Glacial melt content of water use in the tropical Andes

Buytaert, Wouter; Moulds, Simon; Acosta, Luis Eduardo; Bièvre, Bert De; Olmos, Carlos Francisco García; Villacís, Marcos; Tovar, Carolina; Verbist, Koen

doi:10.1088/1748-9326/aa926c

Cited by 91 publications

(58 citation statements)

References 27 publications

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“…Rapid climate change is resulting in dramatic glacier mass loss in Peru, Bolivia, and other Andean countries (Rabatel, Francou, Soruco, Gomez, & many, 2013;Vuille et al, 2018). The potential long-term reduction in stream flow is a significant issue where dense human populations and agriculture rely on water runoff from the highlands (Bradley, Vuille, Diaz, & Vergara, 2006;Buytaert et al, 2017;Buytaert, Celleri, & Timbe, 2009;Engel, Skrzypek, Chuman, & Sefrna, 2014;Mark et al, 2017;Rabatel et al, 2013;Soruco et al, 2015).…”

mentioning

confidence: 99%

Drivers of peatland water table dynamics in the central Andes, Bolivia and Peru

Cooper

Sueltenfuss

Oyague

et al. 2019

Hydrological Processes

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Cushion plant dominated peatlands are key ecosystems in tropical alpine regions of the Andes in South America. The cushion plants have formed peat bodies over thousands of years that fill many valley bottoms, and the forage produced by the plants is critical for native and nonnative domesticated mammals. The sources and flow paths of water supporting these peatlands remain largely unknown. Some studies have suggested that glacier meltwater streams support some peatlands, and that the ongoing loss of glaciers and their meltwaters could lead to the loss or diminishment of peatlands. We analysed the hydrologic regime of 10 peatlands in four mountain regions of Bolivia and Peru using groundwater monitoring. Groundwater levels in peatlands were relatively stable and within 20 cm of the ground surface during the rainy season, and many sites had water tables 40–90 cm below the ground surface in the dry season. Topographic and groundwater elevations in the peatlands demonstrated that the water source of all 10 peatlands was hillslope groundwater flowing from lateral moraines, talus, colluvium, or bedrock aquifers into the peatlands. There was little to no input from streams, whether derived from glacier melt or other sources, and glacier melt could not have recharged the hillslope aquifers supporting peatlands. We measured the stable water isotopes in water samples taken during different seasons, distributed throughout the catchments, and the values are consistent with this interpretation. Our findings indicate that peatlands in the study region are recharged by hillslope groundwater discharge rather than stream water and may not be as vulnerable to glacial decline as other studies have indicated. However, both glaciers and peatlands are susceptible to changing thermal and precipitation regimes that could affect the persistence of peatlands.

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mentioning

confidence: 99%

Drivers of peatland water table dynamics in the central Andes, Bolivia and Peru

Cooper

Sueltenfuss

Oyague

et al. 2019

Hydrological Processes

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“…A few recent studies mentioned that the shrinkage rate of glaciers in the northeastern slopes, which is important in the hydrology of the Amazon Basin, is greater than the observed shrinkage rates in the southwestern slopes (Veettil & Souza, 2017;Veettil et al, 2017a;2017b;2017c). However, it should be noted that the relative contribution of glaciers to the streamflow towards the humid slopes of the Amazon Basin tends to decrease due to the high contributions of non-glacial lateral runoff by orographic precipitation (Bookhagen & Strecker, 2008;Buytaert et al, 2017). The main source of precipitation (snow) for the tropical Andean glaciers is the atmospheric circulation from the Amazon Basin, whose source is the tropical Atlantic Ocean.…”

Section: Introductionmentioning

confidence: 99%

The influence of ENSO and PDO on tropical Andean glaciers and their impact on the hydrology of the Amazon Basin

Rocha

Veettil

Grondona

et al. 2019

Singap J Trop Geogr

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Recent decades, particularly since the late 1970s, have witnessed a rapid retreat of glaciers in the tropical Andes. We compiled the changes in glacier surfaces along the eastern cordilleras of the tropical Andes of Peru and Bolivia since the early 1980s from the literature. Water levels from two Brazilian river basins in the Amazon basin (one (Madeira River) glacially fed by meltwater from the Andes and the other (Envira River) non‐glacially fed), were analysed for a 30‐year period between 1985−2014. Furthermore, precipitation data near these two basins were also analysed in order to understand the differential contributions of glacier melting and rainfall. Variations in the water levels from the glacially fed Madeira River showed that some years were associated with higher water levels even when the precipitation remained low during the corresponding season (May‐October). This observation was common when El Niño events occurred during the positive phase of Pacific Decadal Oscillation (PDO). Water levels in glacier‐fed Madeira River were slightly higher during the periods where El Niño and warm PDO co‐occurred. On the other hand, water levels in the Envira River were precipitation dependent; water levels were higher when the rainfall was high.

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“…Understanding how highaltitude ecosystems respond to changing climate is a matter of urgency, because not only do these regions act as "water towers" supplying water to huge populations downstream (Messerli et al, 2004;Buytaert et al, 2017) but they also provide habitats to many iconic species that are classified by the IUCN (International Union for Conservation of Nature) as being vulnerable (Fan et al, 2014). Alpine freshwaters have multiple ecosystem functions (Messerli et al, 2004;Buytaert et al, 2017) and provide many ecosystem services such as freshwater regulation and habitat provision (Grêt-Regamey et al, 2012). Their multifunctionality depends on local species communities and how species vary through space and time (beta diversity) and are driven by ecosystem properties, environmental gradients, and species interactions (Korhonen et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Neoglacial trends in diatom dynamics from a small alpine lake in the Qinling mountains of central China

et al. 2020

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Abstract. During the latter stages of the Holocene, and prior to anthropogenic global warming, the Earth underwent a period of cooling called the neoglacial. The neoglacial is associated with declining summer insolation and changes to Earth's surface albedo. Although impacts varied globally, in China the neoglacial was generally associated with a cooler climate and an attenuated Asian summer monsoon. Few studies in central China, however, have explored the impact of neoglacial cooling on freshwater diversity, especially in alpine regions. Here we take a palaeolimnological approach to characterise multi-decadal variability in diatom community composition, ecological guilds, and compositional turnover over the past 3500 years from the alpine Yuhuang Chi lake on Mount Taibai in the Qinling mountains. Diatoms in the high-profile guild dominate much of the record from 3500 to 615 cal BP, which suggests that few nutrients in the lake were limiting overall, and disturbance and herbivory were likely low. After 615 cal BP, low-profile and planktic guild diatoms increase, suggesting greater turbulence in the lake, alongside a decline in available nutrients. Diatom turnover highlights periods in the lake history when deterministic processes structured diatom communities. For example, an abrupt decline in turnover is coincident with the shift from high- to low-profile diatoms at 615 cal BP, and this is likely due to the onset of the Little Ice Age in the region. We suggest that Yuhuang Chi lake became more shallow during peak regional aridity, which led to the short-lived community restructuring observed in the record.

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Glacial melt content of water use in the tropical Andes

Cited by 91 publications

References 27 publications

Drivers of peatland water table dynamics in the central Andes, Bolivia and Peru

Drivers of peatland water table dynamics in the central Andes, Bolivia and Peru

The influence of ENSO and PDO on tropical Andean glaciers and their impact on the hydrology of the Amazon Basin

Neoglacial trends in diatom dynamics from a small alpine lake in the Qinling mountains of central China

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