Scots scientists can ‘fingerprint’ underground CO2

Scientists have found a 'unique signature' from traces of noble gases
Scientists have found a 'unique signature' from traces of noble gases
Share this article
2
Have your say

RESEARCHERS have found a way of “fingerprinting” carbon dioxide stored underground so its ultimate fate can be discovered.

Scientists at the Scottish Universities Environmental Research Centre, based in East Killbride, found they were able to use a “unique signature” from traces of the noble gases -helium, neon and argon - to monitor stored CO2.

Carbon dioxide emissions from energy generation, in particular coal burning, contribute to the increasing pace of global climate change.

Carbon capture and storage - or CCS - aims to store carbon dioxide in depleted oil and gas fields or deep aquifers, preventing it from reaching the atmosphere. Widespread use of CCS in the future could help to reduce global carbon emissions and slow global warming.

The researchers collected gas samples in 2009 and 2012 from wells at the Cranfield CO2-enhanced oil recovery field in Mississippi, USA.

Co-author Professor Finlay Stuart said today/yesterday [TUES]: “We have shown for the first time that the naturally occurring helium, neon and argon in the injected gas is a unique ‘fingerprint’ that can be used to monitor the movement of the CO2, and determine how it is stored.

“Before CCS can become widely adopted as a method of CO2 mitigation we need to know how effective the gas can be stored underground. The noble gases are chemically inert so they are not affected by interactions with rocks or water in the way that carbon dioxide is, so they can be used to identify the physical processes that have affected the gas. They provide a cheap way to fingerprint injected gases in future large-scale carbon storage projects, and have the potential to provide a unique way to track the presence of deep shale gas and coal bed-derived methane in shallow aquifers during and after extraction.”

The team’s paper is published in the International Journal of Greenhouse Gas Control. The research was supported by funding from the Engineering and Physical Sciences Research Council.