TY - UNPB
T1 - "SZ spectroscopy" in the coming decade
T2 - Galaxy cluster cosmology and astrophysics in the submillimeter
AU - Basu, Kaustuv
AU - Erler, Jens
AU - Chluba, Jens
AU - Delabrouille, Jacques
AU - Hill, J. Colin
AU - Mroczkowski, Tony
AU - Niemack, Michael D.
AU - Remazeilles, Mathieu
AU - Sayers, Jack
AU - Scott, Douglas
AU - Vavagiakis, Eve M.
AU - Zemcov, Michael
AU - Aravena, Manuel
AU - Bartlett, James G.
AU - Battaglia, Nicholas
AU - Bertoldi, Frank
AU - Charmetant, Maude
AU - Golwala, Sunil
AU - Herter, Terry L.
AU - Klaassen, Pamela
AU - Komatsu, Eiichiro
AU - Magnelli, Benjamin
AU - Mantz, Adam B.
AU - Meerburg, P. Daniel
AU - Melin, Jean-Baptiste
AU - Nagai, Daisuke
AU - Parshley, Stephen C.
AU - Pointecouteau, Etienne
AU - Ramos-Ceja, Miriam E.
AU - Ruszkowski, Mateusz
AU - Sehgal, Neelima
AU - Stacey, Gordon G.
AU - Sunyaev, Rashid
N1 - Science white paper submitted for the Astro2020 decadal review, 5 pages + references
PY - 2019/3/12
Y1 - 2019/3/12
N2 - Sunyaev-Zeldovich (SZ) effects were first proposed in the 1970s as tools to identify the X-ray emitting hot gas inside massive clusters of galaxies and obtain their velocities relative to the cosmic microwave background (CMB). Yet it is only within the last decade that they have begun to significantly impact astronomical research. Thanks to the rapid developments in CMB instrumentation, measurement of the dominant thermal signature of the SZ effects has become a routine tool to find and characterize large samples of galaxy clusters and to seek deeper understanding of several important astrophysical processes via high-resolution imaging studies of many targets. With the notable exception of the Planck satellite and a few combinations of ground-based observatories, much of this "SZ revolution" has happened in the photometric mode, where observations are made at one or two frequencies in the millimeter regime to maximize the cluster detection significance and minimize the foregrounds. Still, there is much more to learn from detailed and systematic analyses of the SZ spectra across multiple wavelengths, specifically in the submillimeter (>300 GHz) domain. The goal of this Science White Paper is to highlight this particular aspect of SZ research, point out what new and potentially groundbreaking insights can be obtained from these studies, and emphasize why the coming decade can be a golden era for SZ spectral measurements.
AB - Sunyaev-Zeldovich (SZ) effects were first proposed in the 1970s as tools to identify the X-ray emitting hot gas inside massive clusters of galaxies and obtain their velocities relative to the cosmic microwave background (CMB). Yet it is only within the last decade that they have begun to significantly impact astronomical research. Thanks to the rapid developments in CMB instrumentation, measurement of the dominant thermal signature of the SZ effects has become a routine tool to find and characterize large samples of galaxy clusters and to seek deeper understanding of several important astrophysical processes via high-resolution imaging studies of many targets. With the notable exception of the Planck satellite and a few combinations of ground-based observatories, much of this "SZ revolution" has happened in the photometric mode, where observations are made at one or two frequencies in the millimeter regime to maximize the cluster detection significance and minimize the foregrounds. Still, there is much more to learn from detailed and systematic analyses of the SZ spectra across multiple wavelengths, specifically in the submillimeter (>300 GHz) domain. The goal of this Science White Paper is to highlight this particular aspect of SZ research, point out what new and potentially groundbreaking insights can be obtained from these studies, and emphasize why the coming decade can be a golden era for SZ spectral measurements.
KW - astro-ph.CO
KW - astro-ph.HE
U2 - 10.48550/arXiv.1903.04944
DO - 10.48550/arXiv.1903.04944
M3 - Preprint
BT - "SZ spectroscopy" in the coming decade
ER -