TY - JOUR
T1 - Studying the Warm-hot Intergalactic Medium in Emission
AU - Takei, Yoh
AU - Ursino, E.
AU - Branchini, E.
AU - Ohashi, T.
AU - Kawahara, H.
AU - Mitsuda, K.
AU - Piro, L.
AU - Corsi, A.
AU - Amati, L.
AU - den Herder, J.W.A.
AU - Galeazzi, M.
AU - Kaastra, J.S.
AU - Moscardini, L.
AU - Nicastro, F.
AU - Paerels, F.
AU - Roncarelli, M.
AU - Viel, M.
PY - 2011
Y1 - 2011
N2 - We assess the possibility of detecting the warm-hot intergalactic medium in emission and characterizing its physical
conditions and spatial distribution through spatially resolved X-ray spectroscopy, in the framework of the recently
proposed DIOS, EDGE, Xenia, and ORIGIN missions, all of which are equipped with microcalorimeter-based
detectors. For this purpose, we analyze a large set of mock emission spectra, extracted from a cosmological
hydrodynamical simulation. These mock X-ray spectra are searched for emission features showing both the Ovii
Kα triplet and Oviii Lyα line, which constitute a typical signature of the warm-hot gas. Our analysis shows that
1Ms long exposures and energy resolution of 2.5 eV will allow us to detect about 400 such features per deg2 with
a significance 5σ and reveals that these emission systems are typically associated with density ∼100 above the
mean. The temperature can be estimated from the line ratio with a precision of ∼20%. The combined effect of
contamination from other lines, variation in the level of the continuum, and degradation of the energy resolution
reduces these estimates. Yet, with an energy resolution of 7 eV and all these effects taken into account, one still
expects about 160 detections per deg2. These line systems are sufficient for tracing the spatial distribution of the
line-emitting gas, which constitute an additional information, independent from line statistics, to constrain the
poorly known cosmic chemical enrichment history and the stellar feedback processes.
Key
AB - We assess the possibility of detecting the warm-hot intergalactic medium in emission and characterizing its physical
conditions and spatial distribution through spatially resolved X-ray spectroscopy, in the framework of the recently
proposed DIOS, EDGE, Xenia, and ORIGIN missions, all of which are equipped with microcalorimeter-based
detectors. For this purpose, we analyze a large set of mock emission spectra, extracted from a cosmological
hydrodynamical simulation. These mock X-ray spectra are searched for emission features showing both the Ovii
Kα triplet and Oviii Lyα line, which constitute a typical signature of the warm-hot gas. Our analysis shows that
1Ms long exposures and energy resolution of 2.5 eV will allow us to detect about 400 such features per deg2 with
a significance 5σ and reveals that these emission systems are typically associated with density ∼100 above the
mean. The temperature can be estimated from the line ratio with a precision of ∼20%. The combined effect of
contamination from other lines, variation in the level of the continuum, and degradation of the energy resolution
reduces these estimates. Yet, with an energy resolution of 7 eV and all these effects taken into account, one still
expects about 160 detections per deg2. These line systems are sufficient for tracing the spatial distribution of the
line-emitting gas, which constitute an additional information, independent from line statistics, to constrain the
poorly known cosmic chemical enrichment history and the stellar feedback processes.
Key
U2 - 10.1088/0004-637X/734/2/91
DO - 10.1088/0004-637X/734/2/91
M3 - Article
SN - 0004-637X
VL - 734
SP - 91/1-91/18
JO - Astrophysical Journal
JF - Astrophysical Journal
IS - 2
ER -