Your search keyword '"time domain astrophysics"' showing total 9 results

1. The high energy X-ray probe (HEX-P): the most powerful jets through the lens of a superb X-ray eye.

Author

Marcotulli, Lea, Ajello, Marco, Böttcher, Markus, Coppi, Paolo, Costamante, Luigi, Di Gesu, Laura, Errando, Manel, García, Javier A., Gokus, Andrea, Liodakis, Ioannis, Madejski, Greg, Madsen, Kristin, Moretti, Alberto, Middei, Riccardo, McBride, Felicia, Petropoulou, Maria, Rani, Bindu, Sbarrato, Tullia, Stern, Daniel, and Vasilopoulos, Georgios

Subjects

*RADIO jets (Astrophysics), *SUPERMASSIVE black holes, *HARD X-rays, *X-rays, *X-ray telescopes, *SOFT X rays, *NEUTRINO detectors

Abstract

A fraction of the active supermassive black holes at the centers of galaxies in our Universe are capable of launching extreme kiloparsec-long relativistic jets. These jets are known multiband (radio to γ-ray) and multimessenger (neutrino) emitters, and some of them have been monitored over decades at all accessible wavelengths. However, several open questions remain unanswered about the processes powering these highly energetic phenomena. These jets intrinsically produce soft-to-hard X-ray emission that extends from E > 0.1 keV up to E > 100 keV, and simultaneous broadband X-ray coverage, combined with excellent timing and imaging capabilities, is required to uncover the physics of jets. Indeed, truly simultaneous soft-to-hard X-ray coverage, in synergy with current and upcoming high-energy facilities (such as IXPE, COSI, CTAO, etc.) and neutrino detectors (e.g., IceCube), would enable us to disentangle the particle population responsible for the high-energy radiation from these jets. A sensitive hard X-ray survey (F20-80 keV < 10-15erg cm-2 s-1) could unveil the bulk of their population in the early Universe. Acceleration and radiative processes responsible for the majority of their X-ray emission would be pinned down by microsecond timing capabilities at both soft and hard X-rays. Furthermore, imaging jet structures for the first time in the hard X-ray regime could unravel the origin of their high-energy emission. The proposed Probe-class mission concept High Energy X-ray Probe (HEX-P) combines all these required capabilities, making it the crucial next-generation X-ray telescope in the multi-messenger, time-domain era. HEX-P will be the ideal mission to unravel the science behind the most powerful accelerators in the Universe. [ABSTRACT FROM AUTHOR]

Published

2024

2. The high energy X-ray probe (HEX-P): the most powerful jets through the lens of a superb X-ray eye

Author

Lea Marcotulli, Marco Ajello, Markus Böttcher, Paolo Coppi, Luigi Costamante, Laura Di Gesu, Manel Errando, Javier A. García, Andrea Gokus, Ioannis Liodakis, Greg Madejski, Kristin Madsen, Alberto Moretti, Riccardo Middei, Felicia McBride, Maria Petropoulou, Bindu Rani, Tullia Sbarrato, Daniel Stern, Georgios Vasilopoulos, Michael Zacharias, Haocheng Zhang, and the HEX-P Collaboration

Subjects

blazar, supermassive black hole, jet, high energy astrophysical phenomena, X-ray mission, time domain astrophysics, Astronomy, QB1-991, Geophysics. Cosmic physics, QC801-809

Abstract

A fraction of the active supermassive black holes at the centers of galaxies in our Universe are capable of launching extreme kiloparsec-long relativistic jets. These jets are known multiband (radio to γ-ray) and multimessenger (neutrino) emitters, and some of them have been monitored over decades at all accessible wavelengths. However, several open questions remain unanswered about the processes powering these highly energetic phenomena. These jets intrinsically produce soft-to-hard X-ray emission that extends from E>0.1keV up to E>100keV, and simultaneous broadband X-ray coverage, combined with excellent timing and imaging capabilities, is required to uncover the physics of jets. Indeed, truly simultaneous soft-to-hard X-ray coverage, in synergy with current and upcoming high-energy facilities (such as IXPE, COSI, CTAO, etc.) and neutrino detectors (e.g., IceCube), would enable us to disentangle the particle population responsible for the high-energy radiation from these jets. A sensitive hard X-ray survey (F20−80keV

Published

2024

3. The Maunakea Spectroscopic Explorer: Thousands of fibers, infinite possibilities.

Author

Sheinis, Andrew, Barden, Samuel C., and Sobeck, Jennifer

Subjects

*GALACTIC evolution, *INFLATIONARY universe, *NEUTRINO mass, *PHYSICAL cosmology, *STARS, *MILKY Way, *ASTROPHYSICS, *GALAXY formation

Abstract

The Maunakea Spectroscopic Explorer (MSE) is a massively multiplexed spectroscopic survey facility that will replace the Canada–France–Hawai'i Telescope over the next two decades. This 12.5‐m telescope, with its 1.5 square degree field of view, will observe 18,000–20,000 astronomical targets in every pointing from 0.36 to 1.80 μ$$ \mu $$m at low/moderate resolution (R∼$$ \sim $$3,000, 6,000) and from 0.36 to 0.90 μ$$ \mu $$m at high resolution (R∼$$ \sim $$30,000). Parallel positioning of all fibers in the field will occur, providing simultaneous full‐field coverage for both resolution modes. Unveiling the composition and dynamics of the faint Universe, MSE will impact nearly every field of astrophysics across all spatial scales, from individual stars to the largest scale structures in the Universe, including (i) the ultimate Gaia follow‐up facility for understanding the chemistry and dynamics of the distant Milky Way, including the distant halo at high spectral resolution, (ii) the unparalleled study of galaxy formation and evolution at cosmic noon, (iii) the determination of the neutrino mass, and (iv) the generation of insights into inflationary physics through a cosmological redshift survey that probes a large volume of the Universe with a high galaxy density. Initially, CFHT will build a Pathfinder instrument to fast‐track the development of MSE technology while providing multi‐object and IFU spectroscopic capability. [ABSTRACT FROM AUTHOR]

Published

2023

4. Chronos - take the pulse of our galactic neighbourhood: After Gaia: Time domain information, masses and ages for stars.

Author

Michel, Eric, Haywood, Misha, Famaey, Benoit, Mosser, Benoit, Samadi, Reza, Monteiro, Mario J.P.F.G., Kjeldsen, Hans, Belkacem, Kevin, Miglio, Andréa, Garcia, Rafael, Katz, David, Suarez, Juan Carlos, Deheuvels, Sébastien, Campante, Tiago, Cunha, Margarida, Aguirre, Victor Silva, Ballot, Jerôme, and Moya, Andy

Subjects

*STELLAR mass, *STELLAR oscillations, *INNER planets, *AGE of stars, *RED giants, *NEIGHBORHOODS, *MILKY Way

Abstract

Understanding our Galaxy's structure, formation, and evolution will, over the next decades, continue to benefit from the wonderful large survey by Gaia, for astrometric, kinematic, and spectroscopic characterization, and by large spectroscopic surveys for chemical characterization. The weak link for full exploitation of these data is age characterization, and stellar age estimation relies predominantly on mass estimates. The ideas presented in this White Paper shows that a seismology survey is the way out of this situation and a natural complement to existing and planned surveys. These ideas are strongly rooted in the past decade's experience of the so-called Seismology revolution, initiated with CoRoT and Kepler. The case of red giant stars is used here as the best current illustration of what we can expect from seismology for large samples, but premises for similar developments exist in various other classes of stars covering other ranges of age or mass. Whatever the star considered, the first information provided by stellar pulsations is always related to the mean density and thus to the mass (and age). In order to satisfy the need for long-duration and all-sky coverage, we rely on a new instrumental concept which decouples integration time and sampling time. We thus propose a long (~1 year) all-sky survey which would perfectly fit between TESS, PLATO, and the Rubin Observatory (previously known as LSST) surveys to offer a time domain complement to the current and planned astrometric and spectroscopic surveys. The fine characterization of host stars is also a key aspect for the interpretation and exploitation of the various projects -- anticipated in the framework of the Voyage 2050 programme -- searching for atmospheric characterization of terrestrial planets or, more specifically, looking for a signature of life, in distant planets. [ABSTRACT FROM AUTHOR]

Published

2021

5. Chronos - take the pulse of our galactic neighbourhood. After Gaia: Time domain information, masses and ages for stars

Author

Sébastien Deheuvels, Kevin Belkacem, T. L. Campante, Jérôme Ballot, Victor Silva Aguirre, D. Katz, B. Mosser, Andy Moya, Margarida S. Cunha, Hans Kjeldsen, Misha Haywood, Juan Carlos Suárez, Benoit Famaey, Rafael A. García, Mário J. P. F. G. Monteiro, R. Samadi, Eric Michel, Andrea Miglio, Michel E., Haywood M., Famaey B., Mosser B., Samadi R., Monteiro M.J.P.F.G., Kjeldsen H., Belkacem K., Miglio A., Garcia R., Katz D., Suarez J.C., Deheuvels S., Campante T., Cunha M., Aguirre V.S., Ballot J., and Moya A.

Subjects

Red giant, Computer science, Milky Way, Milky way galaxy, Astrophysics::Cosmology and Extragalactic Astrophysics, 01 natural sciences, Stellar age estimation, Observatory, Planet, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Seismology, 010308 nuclear & particles physics, Astronomy, Astronomy and Astrophysics, Time domain astrophysics, Galaxy, Stars, Stellar ages, Stellar age, 13. Climate action, Space and Planetary Science, Terrestrial planet, Astrophysics::Earth and Planetary Astrophysics

Abstract

Understanding our Galaxy’s structure, formation, and evolution will, over the next decades, continue to benefit from the wonderful large survey by Gaia, for astrometric, kinematic, and spectroscopic characterization, and by large spectroscopic surveys for chemical characterization. The weak link for full exploitation of these data is age characterization, and stellar age estimation relies predominantly on mass estimates. The ideas presented in this White Paper shows that a seismology survey is the way out of this situation and a natural complement to existing and planned surveys. These ideas are strongly rooted in the past decade’s experience of the so-called Seismology revolution, initiated with CoRoT and Kepler. The case of red giant stars is used here as the best current illustration of what we can expect from seismology for large samples, but premises for similar developments exist in various other classes of stars covering other ranges of age or mass. Whatever the star considered, the first information provided by stellar pulsations is always related to the mean density and thus to the mass (and age). In order to satisfy the need for long-duration and allsky coverage, we rely on a new instrumental concept which decouples integration time and sampling time. We thus propose a long (~1 year) all-sky survey which would perfectly fit between TESS, PLATO, and the Rubin Observatory (previously known as LSST) surveys to offer a time domain complement to the current and planned astrometric and spectroscopic surveys. The fine characterization of host stars is also a key aspect for the interpretation and exploitation of the various projects – anticipated in the framework of the Voyage 2050 programme – searching for atmospheric characterization of terrestrial planets or, more specifically, looking for a signature of life, in distant planets.

Published

2021

6. The LOFAR Transients Pipeline.

Author

Swinbank, John D., Staley, Tim D., Molenaar, Gijs J., Rol, Evert, Rowlinson, Antonia, Scheers, Bart, Spreeuw, Hanno, Bell, Martin E., Broderick, Jess W., Carbone, Dario, Garsden, Hugh, van der Horst, Alexander J., Law, Casey J., Wise, Michael, Breton, Rene P., Cendes, Yvette, Corbel, Stéphane, Eislöffel, Jochen, Falcke, Heino, and Fender, Rob

Subjects

PIPELINES, ASTRONOMICAL surveys, WAVELENGTHS, IMAGE databases, RADIO frequency, IMAGE processing

Abstract

Current and future astronomical survey facilities provide a remarkably rich opportunity for transient astronomy, combining unprecedented fields of view with high sensitivity and the ability to access previously unexplored wavelength regimes. This is particularly true of LOFAR, a recently-commissioned, low-frequency radio interferometer, based in the Netherlands and with stations across Europe. The identification of and response to transients is one of LOFAR’s key science goals. However, the large data volumes which LOFAR produces, combined with the scientific requirement for rapid response, make automation essential. To support this, we have developed the LOFAR Transients Pipeline, or TraP. The TraP ingests multi-frequency image data from LOFAR or other instruments and searches it for transients and variables, providing automatic alerts of significant detections and populating a lightcurve database for further analysis by astronomers. Here, we discuss the scientific goals of the TraP and how it has been designed to meet them. We describe its implementation, including both the algorithms adopted to maximize performance as well as the development methodology used to ensure it is robust and reliable, particularly in the presence of artefacts typical of radio astronomy imaging. Finally, we report on a series of tests of the pipeline carried out using simulated LOFAR observations with a known population of transients. [ABSTRACT FROM AUTHOR]

Published

2015

7. Comet: A VOEvent broker.

Author

Swinbank, J.

Subjects

TRANSPORT protocols (Computer network protocols), TIME-domain analysis, ASTROPHYSICS research, COMPUTER network protocols, ASTRONOMERS

Abstract

The VOEvent standard provides a means of describing transient celestial events in a machine-readable format. This is an essential step towards analysing and, where appropriate, responding to the large volumes of transients which will be detected by future large scale surveys. The VOEvent Transport Protocol (VTP) defines a system by which VOEvents may be disseminated to the community. We describe the design and implementation of Comet, a freely available, open source implementation of VTP. We use Comet as a base to explore the performance characteristics of the VTP system, in particular with reference to meeting the requirements of future survey projects. We describe how, with the aid of simple extensions to VTP, Comet can help users filter high-volume streams of VOEvents to extract only those which are of relevance to particular science cases. Based on these tests and on the experience of developing Comet, we derive a number of recommendations for future refinements of the VTP standard. [ABSTRACT FROM AUTHOR]

Published

2014

8. The LOFAR Transients Pipeline

Author

Rudy Wijnands, Hugh Garsden, Benjamin Stappers, Casey J. Law, Jochen Eislöffel, Heino Falcke, E. Rol, John D. Swinbank, Adam Stewart, Rene P. Breton, Jason W. T. Hessels, Rob Fender, Philippe Zarka, Stephane Corbel, D. Carbone, Bart Scheers, Martin Bell, Y. Cendes, J. W. Broderick, Antonia Rowlinson, Ralph A. M. J. Wijers, Tim D. Staley, Jean-Mathias Grießmeier, Michael W. Wise, Alexander J. van der Horst, Gijs Molenaar, H. Spreeuw, Astronomical Institute Anton Pannekoek (AI PANNEKOEK), University of Amsterdam [Amsterdam] (UvA), Department of Astrophysical Sciences [Princeton], Princeton University, Oxford Astrophysics, University of Oxford [Oxford], Commonwealth Scientific and Industrial Research Organisation [Canberra] (CSIRO), Universität Hamburg (UHH), University of Southampton, Berkeley Radio Astronomy Laboratory (RAL), Department of Astronomy [Berkeley], University of California [Berkeley], University of California-University of California-University of California [Berkeley], University of California-University of California, Netherlands Institute for Radio Astronomy (ASTRON), Unité Scientifique de la Station de Nançay (USN), Université d'Orléans (UO)-Observatoire des Sciences de l'Univers en région Centre (OSUC), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, PSL Research University (PSL)-Centre National de la Recherche Scientifique (CNRS), Astrophysique Interprétation Modélisation (AIM (UMR_7158 / UMR_E_9005 / UM_112)), Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Université Paris Diderot - Paris 7 (UPD7), Thüringer Landessternwarte Tautenburg (TLS), Université Grenoble Alpes - UFR Médecine (UGA UFRM), Université Grenoble Alpes (UGA), Laboratoire de Physique et Chimie de l'Environnement et de l'Espace (LPC2E), Observatoire des Sciences de l'Univers en région Centre (OSUC), PSL Research University (PSL)-PSL Research University (PSL)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Centre National d’Études Spatiales [Paris] (CNES), Jodrell Bank Centre for Astrophysics, University of Manchester [Manchester], Laboratory for Atmospheric and Space Physics [Boulder] (LASP), University of Colorado [Boulder], Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA), Centre National de la Recherche Scientifique (CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Observatoire de Paris, PSL Research University (PSL)-PSL Research University (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC), ANR-10-LABX-0023,Labex UnivEarthS, ANR-11-IDEX-0005-02/11-IDEX-0005,USPC,USPC(2011), European Project: 247295,EC:FP7:ERC,ERC-2009-AdG,AARTFAAC(2010), European Project: 267697,EC:FP7:ERC,ERC-2010-AdG_20100224,4PI-SKY(2011), University of Oxford, University of California [Berkeley] (UC Berkeley), University of California (UC)-University of California (UC)-University of California [Berkeley] (UC Berkeley), University of California (UC)-University of California (UC), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS), Astrophysique Interprétation Modélisation (AIM (UMR7158 / UMR_E_9005 / UM_112)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Centre National d’Études Spatiales [Paris] (CNES), Jodrell Bank Centre for Astrophysics (JBCA), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), ANR-10-LABX-0023,UnivEarthS,Earth - Planets - Universe: observation, modeling, transfer(2010), ANR-11-IDEX-0005,USPC,Université Sorbonne Paris Cité(2011), Database Architectures, Centre National de la Recherche Scientifique (CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire des Sciences de l'Univers en région Centre (OSUC), Université Paris sciences et lettres (PSL)-Université d'Orléans (UO)-Centre National de la Recherche Scientifique (CNRS)-Université d'Orléans (UO), and High Energy Astrophys. & Astropart. Phys (API, FNWI)

Subjects

Astronomy, Real-time computing, Population, FOS: Physical sciences, Techniques: image processing, Astronomical survey, 01 natural sciences, Trap (computing), Methods: data analysis, 0103 physical sciences, education, 010303 astronomy & astrophysics, Instrumentation and Methods for Astrophysics (astro-ph.IM), Remote sensing, Physics, education.field_of_study, 010308 nuclear & particles physics, business.industry, Astronomical transients, Astronomical databases, Astronomy and Astrophysics, LOFAR, Time domain astrophysics, Automation, Pipeline (software), Computer Science Applications, [SDU.ASTR.IM]Sciences of the Universe [physics]/Astrophysics [astro-ph]/Instrumentation and Methods for Astrophysic [astro-ph.IM], Identification (information), Space and Planetary Science, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, business, Astrophysics - Instrumentation and Methods for Astrophysics, Radio astronomy

Abstract

Current and future astronomical survey facilities provide a remarkably rich opportunity for transient astronomy, combining unprecedented fields of view with high sensitivity and the ability to access previously unexplored wavelength regimes. This is particularly true of LOFAR, a recently-commissioned, low-frequency radio interferometer, based in the Netherlands and with stations across Europe. The identification of and response to transients is one of LOFAR's key science goals. However, the large data volumes which LOFAR produces, combined with the scientific requirement for rapid response, make automation essential. To support this, we have developed the LOFAR Transients Pipeline, or TraP. The TraP ingests multi-frequency image data from LOFAR or other instruments and searches it for transients and variables, providing automatic alerts of significant detections and populating a lightcurve database for further analysis by astronomers. Here, we discuss the scientific goals of the TraP and how it has been designed to meet them. We describe its implementation, including both the algorithms adopted to maximize performance as well as the development methodology used to ensure it is robust and reliable, particularly in the presence of artefacts typical of radio astronomy imaging. Finally, we report on a series of tests of the pipeline carried out using simulated LOFAR observations with a known population of transients., Comment: 30 pages, 11 figures; Accepted for publication in Astronomy & Computing; Code at https://github.com/transientskp/tkp

Published

2015

9. The LOFAR Transients Pipeline

Author

Swinbank, J.D., Staley, T.D., Molenaar, G.J., Rol, E., Rowlinson, A., Scheers, L.H.A. (Bart), Spreeuw, H., Bell, M.E., Broderick, J.W., Carbone, D., Garsden, H., Horst, A.J. van der, Law, C.J., Wise, M.W. (Michael), Breton, R.P., Cendes, Y.N., Corbel, S., Eislöffel, J., Falcke, H., Fender, R.P., Grießmeier, J.-M., Hessels, J.W.T., Stappers, B.W., Stewart, A.J., Wijers, R.A.M.J. (Ralph), Wijnands, R., Zarka, P., Swinbank, J.D., Staley, T.D., Molenaar, G.J., Rol, E., Rowlinson, A., Scheers, L.H.A. (Bart), Spreeuw, H., Bell, M.E., Broderick, J.W., Carbone, D., Garsden, H., Horst, A.J. van der, Law, C.J., Wise, M.W. (Michael), Breton, R.P., Cendes, Y.N., Corbel, S., Eislöffel, J., Falcke, H., Fender, R.P., Grießmeier, J.-M., Hessels, J.W.T., Stappers, B.W., Stewart, A.J., Wijers, R.A.M.J. (Ralph), Wijnands, R., and Zarka, P.

Abstract

Current and future astronomical survey facilities provide a remarkably rich opportunity for transient astronomy, combining unprecedented fields of view with high sensitivity and the ability to access previously unexplored wavelength regimes. This is particularly true of LOFAR, a recently-commissioned, low-frequency radio interferometer, based in the Netherlands and with stations across Europe. The identification of and response to transients is one of LOFAR’s key science goals. However, the large data volumes which LOFAR produces, combined with the scientific requirement for rapid response, make automation essential. To support this, we have developed the LOFAR Transients Pipeline, or TraP. The TraP ingests multi-frequency image data from LOFAR or other instruments and searches it for transients and variables, providing automatic alerts of significant detections and populating a lightcurve database for further analysis by astronomers. Here, we discuss the scientific goals of the TraP and how it has been designed to meet them. We describe its implementation, including both the algorithms adopted to maximize performance as well as the development methodology used to ensure it is robust and reliable, particularly in the presence of artefacts typical of radio astronomy imaging. Finally, we report on a series of tests of the pipeline carried out using simulated LOFAR observations with a known population of transients.

Published

2015