Colorado Ultraviolet Transit Experiment: a dedicated CubeSat mission to study exoplanetary mass loss and magnetic fields

Abstract. The Colorado Ultraviolet Transit Experiment (CUTE) is a near-UV (2550 to 3300  Å) 6U CubeSat mission designed to monitor transiting hot Jupiters to quantify their atmospheric mass loss and magnetic fields. CUTE will probe both atomic (Mg and Fe) and molecular (OH) lines for evidence of enhanced transit absorption, and to search for evidence of early ingress due to bow shocks ahead of the planet’s orbital motion. As a dedicated mission, CUTE will observe ≳100 spectroscopic transits of hot Jupiters over a nominal 7-month mission. This represents the equivalent of >700 orbits of the only other instrument capable of these measurements, the Hubble Space Telescope. CUTE efficiently utilizes the available CubeSat volume by means of an innovative optical design to achieve a projected effective area of ∼28  cm2, low instrumental background, and a spectral resolving power of R∼3000 over the primary science bandpass. These performance characteristics enable CUTE to discern transit depths between 0.1% and 1% in individual spectral absorption lines. We present the CUTE optical and mechanical design, a summary of the science motivation and expected results, and an overview of the projected fabrication, calibration, and launch timeline.

[1]  Gopal-Krishna,et al.  Hint of 150 MHz radio emission from the Neptune-mass extrasolar transiting planet HAT-P-11b , 2013, 1302.4612.

[2]  P. Lavvas,et al.  The escape of heavy atoms from the ionosphere of HD209458b. I. A photochemical–dynamical model of the thermosphere , 2012, 1210.1536.

[3]  R. G. West,et al.  METALS IN THE EXOSPHERE OF THE HIGHLY IRRADIATED PLANET WASP-12b , 2010, 1005.3656.

[4]  C. Moutou,et al.  The stellar wind cycles and planetary radio emission of the τ Boo system , 2012, 1204.3843.

[5]  Ch. Helling,et al.  Prospects for detection of exoplanet magnetic fields through bow‐shock observations during transits , 2010, 1011.3455.

[6]  Alan D. Aylward,et al.  A Thermospheric Circulation Model for Extrasolar Giant Planets , 2007 .

[7]  James C. Green,et al.  The Cosmic Origins Spectrograph , 2003, SPIE Astronomical Telescopes + Instrumentation.

[8]  J. C. McConnell,et al.  Magnesium in the atmosphere of the planet HD 209458 b: observations of the thermosphere-exosphere transition region , 2013, 1310.8104.

[9]  V. Bourrier,et al.  Modeling magnesium escape from HD 209458b atmosphere , 2014, 1404.2120.

[10]  Roger V. Yelle,et al.  Aeronomy of extra-solar giant planets at small orbital distances , 2003 .

[11]  P. J. Wheatley,et al.  Characterising exoplanets and their environment with UV transmission spectroscopy , 2015, 1503.01278.

[12]  Alain Lecavelier des Etangs,et al.  3D model of hydrogen atmospheric escape from HD 209458b and HD 189733b: radiative blow-out and stellar wind interactions , 2013, 1308.0561.

[13]  G. H'ebrard,et al.  Detection of Oxygen and Carbon in the Hydrodynamically Escaping Atmosphere of the Extrasolar Planet HD 209458b , 2004, astro-ph/0401457.

[14]  Kevin France,et al.  OBSERVATIONS OF MASS LOSS FROM THE TRANSITING EXOPLANET HD 209458b , 2010, 1005.1633.

[15]  R. G. West,et al.  Near-UV Absorption , Chromospheric Activity , and Star-Planet Interactions in the WASP-12 system . 1 , 2022 .

[16]  T. Bastian,et al.  A Search for Radio Emission from Extrasolar Planets , 1999 .

[17]  Duncan Christie,et al.  Investigation of the environment around close-in transiting exoplanets using cloudy , 2016, 1603.01229.

[18]  Ch. Helling,et al.  EARLY UV INGRESS IN WASP-12b: MEASURING PLANETARY MAGNETIC FIELDS , 2010, 1009.5947.

[19]  P. Lavvas,et al.  The escape of heavy atoms from the ionosphere of HD209458b. II. Interpretation of the observations , 2012, 1210.1543.

[20]  Mary J. Li,et al.  Scattered light characterization of FORTIS , 2017, Optical Engineering + Applications.

[21]  Kevin France,et al.  SISTINE: a pathfinder for FUV imaging spectroscopy on future NASA astrophysics missions , 2016, Astronomical Telescopes + Instrumentation.

[22]  N. Bridges,et al.  The ChemCam Instrument Suite on the Mars Science Laboratory (MSL) Rover: Body Unit and Combined System Tests , 2012 .

[23]  James C. Green,et al.  Cosmic origins spectrograph FUV grating performance , 2002, SPIE Optics + Photonics.

[24]  L. Fossati,et al.  On the ultraviolet anomalies of the WASP-12 and HD 189733 systems: Trojan satellites as a plasma source , 2016, 1605.02507.

[25]  Kevin France,et al.  Searching for Far-ultraviolet Auroral/dayglow Emission from HD209458b with the Cosmic Origins Spectrograph , 2010, 1002.3218.

[26]  M. R. Burleigh,et al.  HUBBLE SPACE TELESCOPE OBSERVATIONS OF THE NUV TRANSIT OF WASP-12b , 2015, 1502.07489.