The Zhurong rover, part of China’s Tianwen-1[{” attribute=””>Mars mission, has found evidence of liquid water at low Martian latitudes, indicating potentially habitable environments. This discovery, contradicting previous beliefs that water could only exist in solid or gaseous states on Mars, was made by analyzing morphological features and mineral compositions of dunes in the landing area.
The Zhurong rover has found evidence of water on dune surfaces on modern Mars by providing key observational proof of liquid water at low Martian latitudes, according to a study led by Prof. Xiaoguang Qin from the Institute of Geology and Geophysics (IGG) of the Chinese Academy of Sciences (CAS).
The study was published on April 28 in the journal Science Advances.
Researchers from the National Astronomical Observatories of CAS and the Institute of Atmospheric Physics of CAS were also involved in the study.
Previous studies have provided proof of a large amount of liquid water on early Mars, but with the escape of the early Martian atmosphere during the later period, the climate changed dramatically. Very low pressure and water vapor content make it difficult for liquid water to sustainably exist on Mars today. Thus, it has been widely believed that water can only exist there in solid or gaseous forms.
Nonetheless, droplets observed on the Phoenix’s robotic arm prove that salty liquid water can appear in the summer at current high latitudes on Mars. Numerical simulations have also shown that climatic conditions suitable for liquid water can briefly occur in certain areas of Mars today. Until now, though, no evidence has shown the presence of liquid water at low latitudes on Mars.
Now, however, findings from the Zhurong rover fill the gap. The Zhurong rover, which is part of China’s Tianwen-1 Mars exploration mission, successfully landed on Mars on May 15, 2021. The landing site is located at the southern edge of the Utopia Planitia (UP) Plain (109.925 E, 25.066 N), where the northern lowlands unit is located.
The researchers used data obtained by the Navigation and Terrain Camera (NaTeCam), Multispectral Camera (MSCam) and Mars Surface Composition Detector (MarSCoDe) aboard the Zhurong rover to study the various scale surface properties and physical compositions of the dunes upon descent. region.
They found some important morphological features on the dune surfaces, such as scales, cracks, grains, polygonal edges, and a ribbon-like trace. Analysis of the spectral data revealed that the surface layer of the dunes is rich in hydrated sulfates, hydrated silica (particularly opal-CT), trivalent iron oxide minerals (especially ferrihydrate) and possibly chlorides.
“According to the meteorological data measured by Zhurong and other Mars rover, we conclude that these dune surface properties are related to the involvement of brines formed from subsequent frost/snow melting on salt-containing dune surfaces when cooling occurs.” Professor Chen.
Specifically, salts in sand dunes cause ice/snow to melt at lower temperatures to form salty liquid water. As the brine dries, hydrated sulfates, opals, iron oxides, and other hydrated minerals precipitate sand particles to form sand aggregates and even crust. The crust is then cracked by shrinkage. Subsequent thaw/frost results in the formation of polygonal edges and a ribbon-like line on the crust surface.
The estimated age of the dunes (ca. 0.4–1.4 Ma) and the relationship between the three water phases indicate that the equatorial transport of water vapor from the polar ice sheet during large deflection phases at the end of the Martian Amazonian period led to the recurrence of wet environments at lower latitudes. Therefore, a scenario of hydroactivity has been proposed, i.e., cooling at low latitudes during large tilt phases of Mars leads to snow/snow precipitation and thus leads to the formation of crusts and agglomerations on the surface of the dunes. Thus consolidating the dunes and leaving their traces. of the activity of the liquid brine.
The discovery provides important observational evidence for liquid water at lower latitudes on Mars, where surface temperatures are relatively warmer and more suitable for life than at higher latitudes.
“This is important for understanding the evolutionary history of the Martian climate, for the search for a habitable environment, and for providing important clues for the search for life in the future,” said Professor Chen.
Reference: “Fresh Water at Low Latitudes on Mars: Possible Evidence for Dune Surfaces” by Xiaoguang Qin, Xin Ren, Xu Wang, Jianjun Liu, Haibin Wu, Xingguo Zeng, Yong Sun, Zhaopeng Chen, Shihao Zhang, Yizhong Zhang Wangli Chen, Bin Liu, Dawei Liu, Lin Guo, Kangkang Li, Xiangzhao Zeng, Hai Huang, Qing Zhang, Songzheng Yu, Chunlai Li, Zhengtang Guo, April 28, 2023, Available Here advances in science.
DOI: 10.1126/sciadv.add8868