Glacier shrinkage driving global changes in downstream systems

Milner, Alexander M.; Khamis, Kieran; Battin, Tom J.; Brittain, John E.; Barrand, Nicholas E.; Füreder, Leopold; Cauvy‐Fraunié, Sophie; Gíslason, Gísli Már; Jacobsen, Dean; Hannah, David M.; Hodson, Andrew J.; Hood, Eran; Lencioni, Valeria; Ólafsson, Jón S.; Robinson, Christopher T.; Tranter, Martyn; Brown, Lee E.

doi:10.1073/pnas.1619807114

Cited by 413 publications

(375 citation statements)

References 118 publications

(138 reference statements)

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“…DOC yield during autumn and winter contributed on average 8 ± 5% and 9 ± 8% to the annual DOC yield from glacierized and non‐glacierized catchments. We suggest that this is attributable to the DOC poor groundwater predominantly feeding high‐alpine streams during these periods (e.g., Milner et al, ).…”

Section: Resultsmentioning

confidence: 99%

Alpine Glacier Shrinkage Drives Shift in Dissolved Organic Carbon Export From Quasi‐Chemostasis to Transport Limitation

Canadell

Escoffier

Ulseth

et al. 2019

Geophysical Research Letters

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The export of dissolved organic carbon (DOC) from catchments is considered as an important energy flux through streams and a major connection between terrestrial and aquatic systems. However, the impact that predicted hydrological changes due to glacier retreat and reduction in snow cover changes will have on DOC export from high‐mountain streams remains unclear. In this study, we measured daily runoff and DOC yield during 1 year in Alpine streams draining catchments with different levels of glacier coverage. DOC yield showed a varied response to runoff across the catchments and varied seasonally as a function of the degree of glaciation and vegetation cover. Using space‐for‐time substitution, our results indicate that the controls on DOC yield from Alpine catchments change from chemostasis to transport limitation as glaciers shrink.

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Section: Resultsmentioning

confidence: 99%

Alpine Glacier Shrinkage Drives Shift in Dissolved Organic Carbon Export From Quasi‐Chemostasis to Transport Limitation

Canadell

Escoffier

Ulseth

et al. 2019

Geophysical Research Letters

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“…Alpine headwaters are of importance for downstream aquatic networks by providing multiple ecosystem services, including water, nutrients, organic matter or invertebrate prey for higher trophic levels (Milner et al., ). The heterogeneity of alpine streams is also vital for the biodiversity of invertebrates (Finn, Bonada, Múrria, & Hughes, ) and bacteria (Besemer et al., ).…”

Section: Introductionmentioning

confidence: 99%

“…The heterogeneity of alpine streams is also vital for the biodiversity of invertebrates (Finn, Bonada, Múrria, & Hughes, ) and bacteria (Besemer et al., ). However, glaciers continue to retreat in alpine environments almost worldwide as a consequence of human‐induced warming (IPCC, ), leading to alterations of the physical conditions in alpine glacier‐fed stream ecosystems (e.g., altered water temperature, suspended sediment concentration and electrical conductivity) (Milner, Brown, & Hannah, ; Milner et al., ). These modification of freshwater habitats seem to occur accelerated and more obvious in the alpine life zone compared to lower altitudes and will increase over time as glaciers retreat (Zemp, Hoelzle, & Haeberli, ).…”

Section: Introductionmentioning

confidence: 99%

When the going gets tough, the tough get going: The enigma of survival strategies in harsh glacial stream environments

Niedrist

Füreder

2018

Freshwater Biology

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Abstract1. Glacier retreat is a key component of environmental change in alpine environments, leading to significant changes in physico-chemical characteristics and biological communities in glacier-fed rivers. While the overall effects of the environment on community structure of invertebrates are largely understood, its influence on functional strategies such as feeding habits of same species are not. 2.The aquatic larvae of the species-rich family Chironomidae, or nonbiting midges, are the first invertebrates colonising alpine headwaters, and the first macroinvertebrate consumers in these harsh environments. Species composition in the two subfamilies, Diamesinae and Orthocladiinae, is diverse and is strongly affected by the changing habitat conditions upon glacier retreat. Here, we show that Diamesinae have extremely flexible feeding strategies that explain their abundance, high body-mass and predominance in glacier-fed streams.3. Along a multifactorial ecological gradient from benign to harsh, based on water temperature, sediment transport and degree of glacial influence, Diamesinae expanded their trophic niche area and covered more trophic levels when conditions harshened. In contrast, niche areas of Orthocladiinae remained small and were not related to this gradient. In Diamesinae, mean body-mass increased with harsher environmental conditions, but no such effects were found in Orthocladiinae. 4.As facultative predators and able to feed on diverse food sources, Diamesinae have evolved survival mechanisms that allow them to thrive and successfully reproduce in glacier-fed streams, which likely explains their predominance in these habitats. 5.Climate change-induced glacier retreat affects the global water balance, with many downstream effects, including on irrigation and domestic use, and our study deepens our understanding of its effects on animals that depend on glacier-melt. K E Y W O R D Sglacial streams, niche breadth, omnivory, stable isotopes, trophic ecology (Milner et al., 2017). The heterogeneity of alpine streams is also vital for the biodiversity of invertebrates (Finn, Bonada, M urria, & Hughes, 2011) and bacteria . However, glaciers continue to retreat in alpine environments almost worldwide as a consequence of human-induced warming (IPCC, 2014), leading to alterations of the physical conditions in alpine glacier-fed stream ecosystems (e.g., altered water temperature, suspended sediment concentration and electrical conductivity) (Milner, Brown, & Hannah, 2009;Milner et al., 2017). These modification of freshwater habitats seem to occur accelerated and more obvious in the alpine life zone compared to lower altitudes and will increase over time as glaciers retreat (Zemp, Hoelzle, & Haeberli, 2009). Currently, biodiversity losses of adapted 'glacial species' and shifts of species (mainly invertebrates) in alpine stream ecosystems around the world are expected (Brown, Hannah, & Milner, 2007;Cauvy-Frauni e et al., 2016;F€ ureder, 2007, 2012Jacobsen, Milner, Brown, & Dangles, 2012). Benthic inverteb...

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“…The primary hydrological impact of glaciers on downstream river systems is to modulate the timing and seasonality of hydrological fluxes (Röthlisberger & Lang, ). A shift to deglacial conditions leads to marked changes in the seasonality of river flow (e.g., a shift of the hydrograph to an earlier peak flow in spring months) and the amount of annual glacier run‐off (Bliss, Hock, & Radić, ; Milner et al, ). Current trends in annual glacial run‐off differ among world regions and glacier hypsometry, but there is a consensus on the typical sequence of meltwalter changes during catchment deglaciation (Bliss et al, ): At the beginning of deglaciation, when the glacier is still sufficiently voluminous, the glacial meltwater tends to increase for a period lasting several decades, before decreasing when the ice stock runs out (Braun, Weber, & Shulz, ; Huss, Farinotti, Bauder, & Funk, ; Jansson, Hock, & Schneider, ; Marren, ).…”

Section: Introductionmentioning

confidence: 99%

Incision and aggradation in proglacial rivers: Post‐Little Ice Age long‐profile adjustments of Southern Iceland outwash plains

et al. 2018

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The retreat of glaciers in response to climate warming leads to substantial changes in meltwater and sediment yield. Glacial shrinkage also induces the emergence and growth of proglacial margin landforms, which strongly affect water and sedimentary transfers from the glacier to the outwash plains. On a decadal timescale, field observations show that outwash plains of retreating glaciers typically exhibit proximal incision, which decreases in magnitude downstream and stops at an inflection point where aggradation begins. Nevertheless, there is a lack of knowledge about the rates and magnitude of this fluvial adjustment and the effects of the proglacial margin configuration on the temperance or the aggravation of this fluvial adjustment to glacier retreat. This paper investigates the proglacial rivers of 14 retreating glaciers in south‐east Iceland over a post‐Little Ice Age timescale, combining fluvial deposits mapping, lichenometric dating, and long‐profile measurements of proglacial fluvial terraces. Our results demonstrate that (a) proximal incision, associated with distal aggradation and downstream migration of the inflection point, is the dominant pattern of proglacial river response to post‐Little Ice Age glacier retreat in Iceland; (b) estimated mean rates of downstream migration of the inflection point range between 5 and 46 m·a−1; and (c) the downstream migration rate of the inflection point is positively correlated with the proportion of proglacial lakes within the glacier foreland. These findings suggest that proglacial margins dominated by proglacial lakes intensify the rates of proximal incision and inflection point migration.

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Glacier shrinkage driving global changes in downstream systems

Cited by 413 publications

References 118 publications

Alpine Glacier Shrinkage Drives Shift in Dissolved Organic Carbon Export From Quasi‐Chemostasis to Transport Limitation

Alpine Glacier Shrinkage Drives Shift in Dissolved Organic Carbon Export From Quasi‐Chemostasis to Transport Limitation

When the going gets tough, the tough get going: The enigma of survival strategies in harsh glacial stream environments

Incision and aggradation in proglacial rivers: Post‐Little Ice Age long‐profile adjustments of Southern Iceland outwash plains

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