After the peak water: the increasing influence of rock glaciers on alpine river systems

Brighenti, Stefano; Tolotti, Monica; Bruno, Maria Cristina; Engel, Michael H.; Wharton, Geraldene; Cerasino, Leonardo; Mair, Volkmar; Bertoldi, Walter

doi:10.1002/hyp.13533

Cited by 28 publications

(35 citation statements)

References 68 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, unlike nearby streams and an emphasis on temperature, the chemical composition of high mountain lakes has received considerable attention. High concentrations of ions (including nitrates, calcium, magnesium, and sulphates) and heavy metals, often exceeding drinking water limits, are common in rock glacier outflows (Williams et al 2007;Colombo et al 2018;Brighenti et al 2019b). High metal concentrations promote sublethal effects on lake biodiversity, as shown by a high prevalence of mouth deformities in the midge Pseudodiamesa nivosa in a rock glacial lake of the Italian Alps (Ilyashuk et al 2014).…”

Section: Lakes and Pondsmentioning

confidence: 99%

“…Current knowledge is also based almost solely on active rock glaciers, with little known for other CRLs, whose outflow water chemistry appears to be less harsh than rock glaciers (Brighenti et al 2019b).…”

Section: Lakes and Pondsmentioning

confidence: 99%

“…Quantifying thermal regimes, and biological and chemical settings of CRLs requires field-based surveys, ideally paired with longer term monitoring. Monitoring of water temperature may be a particularly inexpensive strategy for identifying CRL-based refugia, especially when combined with satellite imagery showing a lack of visible ice or snow upstream (Hotaling et al 2019;Brighenti et al 2019b). When considering the long-term viability of CRL-influenced climate refugia, the distribution and type of CRL is important.…”

Section: Looking To the Futurementioning

confidence: 99%

See 2 more Smart Citations

Rock glaciers and related cold rocky landforms: overlooked climate refugia for mountain biodiversity

Brighenti¹,

Hotaling²,

Finn³

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

Mountains are global biodiversity hotspots where cold environments and their associated ecological communities are expected to shift upward and disappear as climates warm. Considerable research attention has been focused on the ecological effects of alpine glacier and snowfield recession and warming temperatures in aquatic and terrestrial habitats. However, little attention has been devoted to identifying climate refugia in mountain ecosystems where present-day environmental conditions will be maintained, at least in the near-term, as other habitats change. Around the world, montane communities of microbes, animals, and plants live on, adjacent to, and downstream of rock glaciers and related cold rocky landforms (CRL). These geomorphological features have been overlooked in the ecological literature despite being extremely common in mountain ranges worldwide with a propensity to support cold, stable terrestrial and aquatic habitats. Due to the insulating nature of debris cover and their internal ventilation patterns, CRLs are less responsive to atmospheric warming than alpine glaciers and snowfields. Here, we argue that CRLs represent global climate refugia for mountain biodiversity, offer guidelines for incorporating CRLs into management practice, and identify key areas where future research is needed.

show abstract

Section: Lakes and Pondsmentioning

confidence: 99%

Section: Lakes and Pondsmentioning

confidence: 99%

Section: Looking To the Futurementioning

confidence: 99%

See 1 more Smart Citation

Rock glaciers and related cold rocky landforms: overlooked climate refugia for mountain biodiversity

Brighenti¹,

Hotaling²,

Finn³

et al. 2020

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

“…Outflows from rock glaciers, i.e. creeping rocky debris containing permafrost ice (Jones et al., 2019), have been recently proposed as a particular habitat (Brighenti, Tolotti, Bruno, Engel, et al., 2019; Hotaling et al., 2019), given the unique environmental conditions that include clear (<5 NTU) and cold (<1.5°C) waters, stable channels, and high concentrations of major ions and trace elements (Colombo et al., 2018). Despite contributing to the hydrological diversity of alpine river networks, rock glacial streams have hitherto received little attention from ecological research on benthic invertebrates, when compared to glacier‐fed (kryal) and groundwater‐fed (krenal) systems (Brighenti, Tolotti, Bruno, Wharton, et al., 2019; Tronstad et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…Finn et al., 2010; Hieber et al., 2005; Milner et al., 2001; Milner & Petts, 1994), little is known on the ecological relevance of other paraglacial features (i.e. occurring following glacier retreat) such as moraines and taluses, although these landforms have been shown to decrease the glacial influence along the glacier‐fed streams (Brighenti, Tolotti, Bruno, Engel, et al., 2019). The pattern of glacial influence is also mediated by local conditions such as mesohabitat diversity and riffle‐pool prevalence, which influences the invertebrate communities and their functional traits over small spatial scales (Herbst et al., 2018).…”

Section: Introductionmentioning

confidence: 99%

Rock glaciers and paraglacial features influence stream invertebrates in a deglaciating Alpine area

et al. 2020

Self Cite

View full text Add to dashboard Cite

Climate change and progressive glacier loss are leading to rapid ecological shifts in alpine aquatic systems. Rock glaciers and paraglacial features such as proglacial lakes, moraines, and taluses can alter the gradients of glacial influence along alpine river networks, but the ecological responses are still understudied. We investigated benthic invertebrate communities of different stream types (upper kryal, lower kryal, glacio‐rhithral, krenal, and rock glacial) within a deglaciating area of the Italian Alps (Solda and Zay sub‐catchments). Alpha‐ (Shannon index and taxa richness) and β‐diversity (i.e. nestedness and turnover), production (abundance, biomass), average body mass of invertebrate taxa, and functional feeding groups were used to analyse the influence of habitat conditions on invertebrate communities in different microhabitats (mineral substrates, bryophytes, Hydrurus foetidus). We defined an index of habitat mildness based on water temperature, channel stability, turbidity, and organic detritus, to measure the difference in community metrics over a gradient of habitat amelioration, driven by the mixing of distinct stream types and their interactions with paraglacial features. While diversity proxies showed an asymptotic behaviour along the gradient, the quantitative metrics peaked at intermediate mildness. Peaks of invertebrate biomass/abundance were recorded at the glacio‐rhithral station below the talus. Highest average body mass occurred at Zay, specifically at the rock glacial stream, and at the lower kryal stations influenced by the lake/moraine and the rock glacier. The moraine outflow showed unexpected high biomass/abundance values of shredders and grazers, that were supported by a high epilithic production. Bryophytes acted as local scale multipliers of mildness as they stored more detritus, and hosted higher biomass/abundance of invertebrates and, in particular, of gatherer–collectors. Beta‐diversity, driven by the turnover component, was positively related to different habitat mildness of the sampling stations. Although influenced by distinct lentic/lotic conditions, rock glacial streams hosted several taxa typical of glacio‐rhithral and krenal stations, alongside large numbers of Diamesa (Chironomidae), a genus typical of kryal habitats. Under progressive deglaciation, rock glaciers and paraglacial features influence the invertebrate communities of alpine river networks. As they host a high number of taxa dwelling in non‐glacial locations, rock glacial streams may act as stepping stones facilitating invertebrate colonisation following glacier retreat. After glacier loss, rock glacial streams may represent climate refugia for cold adapted taxa and/or kryal specialists, because the slow thawing of their ice might sustain cold water conditions for a longer period of time.

show abstract

Contrasting physical and chemical conditions of two rock glacier springs

Brighenti

Engel

Tolotti

et al. 2021

Hydrological Processes

Self Cite

View full text Add to dashboard Cite

Rock glaciers are increasingly influencing the hydrology and water chemistry of Alpine catchments. During three consecutive summers (2017-2019), we monitored by recording probes and fortnightly/monthly field campaigns the physical and chemical conditions of two rock glacier springs (ZRG, SRG) in the Zay and Solda/Sulden catchments (Eastern Italian Alps). The springs have contrasting hydrological conditions with ZRG emerging with evident ponding (pond-like), and SRG being a typical high-elevation seep (stream-like). Water temperature was constantly low (mean 1.2 C, standard deviation 0.1 C) at both springs. Con-

show abstract

After the peak water: the increasing influence of rock glaciers on alpine river systems

Cited by 28 publications

References 68 publications

Rock glaciers and related cold rocky landforms: overlooked climate refugia for mountain biodiversity

Rock glaciers and related cold rocky landforms: overlooked climate refugia for mountain biodiversity

Rock glaciers and paraglacial features influence stream invertebrates in a deglaciating Alpine area

Contrasting physical and chemical conditions of two rock glacier springs

Contact Info

Product

Resources

About