Biology:Exposed riverine sediments

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Short description: Sediments deposited by streams exposed when water level falls

Exposed riverine sediments, or ERS, are composed of silt, sand and gravel deposited by streams but exposed as water level falls.

Other terms for ERS include river shingle, point bars, berms and shoals and they are most common in actively meandering and braided rivers.

River2.jpg Intermittent Medano Creek Seeps through Desert Sands.jpg Namoi-River-sand-bank.jpg
An exposed shoal. An intermittent braided water course showing fluvial deposits. A sand bar and the opposite bank.
Unspecified river, Bangladesh Medano Creek, Great Sand Dunes National Park and Preserve, Colorado, United States Namoi River, New South Wales, Australia

Adrian Fowles of the Countryside Council for Wales and members of the UK Environment Agency in 1993 coined ‘exposed riverine sediments’ as a term to describe the full scope of these related microhabitats. Their aim in-so-doing was to reduce confusion and pull together the conservation and scientific investigation of these habitats. Bates and Sadler (2005)[1] have since further defined exposed riverine sediments as:

Exposed, within channel, fluvially deposited sediments (gravels, sands and silts) that lack continuous vegetation cover, whose vertical distribution lies between the levels of bankfull and the typical baseflow of the river.

Therefore, eroding river banks are ERS because they are usually composed of fluvially deposited sediment. Whereas areas of the stream bed and over-bank deposits are not ERS because they are only exposed when water levels are unusually low and are more elevated than the bankfull level respectively.

The term ERS is slowly becoming more common and has now been used in a large number of published papers, for example:

ERS habitat

A casual glance at ERS would suggest a harsh, relatively un-inhabited habitat with little value. However, ERS habitats are of considerable conservation importance because of their high species diversity, high degree of species specialisation, and large number of rare and endangered species. ERS are of substantial importance for a small number of vertebrate species, such as the rare little ringed plover, but for the most part their value lies in their invertebrate fauna.

The United Kingdom Biodiversity Action Plan, for example, lists eight species of beetle:

and two species of stilleto fly:

that are associated with ERS.

ERS dynamics

ERS rely on a continued supply of sediment from upstream, and periodic disturbances from flooding to prevent ecological succession to more vegetated riparian habitat.

Threats to ERS

Many of the threats to ERS act to:

  1. reduce the supply of sediment by interrupting its downstream transfer:
    1. dam construction
    2. construction aggregate extraction
    3. reducing river erosion (river engineering and dam construction)
  2. reduce the frequency and magnitude of floods (dam construction) (Plachter and Reich 1998,[2] Sadler et al. 2005,[1] Tockner et al. 2006[3]).

Other threats operate over smaller scales, such as livestock trampling.[4][5]

References

  1. 1.0 1.1 Bates, A.J., and J.P. Sadler. 2005. The ecology and conservation of beetles associated with exposed riverine sediments. CCW Contract Science Report No.688.
  2. Plachter, H. and M. Reich. 1998. The significance of disturbance for populations and ecosystems in natural floodplains. In Proceedings of the International Symposium on River Reastoration, 26–27 May, Tokyo, Japan.
  3. *Tockner, K., A. Paetzold, U. Karaus, C. Claret, and J. Zettel. 2006. Ecology of braided rivers. Pages 339-359 in G. Sambrook-Smith, J. Best, S. Lane, and G. E. Petts (editors) Braided Rivers. IAS Special Publication 36, Blackwell Publishing, Oxford.
  4. Bates, A.J., J.P. Sadler, and A.P. Fowles. 2007. Livestock trampling reduces the conservation value of beetle communities on high quality exposed riverine sediments. Biodiversity & Conservation 16:1491-1509.
  5. Bates et al. 2007

Further general reference material

  • Bates, A.J., J.P. Sadler, and A.P. Fowles. 2006. Condition-dependent dispersal of a patchily distributed riparian ground beetle in response to disturbance. Oecologia 150:50-60.
  • Eyre, M. D., M. L. Luff, and D. A. Phillips. 2001. The ground beetles (Coleoptera: Carabidae) of exposed riverine sediments in Scotland and northern England. Biodiversity & Conservation 10:403-426.
  • Looy, K. V., S. Vanacker, H. Jochems, G. de Blust, and Dufrêne. 2005. Ground beetle habitat templets and riverbank integrity. River Research & Applications 21:1133-1146.
  • Petts, G. E., A. M. Gurnell, A. J. Gerrard, D. M. Hannah, B. Hansford, I. Morrissey, P. J. Edwards, J. Kollmann, J. V. Ward, K. Tockner, and B. P. G. Smith. 2000. Longitudinal variations in exposed riverine sediments: a context for the ecology of the Fiume Tagliamento, Italy. Aquatic Conservation: Marine and Freshwater Ecosystems 10:249-266.
  • Sadler, J. P., D. Bell, and A. P. Fowles. 2004. The hydroecological controls and conservation value of beetles on exposed riverine sediments in England and Wales. Biological Conservation 118:41-56.