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Titel |
Meso-scale habitat simulation for the conservation of the endangered crayfish Austropotamobious pallipes complex in Italy |
VerfasserIn |
Paolo Vezza, Daniela Ghia, Gianluca Fea, Michele Spairani, Claudio Comoglio, Monica Di Francesco |
Konferenz |
EGU General Assembly 2014
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Medientyp |
Artikel
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Sprache |
Englisch
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Digitales Dokument |
PDF |
Erschienen |
In: GRA - Volume 16 (2014) |
Datensatznummer |
250097849
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Publikation (Nr.) |
EGU/EGU2014-13466.pdf |
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Zusammenfassung |
Crayfish are the largest mobile freshwater invertebrates, being often considered key species in
the aquatic ecosystems of small streams and creeks in Italy. Specifically, Austropotamobius
pallipes complex is currently classified as an endangered species, and Italian local
populations significantly decreased over the last decades due to habitat modifications and
introduction of alien species. Information on A. pallipes ecological requirements is then
needed to quantify habitat loss, to simulate restoration scenarios and to implement effective
conservation measures. In this work we analyze mesohabitat use of A. pallipes in
reference streams and creeks located in the Italian pre-Alps (Lombardia region)
and in the mountainous areas of the Gran Sasso e monti della Laga National Park
(Abruzzo region). Data from seven morphologically different streams were used
to calibrate and validate habitat models for the endangered crayfish A. pallipes
complex. The Random Forests algorithm was used to identify the best and the most
parsimonious habitat model, to define the lowest number of variables to be surveyed
in future model applications. The obtained habitat models were then applied to
each stream in order to classify each mesohabitat into suitability categories, and to
develop habitat-flow rating curves. Finally, habitat time series analysis was used to
define detailed schemes of flow management for individual water diversions in
order to represent how physical habitat changes through time and to identify stress
conditions for A. pallipes created by persistent limitation in habitat availability.
Results indicated that fine substrate (as proportion of gravel and sand), shallow
water depth and cover (as presence of boulders, woody debris and undercut banks)
revealed to be significant variables for the occurrence of A. pallipes. Habitat models,
performing well in both model calibration and validation phases (accuracy ranging from
71% to 87%), are regarded as valuable tools being transferable among different
streams with different morphologies. Establishing flow recommendations for small
streams that may not have available ecological and flow data is important, and this
methodology provides a tool where few are currently available. As such, it can be
used for development of regional rules for the conservation of the endangered A.
pallipes complex, as well as for defining more site specific flow management criteria. |
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