Glacier retreat impacts alpine river habitats, leaving biodiversity poorly protected

Glacier retreat impacts alpine river habitats, leaving biodiversity poorly protected

Temperatures are rising more rapidly in Alpine regions than the global average. Strongly location-specific, alpine biodiversity is particularly vulnerable to climate change because the mountain topography and weather conditions restrict opportunities for species to migrate towards the poles. It is therefore expected that the populations of alpine species will instead respond by shifting their ranges to higher elevations. By coupling models of future ice extent, glacial influence on downstream river habitats, and species ecological niches, an international team of researchers has developed a new method to identify potential future refugia for cold-adapted aquatic species. This new approach can now be used to predict future alpine biodiversity and ensure that actions relating to the adaptation of protected species offer maximum conservation potential.

Methods

Projections of river invertebrate distributions were developed for the period 2020-2100 at 10-year intervals for all glaciated subcatchments in the European Alps above 2,000 m, divided into 10x10 m river ‘segments’.

These projections were driven by a glacial influence model that calculates the proportion of glacial ice cover in each river segment’s upstream catchment. Future glacier extent was predicted using the Global Glacier Evolution Model. Projections for 15 species were then developed using species distribution models by integrating 656 biological samples with a set of river environmental parameters comprising glacial influence and hydrological, hydraulic and hydrochemical characteristics.

Key findings

Glacial influence on river ecosystems is projected to diminish to the end of the 21st century in all river basins in the Alps.

In 2100, many of the most suitable areas for glacial cold-water invertebrates will lie outside current protected area networks. This raises concerns over conservation, because locations where glaciers are still in existence in 2100 may also be priority areas for human activities such as hydropower and skiing. More intensive monitoring of alpine river biodiversity is urgently needed so that the distributions of a wider range of aquatic species can be modelled and used to inform conservation decisions.

These advances in predictive capability can benefit the study of other mountain ranges, where local-scale predictions are currently available for only a small number of species.

 

The work described here was carried out by scientists from the UK, Austria, France, Italy and Switzerland, building on multiple studies dating back to the 1990s.

The full report is available online:
https://www.nature.com/articles/s41559-023-02061-5

For more information, contact:  l.brown@leeds.ac.uk

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Modification date : 07 July 2023 | Publication date : 06 July 2023 | Redactor : com