THERE have been many scientific advances during the decades of space exploration and now Glasgow University has added to that long list which includes foil blankets, freeze-dried food and “air” training shoes.

For a drill originally developed by Glasgow University engineers to break through rocks on the planet Mars is set to be deployed to Antarctica on a mission which could help lead to a better understanding of the history of Earth’s changing climate.

A team of engineers left from Glasgow yesterday, heading to a British Antarctic Survey (BAS) research station named Skytrain Ice Rise.

They are taking with them a sophisticated drill they originally developed for use on future unmanned Martian rover missions.

The university said in a statement: “Current drill technology requires considerable downward force in order to drive the drill bit through rock, a considerable challenge in lower-gravity environments such as the surface of Mars. The Glasgow engineers’ drill overcame that issue, which allowed the whole system to be made much smaller. That, in turn, made it ideal for sending down the long, narrow boreholes drilled by ice-cutting systems in Antarctica, where it aims to collect a sample of rock from the very bottom of the ice sheet.”

The team has worked with BAS on several occasions to test their space drill systems in the cold, dry, and rocky Antarctic, one of just a handful of places on Earth whose landscape is similar to that which might be found on Mars.

Glasgow University has long had links to Antarctica – the Hunterian Museum has a collection of rocks from the southernmost continent given by Glasgow alumnus David Ferguson.

The university research team, comprised of Kevin Worrall and Ryan Timoney, are aiming to leave for Antarctica this week, if weather permits. They will spend around three weeks there, before bringing the samples they collect back to the UK. The development of the drill was supported by funding and logistical support from the EU FP7 programme, the UK Space Agency, the Science and Technology Facilities Council, the Natural Environment Reseach Council, the Engineering and Physical Sciences Research Council, and the British Antarctic Survey. On this visit, the aim is to test the effectiveness of their drill technology for a new, more terrestrial purpose. Samples of bedrock, from several hundred metres under the ice, will be recovered and shipped back to the UK for analysis.

The university explained: “Here, scientists will measure the build-up of radioactive isotopes in the rock, the accumulation of which is governed by exposure to sunlight.”

The isotopes’ relative abundance can be used as a kind of “rock clock”, allowing researchers to determine how long ago the rock was covered by ice sheet, and therefore when – and how often – the ice has receded in the past.

Dr Patrick Harkness of the School of Engineering at Glasgow University is leading the team of engineers which developed the drill.

He said: “We’ve worked closely with the British Antarctic Survey in the past to test our Martian drill and we’re really excited to be working with them again this winter. We’re hoping to get a sample of bedrock out from underneath the Antarctic ice sheet and return it to the UK for analysis. When we do that we’ll be able to determine how long it’s been since that rock last saw the sun and that information will allow us to recreate the advance and withdrawal of the ice sheets, which gives us much greater information about the coming and going of ice ages.

“That could allow us to validate our climate models with much greater confidence and make better decisions about environmental matters.”