Evaluation of the Capability of ExoMars-TGO NOMAD Infrared Nadir Channel for Water Ice Clouds Detection on Mars

DOI: 
10.3390/rs14174143
Publication date: 
01/09/2022
Main author: 
Ruiz Lozano L.
IAA authors: 
López Moreno, José Juan
Authors: 
Ruiz Lozano, Luca;Karatekin, Özgür;Dehant, Véronique;Bellucci, Giancarlo;Oliva, Fabrizio;D’Aversa, Emiliano;Carrozzo, Filippo Giacomo;Altieri, Francesca;Thomas, Ian R.;Willame, Yannick;Robert, Séverine;Vandaele, Ann Carinne;Daerden, Frank;Ristic, Bojan;Patel, Manish R.;López Moreno, José Juan
Journal: 
Remote Sensing
Publication type: 
Article
Volume: 
14.0
Number: 
4143
Abstract: 
As part of the payload of the 2016 ExoMars Trace Gas Orbiter (TGO) mission, the Nadir and Occultation for MArs Discovery (NOMAD) suite instrument has been observing the Martian atmosphere since March 2018. NOMAD is mainly dedicated to the study of trace atmospheric species taking advantage of a high-spectral resolution. We demonstrate that when NOMAD is observing in nadir mode, i.e., when the line-of-sight points to the centre of Mars, it can be also exploited to detect ice. In this study we present a method based on the investigation of nadir observations of the NOMAD infrared channel, acquired during Mars Years 34 and 35 (March 2018 to February 2021). We take advantage of the strong water ice absorption band at 2.7 µm by selecting the diffraction orders 167, 168, and 169. We derive the Frost and Clouds Index (FCI), which is a good proxy for ice mapping, and obtain latitudinal-seasonal maps for water ice clouds. FCI is sensitive to the Polar Hood clouds. Nevertheless, detections in the Aphelion Cloud Belt (ACB) are limited. This is consistent with previous observations showing different physical properties between the two main Martian atmospheric structures and making the ACB less detectable in the infrared. We hence derive the infrared nadir channel sensitivity limit for the detection of these clouds.
Database: 
SCOPUS
Keywords: 
H O ice clouds 2 | high-resolution spectrometer | Mars | Martian atmosphere