A predictive model for the ichnological suitability of the Jezero crater, Mars: searching for fossilized traces of life-substrate interactions in the 2020 Rover Mission Landing Site

PeerJ. 2021 Sep 23:9:e11784. doi: 10.7717/peerj.11784. eCollection 2021.

Abstract

Ichnofossils, the fossilized products of life-substrate interactions, are among the most abundant biosignatures on Earth and therefore they may provide scientific evidence of potential life that may have existed on Mars. Ichnofossils offer unique advantages in the search for extraterrestrial life, including the fact that they are resilient to processes that obliterate other evidence for past life, such as body fossils, as well as chemical and isotopic biosignatures. The goal of this paper is evaluating the suitability of the Mars 2020 Landing Site for ichnofossils. To this goal, we apply palaeontological predictive modelling, a technique used to forecast the location of fossil sites in uninvestigated areas on Earth. Accordingly, a geographic information system (GIS) of the landing site is developed. Each layer of the GIS maps the suitability for one or more ichnofossil types (bioturbation, bioerosion, biostratification structures) based on an assessment of a single attribute (suitability factor) of the Martian environment. Suitability criteria have been selected among the environmental attributes that control ichnofossil abundance and preservation in 18 reference sites on Earth. The goal of this research is delivered through three predictive maps showing which areas of the Mars 2020 Landing Site are more likely to preserve potential ichnofossils. On the basis of these maps, an ichnological strategy for the Perseverance rover is identified, indicating (1) 10 sites on Mars with high suitability for bioturbation, bioerosion and biostratification ichnofossils, (2) the ichnofossil types, if any, that are more likely to be present at each site, (3) the most efficient observation strategy for detecting eventual ichnofossils. The predictive maps and the ichnological strategy can be easily integrated in the existing plans for the exploration of the Jezero crater, realizing benefits in life-search efficiency and cost-reduction.

Keywords: Astrobiology; Bioerosion; Biostratification; Bioturbation; GIS; Ichnofossil; Ichnology; Mars; Paleontology; Predictive modelling.

Grants and funding

The work of Andrea Baucon is supported by the CAMBIACLIMA project (University of Genova). The fieldwork of Andrea Baucon in Portugal has been supported by the project PALAEOGIANTS (University of Genova) and FOSSIL ART (Naturtejo). Associação de Estudos do Alto Tejo (Portugal) provided financial support. The authors received support from the University of Milan through the APC initiative. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.