Tiny organisms could change the face of coastal science
New scientific research published in the journal Nature Communications, led by researchers at 麻豆传媒高清版 in collaboration with scientists from the National Oceanography Centre Liverpool and the Universities of St. Andrews, Hull, Leeds and Plymouth, has discovered that 鈥榮ticky鈥 sugars produced by micro-organisms have a remarkably large effect on the movement of sand and mud in aquatic environments.
鈥淭he effect of large amounts of extracellular polymeric substances (EPS), the sticky sugars secreted by micro-organisms in sand and mud found on the floor of rivers and seas, is well known in the scientific literature: EPS stabilises the bed by forming a 鈥榖iofilm鈥 that is strong enough to resist erosion. However, our research has shown that even far more modest amounts of evenly distributed EPS are enough to dramatically slow down the growth of sediment ripples and other bedform types. Properly representing the occurrence and growth of sediment ripples is vital to the accurate prediction of the movement of sand and mud in rivers, estuaries and oceans in computer models. Our research implies that such models could do better in making predictions on a day-to-day basis. These model results are crucial to government agencies charged with mitigating the effects of coastal storms and river floods鈥 explains lead author Dr. Jonathan Malarkey, oceanographer from 麻豆传媒高清版鈥檚 School of Ocean Sciences.
Dr. Malarkey adds: 鈥漈he effect of EPS is much stronger than the effect of clays on ripple development. We believe that this is down to the nature of the binding, since the EPS is far more effective at inhibiting the sand grains from moving independently鈥.
This research is part of the Natural Environment Research Council鈥檚 million pound COHBED project, which involves experiments undertaken at hydraulics laboratories at the Universities of Bangor and Hull and fieldwork undertaken in the Dee Estuary. 鈥淥ne of the main reasons for setting up this research project is that our knowledge of bedform behaviour is limited almost entirely to pure sand, despite most aquatic environments being mixtures of sand, clay and EPS. In order to fill this gap in knowledge the project has required an innovative collaboration between biologists, oceanographers and sedimentologists鈥, explains Dr. Jaco Baas, senior lecturer at the School of Ocean Sciences, principle investigator of the COHBED project, and recognised expert on bedform research.
Malarkey, J., J.H. Baas, J.A. Hope, R.J. Aspden, D.R. Parsons, J. Peakall, D.M. Paterson, R.J. Schindler, L. Ye, I.D. Lichtman, S.J. Bass, A.G. Davies, A.J. Manning and P.D. Thorne, 2015. The pervasive role of biological cohesion in bedform development. Nature Communications, 6:6257, doi: 10.1038/ncomms7257.
Publication date: 6 February 2015