Simon Calcutt

NASA's Lunar Trailblazer Mission: A Pioneering Small Satellite for Lunar Water and Lunar Geology

Institute of Electrical and Electronics Engineers (IEEE) 00 (2022) 1-14

Authors:

Bethany L Ehlmann, Rachel L Klima, Calina C Seybold, Andrew T Klesh, Mitchell H Au, Holly A Bender, C Lee Bennett, Diana L Blaney, Neil Bowles, Simon Calcutt, Djuna Copley-Woods, James L Dickson, Karim Djotni, Kerri Donaldson Hanna, Christopher S Edwards, Rory Evans, Emily Felder, Robert Fogg, Robert O Green, Gary Hawkins, Martha House, Samuel Islas, Gregory Lantoine, Sue Linch, Thomas McCaa, Ian McKinley, Trevor F Merkley, Jasper K Miura, Carle M Pieters, Wil Santiago, Elena Scire, Richard Sherwood, Katherine Shirley, Chris Smith, Michael Sondheim, Peter Sullivan, Jon Temples, David R Thompson, Kristian I Waldorff, Walton R Williamson, Tristam J Warren, Joshua L Wood, Shannon Zareh

Resonances of the InSight Seismometer on Mars

Bulletin of the Seismological Society of America Seismological Society of America (SSA) 111:6 (2021) 2951-2963

Authors:

Kenneth Hurst, Lucile Fayon, Brigitte Knapmeyer-Endrun, Cedric Schmelzbach, Martin van Driel, Joan Ervin, Sharon Kedar, William T Pike, Simon Calcutt, Tristram Warren, Constantino Charalambous, Alexander Stott, Marco Bierwirth, Philippe Lognonne, Sebastien de Raucourt, Taoufik Gabsi, Tanguy Nebut, Oliver Robert, Sylvain Tillier, Savas Ceylan, Maren Böse, John Clinton, Domenico Giardini, Anna Horleston, Taichi Kawamura, Amir Khan, Guenole Orhand-Mainsant, John-Robert Scholz, Simon Stähler, Jennifer Stevanovic, William B Banerdt

Standing on Apollo’s Shoulders: A Microseismometer for the Moon

The Planetary Science Journal American Astronomical Society 2:1 (2021) 36

Authors:

Ceri Nunn, William T Pike, Ian M Standley, Simon B Calcutt, Sharon Kedar, Mark P Panning

Spectral Characterization of Bennu Analogs Using PASCALE: A New Experimental Set‐Up for Simulating the Near‐Surface Conditions of Airless Bodies

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:2 (2021) e2020je006624

Authors:

KL Donaldson Hanna, NE Bowles, TJ Warren, VE Hamilton, DL Schrader, TJ McCoy, J Temple, A Clack, S Calcutt, DS Lauretta

Studying the composition and mineralogy of the hermean surface with the Mercury Radiometer and Thermal Infrared Spectrometer (MERTIS) for the BepiColombo mission: an update

Space Science Reviews Springer 216:6 (2020) 110

Authors:

H Hiesinger, J Helbert, G Alemanno, Ke Bauch, M D’Amore, A Maturilli, A Morlok, Mp Reitze, C Stangarone, An Stojic, I Varatharajan, I Weber, G Arnold, M Banaszkiewicz, K Bauch, J Benkhoff, A Bischoff, M Blecka, N Bowles, S Calcutt, L Colangeli, S Erard, S Fonti, Bt Greenhagen, O Groussain, H Hirsch, J Jahn, R Killen, J Knollenberg, E Kührt, E Lorenz, I Mann, U Mall, A Maturilli, A Morlok, L Moroz, G Peter, M Rataj, M Robinson, W Skrbek, T Spohn, A Sprague, D Stöffler, A Stojic, F Taylor, I Varatharajan, H Venus, J Warrell, I Walter, I Weber

Abstract:

Launched onboard the BepiColombo Mercury Planetary Orbiter (MPO) in October 2018, the Mercury Radiometer and Thermal Infrared Spectrometer (MERTIS) is on its way to planet Mercury. MERTIS consists of a push-broom IR-spectrometer (TIS) and a radiometer (TIR), which operate in the wavelength regions of 7-14 μm and 7-40 μm, respectively. This wavelength region is characterized by several diagnostic spectral signatures: the Christiansen feature (CF), Reststrahlen bands (RB), and the Transparency feature (TF), which will allow us to identify and map rock-forming silicates, sulfides as well as other minerals. Thus, the instrument is particularly well-suited to study the mineralogy and composition of the hermean surface at a spatial resolution of about 500 m globally and better than 500 m for approximately 5-10% of the surface. The instrument is fully functional onboard the BepiColombo spacecraft and exceeds all requirements (e.g., mass, power, performance). To prepare for the science phase at Mercury, the team developed an innovative operations plan to maximize the scientific output while at the same time saving spacecraft resources (e.g., data downlink). The upcoming fly-bys will be excellent opportunities to further test and adapt our software and operational procedures. In summary, the team is undertaking action at multiple levels, including performing a comprehensive suite of spectroscopic measurements in our laboratories on relevant analog materials, performing extensive spectral modeling, examining space weathering effects, and modeling the thermal behavior of the hermean surface.