Dr Tristram Warren

The Site Tilt and Lander Transfer Function from the Short-Period Seismometer of InSight on Mars

Bulletin of the Seismological Society of America Seismological Society of America (SSA) 111:6 (2021) 2889-2908

Authors:

Alexander E Stott, Constantinos Charalambous, Tristram J Warren, William T Pike, Robert Myhill, Naomi Murdoch, John B McClean, Ashitey Trebi-Ollennu, Grace Lim, Raphael F Garcia, David Mimoun, Sharon Kedar, Kenneth J Hurst, Marco Bierwirth, Philippe Lognonné, Nicholas A Teanby, Anna Horleston, William B Banerdt

Vortex‐Dominated Aeolian Activity at InSight's Landing Site, Part 1: Multi‐Instrument Observations, Analysis, and Implications

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:6 (2021)

Authors:

C Charalambous, JB McClean, M Baker, WT Pike, M Golombek, M Lemmon, V Ansan, C Perrin, A Spiga, RD Lorenz, ME Banks, N Murdoch, S Rodriguez, CM Weitz, JA Grant, NH Warner, J Garvin, IJ Daubar, E Hauber, AE Stott, CL Johnson, A Mittelholz, T Warren, S Navarro, LM Sotomayor, J Maki, A Lucas, D Banfield, C Newman, D Viúdez‐Moreiras, J Pla‐García, P Lognonné, WB Banerdt

Dynamics of Subsurface Migration of Water on the Moon

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:5 (2021)

Authors:

P Reiss, T Warren, E Sefton‐Nash, R Trautner

A Comodulation Analysis of Atmospheric Energy Injection Into the Ground Motion at InSight, Mars

Journal of Geophysical Research Planets American Geophysical Union (AGU) 126:4 (2021)

Authors:

C Charalambous, AE Stott, WT Pike, JB McClean, T Warren, A Spiga, D Banfield, RF Garcia, J Clinton, S Stähler, S Navarro, P Lognonné, J‐R Scholz, T Kawamura, M van Driel, M Böse, S Ceylan, A Khan, A Horleston, G Orhand‐Mainsant, LM Sotomayor, N Murdoch, D Giardini, WB Banerdt

Updates to the Oxford Space Environment Goniometer to measure visible wavelength bidirectional reflectance distribution functions in ambient conditions

Review of Scientific Instruments AIP Publishing 92:3 (2021) 034504

Authors:

Rowan Curtis, Tristram Warren, Neil Bowles

Abstract:

Understanding how the surfaces of airless planetary bodies—such as the Moon—scatter visible light enables constraints to be placed on their surface properties and top boundary layer inputs to be set within thermal models. Remote sensing instruments—such as Diviner onboard the Lunar Reconnaissance Orbiter—measure thermal emission and visible light scattering functions across visible (∼0.38–0.7 µm) to thermal infrared (TIR) wavelengths (∼0.7–350 μm). To provide ground support measurements for such instruments, the Oxford Space Environment Goniometer (OSEG) was built. Initially, the OSEG focused on measuring TIR directional emissivity functions for regolith and regolith simulant samples in a simulated space environment, but it has recently been modified to measure visible wavelength Bidirectional Reflectance Distribution Functions (BRDFs) of samples in ambient conditions. Laboratory-measured BRDFs can be used (1) to test and to help interpret models—such as the Hapke photometric model—and (2) as visible scattering function inputs for thermal models. This paper describes the modifications to and initial calibration measurements taken by the Visible Oxford Space Environment Goniometer with a 532 nm laser, and details how this setup can be used to measure BRDFs of regolith and regolith simulant samples of airless planetary bodies.