Solar system

Composite infrared spectrometer (CIRS) on Cassini

Applied Optics 56:18 (2017) 5274-5294

Authors:

DE Jennings, FM Flasar, VG Kunde, CA Nixon, ME Segura, PN Romani, N Gorius, S Albright, JC Brasunas, RC Carlson, AA Mamoutkine, E Guandique, MS Kaelberer, S Aslam, RK Achterberg, GL Bjoraker, CM Anderson, V Cottini, JC Pearl, MD Smith, BE Hesman, RD Barney, S Calcutt, TJ Vellacott, LJ Spilker, SG Edgington, SM Brooks, P Ade, PJ Schinder, A Coustenis, R Courtin, G Michel, R Fettig, S Pilorz, C Ferrari

Abstract:

© 2017 Optical Society of America. The Cassini spacecraft orbiting Saturn carries the composite infrared spectrometer (CIRS) designed to study thermal emission from Saturn and its rings and moons. CIRS, a Fourier transform spectrometer, is an indispensable part of the payload providing unique measurements and important synergies with the other instruments. It takes full advantage of Cassini's 13-year-long mission and surpasses the capabilities of previous spectrometers on Voyager 1 and 2. The instrument, consisting of two interferometers sharing a telescope and a scan mechanism, covers over a factor of 100 in wavelength in the mid and far infrared. It is used to study temperature, composition, structure, and dynamics of the atmospheres of Jupiter, Saturn, and Titan, the rings of Saturn, and surfaces of the icy moons. CIRS has returned a large volume of scientific results, the culmination of over 30 years of instrument development, operation, data calibration, and analysis. As Cassini and CIRS reach the end of their mission in 2017, we expect that archived spectra will be used by scientists for many years to come.

Independent evolution of stratospheric temperatures in Jupiter's northern and southern auroral regions from 2014 to 2016

Geophysical Research Letters American Geophysical Union 44:11 (2017) 5345-5354

Authors:

JA Sinclair, GS Orton, TK Greathouse, LN Fletcher, C Tao, GR Gladstone, A Adriani, W Dunn, JI Moses, V Hue, Patrick Irwin, H Melin, RS Giles

Abstract:

We present retrievals of the vertical temperature profile of Jupiter's high latitudes from Infrared Telescope Facility-Texas Echelon Cross Echelle Spectrograph measurements acquired on 10–11 December 2014 and 30 April to 1 May 2016. Over this time range, 1 mbar temperature in Jupiter's northern and southern auroral regions exhibited independent evolution. The northern auroral hot spot exhibited negligible net change in temperature at 1 mbar and its longitudinal position remained fixed at 180°W (System III), whereas the southern auroral hot spot exhibited a net increase in temperature of 11.1 ± 5.2 K at 0.98 mbar and its longitudinal orientation moved west by approximately 30°. This southern auroral stratospheric temperature increase might be related to (1) near-contemporaneous brightening of the southern auroral ultraviolet/near-infrared H + 3 emission measured by the Juno spacecraft and (2) an increase in the solar dynamical pressure in the preceding 3 days. We therefore suggest that 1 mbar temperature in the southern auroral region might be modified by higher-energy charged particle precipitation.

The PanCam instrument for the ExoMars rover

Astrobiology Mary Ann Liebert 17:6-7 (2017) 511-541

Authors:

AJ Coates, R Jaumann, AD Griffiths, CE Leff, N Schmitz, J-L Josset, G Paar, M Gunn, E Hauber, CR Cousins, RE Cross, P Grindrod, JC Bridges, M Balme, S Gupta, IA Crawford, Patrick Irwin, R Stabbins, D Tirsch, JL Vago, T Theodorou, M Caballo-Perucha, GR Osinski

Abstract:

The scientific objectives of the ExoMars rover are designed to answer several key questions in the search for life on Mars. In particular, the unique subsurface drill will address some of these, such as the possible existence and stability of subsurface organics. PanCam will establish the surface geological and morphological context for the mission, working in collaboration with other context instruments. Here, we describe the PanCam scientific objectives in geology, atmospheric science, and 3-D vision. We discuss the design of PanCam, which includes a stereo pair of Wide Angle Cameras (WACs), each of which has an 11-position filter wheel and a High Resolution Camera (HRC) for high-resolution investigations of rock texture at a distance. The cameras and electronics are housed in an optical bench that provides the mechanical interface to the rover mast and a planetary protection barrier. The electronic interface is via the PanCam Interface Unit (PIU), and power conditioning is via a DC-DC converter. PanCam also includes a calibration target mounted on the rover deck for radiometric calibration, fiducial markers for geometric calibration, and a rover inspection mirror. Key Words: Mars-ExoMars-Instrumentation-Geology-Atmosphere-Exobiology-Context. Astrobiology 17, 511-541.

Detection of a hydrogen corona at Callisto

Journal of Geophysical Research: Planets (2017)

Authors:

L Roth, J Alday, TM Becker, N Ivchenko, KD Retherford

Inflight radiometric calibration of New Horizons’ Multispectral Visible Imaging Camera (MVIC)

Icarus Elsevier BV 287 (2017) 140-151

Authors:

Cja Howett, Ah Parker, Cb Olkin, Dc Reuter, K Ennico, Wm Grundy, Al Graps, Kp Harrison, Hb Throop, Mw Buie, Jr Lovering, Sb Porter, Ha Weaver, La Young, Sa Stern, Ra Beyer, Rp Binzel, Bj Buratti, Af Cheng, Jc Cook, Dp Cruikshank, Cm Dalle Ore, Am Earle, De Jennings, Ir Linscott, Aw Lunsford, Jwm Parker, S Phillippe, S Protopapa, E Quirico, Pm Schenk, B Schmitt, Kn Singer, Jr Spencer, Ja Stansberry, Ccc Tsang, Ge Weigle, Aj Verbiscer

Abstract:

© 2016 Elsevier Inc. We discuss two semi-independent calibration techniques used to determine the inflight radiometric calibration for the New Horizons’ Multi-spectral Visible Imaging Camera (MVIC). The first calibration technique compares the measured number of counts (DN) observed from a number of well calibrated stars to those predicted using the component-level calibration. The ratio of these values provides a multiplicative factor that allows a conversation between the preflight calibration to the more accurate inflight one, for each detector. The second calibration technique is a channel-wise relative radiometric calibration for MVIC's blue, near-infrared and methane color channels using Hubble and New Horizons observations of Charon and scaling from the red channel stellar calibration. Both calibration techniques produce very similar results (better than 7% agreement), providing strong validation for the techniques used. Since the stellar calibration described here can be performed without a color target in the field of view and covers all of MVIC's detectors, this calibration was used to provide the radiometric keyword values delivered by the New Horizons project to the Planetary Data System (PDS). These keyword values allow each observation to be converted from counts to physical units; a description of how these keyword values were generated is included. Finally, mitigation techniques adopted for the gain drift observed in the near-infrared detector and one of the panchromatic framing cameras are also discussed.