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LEM All-Sky Survey: Soft X-ray Sky at Microcalorimeter Resolution

Authors :
Khabibullin, Ildar
Galeazzi, Massimiliano
Bogdan, Akos
Cann, Jenna M.
Churazov, Eugene
Dolag, Klaus
Drake, Jeremy J.
Forman, William
Hernquist, Lars
Koutroumpa, Dimitra
Kraft, Ralph
Kuntz, K. D.
Markevitch, Maxim
McCammon, Dan
Ogorzalek, Anna
Pfeifle, Ryan
Pillepich, Annalisa
Plucinsky, Paul P.
Ponti, Gabriele
Schellenberger, Gerrit
Truong, Nhut
Valentini, Milena
Veilleux, Sylvain
Vladutescu-Zopp, Stephan
Wang, Q. Daniel
Weaver, Kimberly
Khabibullin, Ildar
Galeazzi, Massimiliano
Bogdan, Akos
Cann, Jenna M.
Churazov, Eugene
Dolag, Klaus
Drake, Jeremy J.
Forman, William
Hernquist, Lars
Koutroumpa, Dimitra
Kraft, Ralph
Kuntz, K. D.
Markevitch, Maxim
McCammon, Dan
Ogorzalek, Anna
Pfeifle, Ryan
Pillepich, Annalisa
Plucinsky, Paul P.
Ponti, Gabriele
Schellenberger, Gerrit
Truong, Nhut
Valentini, Milena
Veilleux, Sylvain
Vladutescu-Zopp, Stephan
Wang, Q. Daniel
Weaver, Kimberly
Publication Year :
2023

Abstract

The Line Emission Mapper (LEM) is an X-ray Probe with with spectral resolution ~2 eV FWHM from 0.2 to 2.5 keV and effective area >2,500 cm$^2$ at 1 keV, covering a 33 arcmin diameter Field of View with 15 arcsec angular resolution, capable of performing efficient scanning observations of very large sky areas and enabling the first high spectral resolution survey of the full sky. The LEM-All-Sky Survey (LASS) is expected to follow the success of previous all sky surveys such as ROSAT and eROSITA, adding a third dimension provided by the high resolution microcalorimeter spectrometer, with each 15 arcsec pixel of the survey including a full 1-2 eV resolution energy spectrum that can be integrated over any area of the sky to provide statistical accuracy. Like its predecessors, LASS will provide both a long-lasting legacy and open the door to the unknown, enabling new discoveries and delivering the baseline for unique GO studies. No other current or planned mission has the combination of microcalorimeter energy resolution and large grasp to cover the whole sky while maintaining good angular resolution and imaging capabilities. LASS will be able to probe the physical conditions of the hot phases of the Milky Way at multiple scales, from emission in the Solar system due to Solar Wind Charge eXchange, to the interstellar and circumgalactic media, including the North Polar Spur and the Fermi/eROSITA bubbles. It will measure velocities of gas in the inner part of the Galaxy and extract the emissivity of the Local Hot Bubble. By maintaining the original angular resolution, LASS will also be able to study classes of point sources through stacking. For classes with ~$10^4$ objects, it will provide the equivalent of 1 Ms of high spectral resolution data. We describe the technical specifications of LASS and highlight the main scientific objectives that will be addressed. (Abridged)<br />Comment: White Paper in support of a mission concept to be submitted for the 2023 NASA Astrophysics Probes opportunity. This White Paper will be updated when required. 30 pages, 25 figures

Details

Database :
OAIster
Publication Type :
Electronic Resource
Accession number :
edsoai.on1430700967
Document Type :
Electronic Resource