TY - JOUR
T1 - Hyperion
T2 - The origin of the stars. A far UV space telescope for high-resolution spectroscopy over wide fields
AU - Hamden, Erika T.
AU - Schiminovich, David
AU - Nikzad, Shouleh
AU - Turner, Neal J.
AU - Burkhart, Blakesley
AU - Haworth, Thomas J.
AU - Hoadley, Keri
AU - Serena Kim, Jinyoung
AU - Bialy, Shmuel
AU - Bryden, Geoff
AU - Chung, Haeun
AU - Imara, Nia
AU - Kennicutt, Rob
AU - Pineda, Jorge
AU - Kong, Shuo
AU - Hasegawa, Yasuhiro
AU - Pascucci, Ilaria
AU - Godard, Benjamin
AU - Krumholz, Mark
AU - Lee, Min Young
AU - Seifried, Daniel
AU - Sternberg, Amiel
AU - Walch, Stefanie
AU - Smith, Miles
AU - Unwin, Stephen C.
AU - Luthman, Elizabeth
AU - Kiessling, Alina
AU - McGuire, James P.
AU - Rais-Zadeh, Mina
AU - Hoenk, Michael
AU - Pavlak, Thomas
AU - Vargas, Carlos
AU - Kim, Daewook
N1 - Publisher Copyright: © The Authors. Published by SPIE under a Creative Commons Attribution 4.0 International License. Distribution or reproduction of this work in whole or in part requires full attribution of the original publication, including its DOI.
PY - 2022/10/1
Y1 - 2022/10/1
N2 - We present Hyperion, a mission concept recently proposed to the December 2021 NASA Medium Explorer announcement of opportunity. Hyperion explores the formation and destruction of molecular clouds and planet-forming disks in nearby star-forming regions of the Milky Way. It does this using long-slit high-resolution spectroscopy of emission from fluorescing molecular hydrogen, which is a powerful far-ultraviolet (FUV) diagnostic. Molecular hydrogen (H2) is the most abundant molecule in the universe and a key ingredient for star and planet formation but is typically not observed directly because its symmetric atomic structure and lack of a dipole moment mean there are no spectral lines at visible wavelengths and few in the infrared. Hyperion uses molecular hydrogen's wealth of FUV emission lines to achieve three science objectives: (1) determining how star formation is related to molecular hydrogen formation and destruction at the boundaries of molecular clouds, (2) determining how quickly and by what process massive star feedback disperses molecular clouds, and (3) determining the mechanism driving the evolution of planet-forming disks around young solar-Analog stars. Hyperion conducts this science using a straightforward, highly efficient, single-channel instrument design. Hyperion's instrument consists of a 48-cm primary mirror with an f/5 focal ratio. The spectrometer has two modes, both covering 138.5-to 161.5-nm bandpasses. A low resolution mode has a spectral resolution of R ≥ 10,000 with a slit length of 65 arcmin, whereas the high-resolution mode has a spectral resolution of R ≥ 50,000 over a slit length of 5 armin. Hyperion occupies a 2-week-long high-earth lunar resonance TESS-like orbit and conducts 2 weeks of planned observations per orbit, with time for downlinks and calibrations. Hyperion was reviewed as category I, which is the highest rating possible but was not selected.
AB - We present Hyperion, a mission concept recently proposed to the December 2021 NASA Medium Explorer announcement of opportunity. Hyperion explores the formation and destruction of molecular clouds and planet-forming disks in nearby star-forming regions of the Milky Way. It does this using long-slit high-resolution spectroscopy of emission from fluorescing molecular hydrogen, which is a powerful far-ultraviolet (FUV) diagnostic. Molecular hydrogen (H2) is the most abundant molecule in the universe and a key ingredient for star and planet formation but is typically not observed directly because its symmetric atomic structure and lack of a dipole moment mean there are no spectral lines at visible wavelengths and few in the infrared. Hyperion uses molecular hydrogen's wealth of FUV emission lines to achieve three science objectives: (1) determining how star formation is related to molecular hydrogen formation and destruction at the boundaries of molecular clouds, (2) determining how quickly and by what process massive star feedback disperses molecular clouds, and (3) determining the mechanism driving the evolution of planet-forming disks around young solar-Analog stars. Hyperion conducts this science using a straightforward, highly efficient, single-channel instrument design. Hyperion's instrument consists of a 48-cm primary mirror with an f/5 focal ratio. The spectrometer has two modes, both covering 138.5-to 161.5-nm bandpasses. A low resolution mode has a spectral resolution of R ≥ 10,000 with a slit length of 65 arcmin, whereas the high-resolution mode has a spectral resolution of R ≥ 50,000 over a slit length of 5 armin. Hyperion occupies a 2-week-long high-earth lunar resonance TESS-like orbit and conducts 2 weeks of planned observations per orbit, with time for downlinks and calibrations. Hyperion was reviewed as category I, which is the highest rating possible but was not selected.
KW - spectroscopy
KW - telescopes
KW - ultraviolet astronomy
KW - ultraviolet spectroscopy
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U2 - 10.1117/1.JATIS.8.4.044008
DO - 10.1117/1.JATIS.8.4.044008
M3 - Article
SN - 2329-4124
VL - 8
JO - Journal of Astronomical Telescopes, Instruments, and Systems
JF - Journal of Astronomical Telescopes, Instruments, and Systems
IS - 4
M1 - 044008
ER -