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Mineral that has implications for Mars mission identified
A mineral that breaks down organic compounds when it is flash-heated has key implications for the Mars Curiosity Mission, scientists reported. Jarosite is an iron sulphate and it is one of several minerals that NASA\'s Curiosity Mission is searching for as its presence could indicate ancient habitable environments which may have once hosted life on the red planet.
London: A mineral that breaks down organic compounds when it is flash-heated has key implications for the Mars Curiosity Mission, scientists reported. Jarosite is an iron sulphate and it is one of several minerals that NASA's Curiosity Mission is searching for as its presence could indicate ancient habitable environments which may have once hosted life on the red planet.
On Earth, iron sulphate minerals like jarosite form in the harsh acidic waters flowing out of sulphur rich rocks. Despite the adverse conditions, these waters are a habitat for bacteria that use these dissolved sulphate ions. Their presence on the red planet provides evidence that acidic liquid water was present at the same time the minerals formed.
This could have provided an environment favorable for harboring ancient microbial Martian life. To reach this conclusion, researchers from Imperial College London and the Natural History Museum replicated a technique that one of Curiosity Rover's on-board instruments is using to analyze soil samples. They tested a combination of jarosite and organic compounds.
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The team discovered that the instrument's technique - which uses intense bursts of heat called flash-heating - broke down jarosite into sulphur dioxide and oxygen, with the oxygen then destroying the organic compounds, leaving no trace of it behind. "The destructive properties of some iron sulphates and perchlorate to organic matter may explain why current and previous missions have so far offered no conclusive evidence of organic matter preserved on Mars' surface," said professor Mark Sephton from Imperial College London.
The next step will see the researchers using synthetic jarosite in their experiments which will enable a cleaner decomposition process to occur when the mineral is flash-heated. This will allow for more precise quantitative measurements to be taken when the oxygen is being released.
