Sensor technology comes in from the cold
The response of glaciers to global warming is an important element in understanding climate change, involving sea-level change and changes to the thermohaline circulation in the North Atlantic. To predict changes in the future it is vital to understand the behaviour of the sub-glacial bed. But reliable data is a prerequisite.
In the first investigation of its kind in the world the University of Southampton’s interdisciplinary GLACSWEB team is recording glacier behaviour through a network of sensor probes installed directly into the glacier.
The GLACSWEB project is aiming to understand glacier dynamics and climatic change, as well as making advances in pervasive sensor networks. The GLACSWEB team, led by Dr Jane Hart, Dr Kirk Martinez and Dr Royan Ong, installed the sensor network last summer at the Briksdalsbreen glacier in Norway. This glacier advanced dramatically in the 1990s as a result of climate change, and the team will return to Briksdalsbreen this summer to deploy a second type of probe which is based on new research developments.
’The aim of the Glacsweb project is to study climate change through its effects on glaciers,’ said Kirk Martinez of the School of Electronics and Computer Science.
’We are using “Subglacial Probes” beneath a glacier, communicating to the surface via radio links. They contain various sensors and their position and orientation is sensed by the surface system. This is the first time wireless probes have been put inside glaciers and it involves many challenges. The systems must feed data back to a server in the UK and contend with communication loss, power loss, noise and bad weather!’
The probes are installed in the sedimentary base of the glacier, about 60 metres under the surface through the use of a powerful hot water drill. They record temperature, pressure, speed and movement of the ice, and more importantly of the sediments at its base.
The probes emit signals carrying the data, which are relayed back to a base station on the glacier surface by radio communications, and then transmitted to Southampton by mobile phone. The data is available to researchers at httpwww.glacsweb.org.
The project is part of the DTI-funded Next Wave Technologies and Markets programme. It aims to ensure that UK business is structured and equipped to exploit new information and communications technologies and products that enable intelligent functionality to be embedded into devices that will eventually become an integral part of life. The ENVISENSE centre at Southampton hosts projects in the areas of larger-scale reconfigurable pervasive computing, such as environmental projects.
’A combination of technologies has made sensor webs possible,’ says Kirk Martinez. ’These will eventually be spread around the world and will give us a clearer picture of exactly how we are changing our environment. In order to make successful sensor webs issues such as: communications, low-power, robustness and adaptability have to be solved through a combination of mechanical engineering, electronics, computer science and environmental science.
’Our sensors are housed in “electronic pebbles” which will behave as part of the glacier, enabling us to get the clearest picture possible of what is happening deep below the surface.’
The project is funded by the Royal Society and the Department of Trade and Industry, and the GLACSWEB team includes Sue Way, Dr Joe Stefanov, Al Riddoch, Chris Havill and Reuben Wilcox.
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Earth Sciences (also referred to as Geosciences), which deals with basic issues surrounding our planet, plays a vital role in the area of energy and raw materials supply.
Earth Sciences comprises subjects such as geology, geography, geological informatics, paleontology, mineralogy, petrography, crystallography, geophysics, geodesy, glaciology, cartography, photogrammetry, meteorology and seismology, early-warning systems, earthquake research and polar research.
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