The ESA Gaia satellite scans the whole sky with a temporal sampling ranging
from seconds and hours to months. Each time a source passes within the Gaia
field of view, it moves over 10 CCDs in 45 s and a lightcurve with 4.5 s
sampling (the crossing time per CCD) is registered. Given that the 4.5 s
sampling represents a virtually unexplored parameter space in optical time
domain astronomy, this data set potentially provides a unique opportunity to
open up the fast transient sky. We present a method to start mining the wealth
of information in the per CCD Gaia data. We perform extensive data filtering to
eliminate known on-board and data processing artefacts, and present a
statistical method to identify sources that show transient brightness
variations on ~2 hours timescales. We illustrate that by using the Gaia
photometric CCD measurements, we can detect transient brightness variations
down to an amplitude of 0.3 mag on timescales ranging from 15 seconds to
several hours. We search an area of ~23.5 square degrees on the sky, and find
four strong candidate fast transients. Two candidates are tentatively
classified as flares on M-dwarf stars, while one is probably a flare on a giant
star and one potentially a flare on a solar type star. These classifications
are based on archival data and the timescales involved. We argue that the
method presented here can be added to the existing Gaia Science Alerts
infrastructure for the near real-time public dissemination of fast transient
events.
%0 Generic
%1 wevers2017transient
%A Wevers, Thomas
%A Jonker, Peter G.
%A Hodgkin, Simon T.
%A Kostrzewa-Rutkowska, Zuzanna
%A Harrison, Diana L.
%A Rixon, Guy
%A Nelemans, Gijs
%A Roelens, Maroussia
%A Eyer, Laurent
%A van Leeuwen, Floor
%A Yoldas, Abdullah
%D 2017
%K variability
%R 10.1093/mnras/stx2625
%T The fast transient sky with Gaia
%U http://arxiv.org/abs/1710.08924
%X The ESA Gaia satellite scans the whole sky with a temporal sampling ranging
from seconds and hours to months. Each time a source passes within the Gaia
field of view, it moves over 10 CCDs in 45 s and a lightcurve with 4.5 s
sampling (the crossing time per CCD) is registered. Given that the 4.5 s
sampling represents a virtually unexplored parameter space in optical time
domain astronomy, this data set potentially provides a unique opportunity to
open up the fast transient sky. We present a method to start mining the wealth
of information in the per CCD Gaia data. We perform extensive data filtering to
eliminate known on-board and data processing artefacts, and present a
statistical method to identify sources that show transient brightness
variations on ~2 hours timescales. We illustrate that by using the Gaia
photometric CCD measurements, we can detect transient brightness variations
down to an amplitude of 0.3 mag on timescales ranging from 15 seconds to
several hours. We search an area of ~23.5 square degrees on the sky, and find
four strong candidate fast transients. Two candidates are tentatively
classified as flares on M-dwarf stars, while one is probably a flare on a giant
star and one potentially a flare on a solar type star. These classifications
are based on archival data and the timescales involved. We argue that the
method presented here can be added to the existing Gaia Science Alerts
infrastructure for the near real-time public dissemination of fast transient
events.
@misc{wevers2017transient,
abstract = {The ESA Gaia satellite scans the whole sky with a temporal sampling ranging
from seconds and hours to months. Each time a source passes within the Gaia
field of view, it moves over 10 CCDs in 45 s and a lightcurve with 4.5 s
sampling (the crossing time per CCD) is registered. Given that the 4.5 s
sampling represents a virtually unexplored parameter space in optical time
domain astronomy, this data set potentially provides a unique opportunity to
open up the fast transient sky. We present a method to start mining the wealth
of information in the per CCD Gaia data. We perform extensive data filtering to
eliminate known on-board and data processing artefacts, and present a
statistical method to identify sources that show transient brightness
variations on ~2 hours timescales. We illustrate that by using the Gaia
photometric CCD measurements, we can detect transient brightness variations
down to an amplitude of 0.3 mag on timescales ranging from 15 seconds to
several hours. We search an area of ~23.5 square degrees on the sky, and find
four strong candidate fast transients. Two candidates are tentatively
classified as flares on M-dwarf stars, while one is probably a flare on a giant
star and one potentially a flare on a solar type star. These classifications
are based on archival data and the timescales involved. We argue that the
method presented here can be added to the existing Gaia Science Alerts
infrastructure for the near real-time public dissemination of fast transient
events.},
added-at = {2017-10-26T23:18:35.000+0200},
author = {Wevers, Thomas and Jonker, Peter G. and Hodgkin, Simon T. and Kostrzewa-Rutkowska, Zuzanna and Harrison, Diana L. and Rixon, Guy and Nelemans, Gijs and Roelens, Maroussia and Eyer, Laurent and van Leeuwen, Floor and Yoldas, Abdullah},
biburl = {https://www.bibsonomy.org/bibtex/21338eb5ea69ff8c39553607f1c6110e5/superjenwinters},
description = {The fast transient sky with Gaia},
doi = {10.1093/mnras/stx2625},
interhash = {8fe71da221536f9f607116466848b400},
intrahash = {1338eb5ea69ff8c39553607f1c6110e5},
keywords = {variability},
note = {cite arxiv:1710.08924Comment: 10 pages, 5 figures and 5 tables; MNRAS in press},
timestamp = {2017-10-26T23:18:35.000+0200},
title = {The fast transient sky with Gaia},
url = {http://arxiv.org/abs/1710.08924},
year = 2017
}