dark matter to be reconstructed; by examining the dark matter distribution we uncover the nature of the apparent dark energy. However to capitalize on the great potential of gravitational shear we must measure incredibly small image distortions in the presence of much larger image modifications that occur in the measurement process. I am proposing a fresh look at this problem using an inter-disciplinary approach in collaboration with computer scientists. This grant would enable my team to play a central role in the key results from the upcoming Dark Energy Survey. We would further capitalize on the gravitational shear signal by moving away from the current dark energy bandwagon by instead focusing on testing General Relativity using novel approaches. Our work will produce results which will lead the next Einstein to solve the biggest puzzle in cosmology, and arguably physics.
Max ERC Funding
1 400 000 €
Duration
Start date: 2010-04-01, End date: 2016-03-31
Project acronym EXOEARTHS
Project EXtra-solar planets and stellar astrophysics: towards the detection of Other Earths
Researcher (PI) Nuno Miguel Cardoso Santos
Host Institution (HI) CENTRO DE INVESTIGACAO EM ASTRONOMIA E ASTROFISICA DA UNIVERSIDADE DO PORTO
Call Details Starting Grant (StG), PE9, ERC-2009-StG
Summary The detection of more than 300 extrasolar planets orbiting other solar-like stars opened the window to a new field of astrophysics. Many projects to search for Earth-like planets are currently under way, using a huge battery of telescopes and instruments. New instrumentation is also being developed towards this goal for use in both ground- and space-based based facilities. Since planets come as an output of the star formation process, the study of the stars hosting planets is of great importance. The stellar-planet connection is strengthened by the fact that most of the exoplanets were discovered using a Doppler radial-velocity technique, where the gravitational influence of the planet on the star and not the planet itself is actually measured. This project aims at doing frontier research to explore i) in unique detail the stellar limitations of the radial-velocity technique, as well as ways of reducing them, having in mind the detection of Earth-like planets and ii) to develop and apply software packages aiming at the study of the properties of the planet-host stars, having in mind the full characterization of the newfound planets, as well as understanding planet formation processes. These goals will improve our capacity to detect, study, and characterize new very low mass extra-solar planets. EXOEarths further fits into the fact that I am currently Co-PI of the project for a new high-resolution ultra-stable spectrograph for the VLT. The results of this project are crucial to fully exploit this new instrument. They will be also of extreme importance to current state-of-the-art planet-search projects aiming at the discovery of other Earths, in particular those making use of the radial-velocity method.
Summary
The detection of more than 300 extrasolar planets orbiting other solar-like stars opened the window to a new field of astrophysics. Many projects to search for Earth-like planets are currently under way, using a huge battery of telescopes and instruments. New instrumentation is also being developed towards this goal for use in both ground- and space-based based facilities. Since planets come as an output of the star formation process, the study of the stars hosting planets is of great importance. The stellar-planet connection is strengthened by the fact that most of the exoplanets were discovered using a Doppler radial-velocity technique, where the gravitational influence of the planet on the star and not the planet itself is actually measured. This project aims at doing frontier research to explore i) in unique detail the stellar limitations of the radial-velocity technique, as well as ways of reducing them, having in mind the detection of Earth-like planets and ii) to develop and apply software packages aiming at the study of the properties of the planet-host stars, having in mind the full characterization of the newfound planets, as well as understanding planet formation processes. These goals will improve our capacity to detect, study, and characterize new very low mass extra-solar planets. EXOEarths further fits into the fact that I am currently Co-PI of the project for a new high-resolution ultra-stable spectrograph for the VLT. The results of this project are crucial to fully exploit this new instrument. They will be also of extreme importance to current state-of-the-art planet-search projects aiming at the discovery of other Earths, in particular those making use of the radial-velocity method.
Max ERC Funding
928 090 €
Duration
Start date: 2009-10-01, End date: 2014-12-31
Project acronym FORCE
Project Fine Observations of the Rate of Cosmic Expansion: Combining the powers of Weak Gravitational Lensing and Baryon Acoustic Oscillations as Probes of Dark Energy
Researcher (PI) Catherine Elizabeth Cox Heymans
Host Institution (HI) THE UNIVERSITY OF EDINBURGH
Call Details Starting Grant (StG), PE9, ERC-2009-StG
Summary I propose to combine state-of-the-art observations of weak gravitational lensing and baryon acoustic oscillations to answer one fundamental question; is the accelerating expansion of our Universe caused by dark energy, or is it a manifestation of beyond-Einstein gravity theories, as might arise if the Universe has more dimensions? This frontier research will have a wide ranging impact as is it believed that understanding the dark energy phenomenon will revolutionize our understanding of Physics today. The observational task of detecting and analysing probes of dark energy is technically very challenging and may be subject to systematic limits. I detail how I will exploit synergies between the weak lensing and baryon acoustic oscillations techniques, showing that the physical systematics that effect each technique can be neatly resolved using complementary information from the alternative technique. With support from the ERC I will create an inter-disciplinary team well positioned to first solve many of the systematic problems associated with dark energy research and then apply those novel solutions to the dark energy analysis of three world-leading wide-field surveys that I currently co-investigate; CFHTLS, a recently completed 170 square degree ugriz survey, PanSTARRS-1, a soon to be started all-sky grizy survey and ADEPT, a space-based infra-red telescope for baryon acoustic oscillation studies proposed for NASA s Joint Dark Energy Mission. Using innovative 3D statistical analyses, optimised photometric redshifts and new combined lensing and galaxy clustering statistics, my ERC team will aim to control systematic errors to place joint constraints on the evolving nature of dark energy and test directly beyond-Einstein gravity.
Summary
I propose to combine state-of-the-art observations of weak gravitational lensing and baryon acoustic oscillations to answer one fundamental question; is the accelerating expansion of our Universe caused by dark energy, or is it a manifestation of beyond-Einstein gravity theories, as might arise if the Universe has more dimensions? This frontier research will have a wide ranging impact as is it believed that understanding the dark energy phenomenon will revolutionize our understanding of Physics today. The observational task of detecting and analysing probes of dark energy is technically very challenging and may be subject to systematic limits. I detail how I will exploit synergies between the weak lensing and baryon acoustic oscillations techniques, showing that the physical systematics that effect each technique can be neatly resolved using complementary information from the alternative technique. With support from the ERC I will create an inter-disciplinary team well positioned to first solve many of the systematic problems associated with dark energy research and then apply those novel solutions to the dark energy analysis of three world-leading wide-field surveys that I currently co-investigate; CFHTLS, a recently completed 170 square degree ugriz survey, PanSTARRS-1, a soon to be started all-sky grizy survey and ADEPT, a space-based infra-red telescope for baryon acoustic oscillation studies proposed for NASA s Joint Dark Energy Mission. Using innovative 3D statistical analyses, optimised photometric redshifts and new combined lensing and galaxy clustering statistics, my ERC team will aim to control systematic errors to place joint constraints on the evolving nature of dark energy and test directly beyond-Einstein gravity.
Max ERC Funding
1 258 797 €
Duration
Start date: 2010-04-01, End date: 2015-10-31
Project acronym GALACTICA
Project Dynamical imprints of the evolutionary history of the Milky Way
Researcher (PI) Amina Helmi
Host Institution (HI) RIJKSUNIVERSITEIT GRONINGEN
Call Details Starting Grant (StG), PE9, ERC-2009-StG
Summary Galactic Astronomy is entering a new era, driven by state-of-the-art instrumentation and large surveys, and by the dramatic leaps in our understanding of galaxy formation provided by the cosmological LCDM framework. These surveys have shown that the Galaxy is up for discoveries every single month, and have revealed the first footprints of past mergers. This Era will reach its summit when the Gaia mission, scheduled for launch in 2011, provides the much-awaited survey of Galactic phase-space for a billion stars. This motivates us to propose a program that will provide a comprehensive view of the dynamical imprints leftover from the Galaxy s evolutionary history. This program will address the following key questions: How much memory does a galaxy like the Milky Way retain of its past? What is the relative importance of internally driven (secular processes) and externally acquired (mergers) phase-space substructure? What was the merging history of the Galaxy? Is the Galaxy consistent with LCDM? This ambitious program will advance the field of Galactic archaeology beyond the state-of-the-art thanks to two developments: the Aquarius Project simulations and the RAVE spectroscopic survey. The Aquarius are the largest ever cosmological simulations of a Milky Way dark matter halo. When complemented with a recently built phenomenological galaxy formation model, these superb simulations will serve for comparisons to the latest observational datasets, and in particular to the RAVE survey that is providing a fantastic dynamical map of the Solar vicinity. This will enable us to be in prime position to exploit the first Gaia data release in 2013, and before the end of this Research Program, to harvest its key scientific goal, namely to unravel the assembly history of the Milky Way.
Summary
Galactic Astronomy is entering a new era, driven by state-of-the-art instrumentation and large surveys, and by the dramatic leaps in our understanding of galaxy formation provided by the cosmological LCDM framework. These surveys have shown that the Galaxy is up for discoveries every single month, and have revealed the first footprints of past mergers. This Era will reach its summit when the Gaia mission, scheduled for launch in 2011, provides the much-awaited survey of Galactic phase-space for a billion stars. This motivates us to propose a program that will provide a comprehensive view of the dynamical imprints leftover from the Galaxy s evolutionary history. This program will address the following key questions: How much memory does a galaxy like the Milky Way retain of its past? What is the relative importance of internally driven (secular processes) and externally acquired (mergers) phase-space substructure? What was the merging history of the Galaxy? Is the Galaxy consistent with LCDM? This ambitious program will advance the field of Galactic archaeology beyond the state-of-the-art thanks to two developments: the Aquarius Project simulations and the RAVE spectroscopic survey. The Aquarius are the largest ever cosmological simulations of a Milky Way dark matter halo. When complemented with a recently built phenomenological galaxy formation model, these superb simulations will serve for comparisons to the latest observational datasets, and in particular to the RAVE survey that is providing a fantastic dynamical map of the Solar vicinity. This will enable us to be in prime position to exploit the first Gaia data release in 2013, and before the end of this Research Program, to harvest its key scientific goal, namely to unravel the assembly history of the Milky Way.
Max ERC Funding
1 613 680 €
Duration
Start date: 2010-01-01, End date: 2015-12-31
Project acronym GALFORMOD
Project Galaxy formation models for the next generation of evolutionary and cosmological surveys
Researcher (PI) Simon David Manton White
Host Institution (HI) MAX-PLANCK-GESELLSCHAFT ZUR FORDERUNG DER WISSENSCHAFTEN EV
Call Details Advanced Grant (AdG), PE9, ERC-2009-AdG
Summary Over the next decade, much effort on major astronomical facilities will be dedicated to large-scale surveys of the galaxy population. Their aim is two-fold: understanding the origin and evolution of galaxies and their central supermassive black holes, and clarifying the nature of dark matter, dark energy and the process that produced all cosmic structure. Achieving these goals will require powerful and flexible modelling tools that can simulate galaxy evolution in all viable cosmologies and under a wide variety of assumptions about the governing physical processes. Such capabilities do not currently exist. I propose to develop them through a major expansion of the functionality and scope of the Millennium Simulation archive. New simulations, new theoretical approaches and new web services will allow users to study galaxy formation across the full range of galaxy masses (from dwarf spheroidals to giant cDs). Remote users will be able to change parameters and modelling prescriptions at will, creating virtual surveys of universes with any chosen cosmology and galaxy formation model. Matching to multiwavelength surveys of real galaxies will make it possible to isolate the physical processes driving galaxy evolution, and to characterize the systematic errors that uncertain galaxy formation physics induce in precision estimates of cosmological parameters. Scientific problems where these new capabilities may be decisive in enabling progress include: the role of supermassive black holes in shaping galaxy formation; the origin of diversity in the forms of galaxies and in their nuclear activity; the effects of environment on galaxy structure; the formation history of our own Milky Way; the nature of the first galaxies and their effects on later and more easily observable generations of galaxies; the distribution and nature of dark matter; the origin of all cosmic structure; and the nature of dark energy.
Summary
Over the next decade, much effort on major astronomical facilities will be dedicated to large-scale surveys of the galaxy population. Their aim is two-fold: understanding the origin and evolution of galaxies and their central supermassive black holes, and clarifying the nature of dark matter, dark energy and the process that produced all cosmic structure. Achieving these goals will require powerful and flexible modelling tools that can simulate galaxy evolution in all viable cosmologies and under a wide variety of assumptions about the governing physical processes. Such capabilities do not currently exist. I propose to develop them through a major expansion of the functionality and scope of the Millennium Simulation archive. New simulations, new theoretical approaches and new web services will allow users to study galaxy formation across the full range of galaxy masses (from dwarf spheroidals to giant cDs). Remote users will be able to change parameters and modelling prescriptions at will, creating virtual surveys of universes with any chosen cosmology and galaxy formation model. Matching to multiwavelength surveys of real galaxies will make it possible to isolate the physical processes driving galaxy evolution, and to characterize the systematic errors that uncertain galaxy formation physics induce in precision estimates of cosmological parameters. Scientific problems where these new capabilities may be decisive in enabling progress include: the role of supermassive black holes in shaping galaxy formation; the origin of diversity in the forms of galaxies and in their nuclear activity; the effects of environment on galaxy structure; the formation history of our own Milky Way; the nature of the first galaxies and their effects on later and more easily observable generations of galaxies; the distribution and nature of dark matter; the origin of all cosmic structure; and the nature of dark energy.
Max ERC Funding
1 830 000 €
Duration
Start date: 2010-01-01, End date: 2014-12-31
Project acronym GLOSTAR
Project A Global View of Star Formation in the Milky Way
Researcher (PI) Karl M. Menten
Host Institution (HI) MAX-PLANCK-GESELLSCHAFT ZUR FORDERUNG DER WISSENSCHAFTEN EV
Call Details Advanced Grant (AdG), PE9, ERC-2009-AdG
Summary Stars with more than about ten solar masses dominate galactic ecosystems and understanding the circumstances of their formation is one of the great challenges of modern astronomy. The spectacular HII regions they excite delineate the spiral arms of galaxies such as our own when seen face on making it clear that star formation and Galactic structure are intimately related. We propose to attain a Global View of Star Formation in the Milky Way in a powerful multi-pronged approach. Using VLBI observations of maser sources associated with young protostars, we will measure distances by trigonometric parallax to most of the dominant star forming regions in the Galaxy, which will reveal its spiral structure as well as faithfully represent the luminosity and masses of its constituents. A survey for submillimeter emission from dust, which we are presently pursuing, will deliver the locations of unseen deeply embedded protostars and protoclusters. We plan to combine this data with a comprehensive program to study the gaseous content of the protostellar regions and a very sensitive survey of the Galactic plane with the newly Expanded Very Large Array to find masers and hypercompact HII regions, pinpointing the very centers of the earliest star-forming activity. We also propose to study the infrared emission from more developed massive star clusters, deriving distance with the classic spectro-photometric method, properly calibrated with trigonometric parallaxes, and for the first time adapted to an extensive IR dataset. Our synoptic approach will utilize Europe s premier telescopes including ESO s VLT, the European VLBI Network, the APEX telescope, and ALMA to create a coherent, unique dataset with true legacy value for a global perspective on star formation in our Galaxy.
Summary
Stars with more than about ten solar masses dominate galactic ecosystems and understanding the circumstances of their formation is one of the great challenges of modern astronomy. The spectacular HII regions they excite delineate the spiral arms of galaxies such as our own when seen face on making it clear that star formation and Galactic structure are intimately related. We propose to attain a Global View of Star Formation in the Milky Way in a powerful multi-pronged approach. Using VLBI observations of maser sources associated with young protostars, we will measure distances by trigonometric parallax to most of the dominant star forming regions in the Galaxy, which will reveal its spiral structure as well as faithfully represent the luminosity and masses of its constituents. A survey for submillimeter emission from dust, which we are presently pursuing, will deliver the locations of unseen deeply embedded protostars and protoclusters. We plan to combine this data with a comprehensive program to study the gaseous content of the protostellar regions and a very sensitive survey of the Galactic plane with the newly Expanded Very Large Array to find masers and hypercompact HII regions, pinpointing the very centers of the earliest star-forming activity. We also propose to study the infrared emission from more developed massive star clusters, deriving distance with the classic spectro-photometric method, properly calibrated with trigonometric parallaxes, and for the first time adapted to an extensive IR dataset. Our synoptic approach will utilize Europe s premier telescopes including ESO s VLT, the European VLBI Network, the APEX telescope, and ALMA to create a coherent, unique dataset with true legacy value for a global perspective on star formation in our Galaxy.
Max ERC Funding
2 355 079 €
Duration
Start date: 2010-05-01, End date: 2015-04-30
Project acronym OGLEIV
Project Optical Gravitational Lensing Experiment: New Frontiers in Observational Astronomy
Researcher (PI) Andrzej Udalski
Host Institution (HI) UNIWERSYTET WARSZAWSKI
Call Details Advanced Grant (AdG), PE9, ERC-2009-AdG
Summary We apply for financial support for the new, fourth phase of the Optical Gravitational Lensing Experiment (OGLE-IV) - one of the largest scale sky surveys worldwide, operating continuously since 1992. During its operation the OGLE project contributed significantly to many fields of modern astrophysics including gravitational microlensing, extrasolar planets searches, stellar astrophysics, Galactic structure and many others. The main scientific goal of the OGLE-IV phase will be the second generation planetary microlensing survey. It should result in top rank discoveries of the Earth mass planets and should provide the full census of planets down to Earth masses orbiting their hosts at 1-5 AU orbits. This parameter space is only accessible to the microlensing technique. Complementary census of planets orbiting at the distances smaller that 1 AU is to be made by space missions using transit technique. OGLE-IV survey will also conduct research in many other top rank astrophysical topics like the search for Pluto size dwarf planets from the Kuiper Belt, search for free-floating black holes, microlensing in the Magellanic Clouds and Galactic disk. Hundreds of new discoveries in the variable star field are also guaranteed. Moreover, OGLE-IV will operate on-line services providing real time photometry of variable objects of many types. The OGLE-IV data will be placed in public domain and available to the astronomical community.
Summary
We apply for financial support for the new, fourth phase of the Optical Gravitational Lensing Experiment (OGLE-IV) - one of the largest scale sky surveys worldwide, operating continuously since 1992. During its operation the OGLE project contributed significantly to many fields of modern astrophysics including gravitational microlensing, extrasolar planets searches, stellar astrophysics, Galactic structure and many others. The main scientific goal of the OGLE-IV phase will be the second generation planetary microlensing survey. It should result in top rank discoveries of the Earth mass planets and should provide the full census of planets down to Earth masses orbiting their hosts at 1-5 AU orbits. This parameter space is only accessible to the microlensing technique. Complementary census of planets orbiting at the distances smaller that 1 AU is to be made by space missions using transit technique. OGLE-IV survey will also conduct research in many other top rank astrophysical topics like the search for Pluto size dwarf planets from the Kuiper Belt, search for free-floating black holes, microlensing in the Magellanic Clouds and Galactic disk. Hundreds of new discoveries in the variable star field are also guaranteed. Moreover, OGLE-IV will operate on-line services providing real time photometry of variable objects of many types. The OGLE-IV data will be placed in public domain and available to the astronomical community.
Max ERC Funding
2 498 000 €
Duration
Start date: 2010-01-01, End date: 2014-12-31
