Showing total 16 results

1. Sharp Increase of Extreme Turbidity Events Due To Deglaciation in the Subtropical Andes.

Author

Vergara, Iván, Garreaud, René, and Ayala, Álvaro

Subjects

GLACIAL melting, GLACIERS, TURBIDITY, SEDIMENT transport, WATERSHEDS, CLIMATE change, DRINKING water

Abstract

Climate change may affect sediment fluvial export from high mountain regions, leading to downstream environmental disruptions and direct impacts on human activities. In this paper, three decades (1990–2020) of turbidity measurements, along with climate and hydro‐glaciological variables, were used to investigate the interannual and interdecadal variability in the number of extreme turbidity events (ETE) in the glacierized Maipo River basin, located in the western subtropical Andes. ETE are defined as a sequence of days (most often 1 or 2) during which the daily maximum turbidity was in the 99% quantile of the entire study period. Some of these events compromised the drinking water provision for the city of Santiago, with more than 6 million inhabitants. ETE are more frequent during summer and are mostly associated with melt‐favourable conditions. The number of ETE tends to increase in summers with large glacier ice melt and low snowmelt (outside or over glaciers). Most notable, the mean annual number of ETE exhibits a 6‐fold increase in the last decade compared with the 1990–2010 period. After 2010, ETE also shifted their seasonal maximum from late spring to mid‐summer and their occurrence became strongly coupled with large ice melt rates. We hypothesize that such regime change was caused by an enhanced hydrological connectivity of subglacial sediment pools that increased the sensitivity of the sediment system to glacier melt. The latter is in line with recent research and is consistent with the ongoing glacier retreat due to strong regional warming and drying. Plain Language Summary: Climate change may affect sediment fluvial transport from high mountain regions, leading to environmental disruptions and direct impacts on human activities. In this paper, three decades (1990–2020) of river turbidity measurements to investigate how extreme turbidity events (ETE) have changed in the glacierized Maipo River basin, subtropical Andes. ETE are defined as a sequence of days (most often one or two) during which the turbidity was very high. Some of these events compromised the drinking water provision for the city of Santiago, with more than 6 million inhabitants. ETE are more frequent during summer and are mostly associated with melt‐favourable conditions. Most notable, the mean number of ETE exhibits a sharp increase in the last decade compared with the 1990–2010 period. After 2010, ETE also shifted their seasonal maximum from late spring to mid‐summer and their occurrence became strongly coupled with large ice melt rates. We hypothesize that such regime change was caused by meltwater that has reached subglacial sediments that used to be confined under the glacier ice. The latter is in line with recent research and is consistent with the ongoing glacier retreat as a consequence of intense regional warming and drying. Key Points: The interannual and interdecadal variability in the number of extreme turbidity events are analyzed in a glacierized basin of the AndesMost events are melt‐driven and their number increased by a factor of six during the last decade with respect to the 1990–2010 averageIt is hypothesized that the rise was due to a higher hydraulic connectivity in the subglacial system driven by regional warming and drying [ABSTRACT FROM AUTHOR]

Published

2022

2. Fast uplift in the southern Patagonian Andes due to long- and short-term deglaciation and the asthenospheric window underneath.

Author

Muller, Veleda A. P., Sternai, Pietro, and Sue, Christian

Subjects

GLOBAL Positioning System, LITTLE Ice Age, LAST Glacial Maximum, GLACIAL isostasy, GEODYNAMICS, GLACIAL melting

Abstract

An asthenospheric window underneath much of the South American continent increases the heat flow in the southern Patagonian Andes where glacial–interglacial cycles drive the building and melting of the Patagonian Icefields since the latest Miocene. The Last Glacial Maximum (LGM) was reached ∼26000 yr BP (years before present). Significant deglaciation onsets between 21 000 and 17 000 yr BP were subject to an acceleration since the Little Ice Age (LIA), which was ∼400 yr BP. Fast uplift rates of up to 41±3 mm yr -1 are measured by global navigation satellite system (GNSS) around the Southern Patagonian Icefield and are currently ascribed to post-LIA lithospheric rebound, but the possible longer-term post-LGM rebound is poorly constrained. These uplift rates, in addition, are 1 order of magnitude higher than those measured on other glaciated orogens (e.g. the European Alps), which raises questions about the role of the asthenospheric window in affecting the vertical surface displacement rates. Here, we perform geodynamic thermo-mechanical numerical modelling to estimate the surface uplift rates induced by post-LIA and post-LGM deglaciation, accounting for temperature-dependent rheologies and different thermal regimes in the asthenosphere. Our modelled maximum post-glacial rebound matches the observed uplift rate budget only when both post-LIA and post-LGM deglaciation are accounted for and only if a standard continental asthenospheric mantle potential temperature is increased by 150–200 °C. The asthenospheric window thus plays a key role in controlling the magnitude of presently observed uplift rates in the southern Patagonian Andes. [ABSTRACT FROM AUTHOR]

Published

2024

3. Coupling Sediment Transport Dynamics with Sediment and Discharge Sources in a Glacial Andean Basin.

Author

Carrillo, Ricardo and Mao, Luca

Subjects

SEDIMENT transport, ABLATION (Glaciology), FLUVIAL geomorphology, SUSPENDED sediments, BED load, GLACIAL melting

Abstract

Suspended and bedload transport dynamics on rivers draining glacierized basins depend on complex processes of runoff generation together with the degree of sediment connectivity and coupling at the basin scale. This paper presents a recent dataset of sediment transport in the Estero Morales, a 27 km2 glacier-fed basin in Chile where suspended sediment concentration (SSC) and bedload (BL) fluxes have been continuously monitored during two ablation seasons (2014–2015 and 2015–1016). The relationship between discharge and SSC depends on the origin of runoff, which is higher during glacier melting, although the hysteresis index reveals that sediment sources are closer to the outlet during snowmelt. As for suspended sediment transport, bedload availability and yield depend on the origin of runoff. Bedload yield and bedload transport efficiency are higher during the glacier melting period in the first ablations season due to a high coupling to the proglacial area after the snowmelt period. Instead, on the second ablation seasons the peak of bedload yield and bedload transport efficiency occur in the snowmelt period, due to a better coupling of the lower part of the basin caused by a longer permanency of snow. Differences in volumes of transported sediments between the two seasons reveal contrasting mechanisms in the coupling dynamic of the sediment cascade, due to progressive changes of type and location of the main sources of runoff and sediments in this glacierized basin. The paper highlights the importance of studying these trends, as with retreating glaciers basins are likely producing less sediments after the "peak flow", with long-term consequences on the ecology and geomorphology of rivers downstream. [ABSTRACT FROM AUTHOR]

Published

2020

4. Megalandslides and deglaciation: modelling of two case studies in the Central Andes.

Author

Sepúlveda, Sergio A., Tobar, Christian, Rosales, Vannesa, Ochoa-Cornejo, Felipe, and Lara, Marisol

Subjects

GLACIAL melting, LANDSLIDES, ROCK slopes, GREEN infrastructure, SHEAR (Mechanics)

Abstract

Large-volume rock slope failures are one of the main hazards in high mountain glaciated valleys, inducing severe damage to population and infrastructure, representing a high risk for society, ecosystems and infrastructure. The Andes Mountain Range is shaped by glacial activity and therefore by megalandslides due to changes in shear strength and deformation during periods of glaciation and deglaciation, which modify the slope stress state and, along with other processes, induce progressive damage in the rock mass, eventually leading to failure. The study focuses on validating the hypothesis that glacier unloading contributes to these types of landslides. The research numerically modelled the effects of glacier unloading on stress distribution and its potential impact on landslides, particularly using two Chilean cases: The 1987 Estero Parraguirre and the 2018 Yerba Loca rock slides. These models used the Universal Distinct Element Code, along with geological and geotechnical data from previous studies and field observations. The numerical results showed that the combination of shear stress changes due to glacial unloading and structural control from main discontinuities could cause landslides, with the deglaciation of glaciers potentially preparing the slope for catastrophic failure that may occur due to external climatic or tectonic triggers. The results suggest that stress redistribution and damage to the rock mass caused by deglaciation can lead to progressive failure. Further work is needed to understand better the slope failure mechanics to assess the geohazards in the Andes and other mountain regions. [ABSTRACT FROM AUTHOR]

Published

2023

5. Modelling rock glacier ice content based on InSAR-derived velocity, Khumbu and Lhotse valleys, Nepal.

Author

Hu, Yan, Harrison, Stephan, Liu, Lin, and Wood, Joanne Laura

Subjects

ALPINE glaciers, WATER storage, ROCK glaciers, GLOBAL warming, SYNTHETIC aperture radar, ICE, VISCOUS flow, GLACIAL melting

Abstract

Active rock glaciers are viscous flow features embodying ice-rich permafrost and other ice masses. They contain significant amounts of ground ice and serve as potential freshwater reservoirs as mountain glaciers melt in response to climate warming. However, current knowledge about ice content in rock glaciers has been acquired mainly from in situ investigations in limited study areas, which hinders a comprehensive understanding of ice storage in rock glaciers situated in remote mountains over local to regional scales. This study proposes a novel approach for assessing the hydrological value of rock glaciers in a more quantitative way and presents exploratory results focusing on a small region. We develop an empirical rheological model to infer ice content of rock glaciers using readily available input data, including rock glacier planar shape, surface slope angle, active layer thickness, and surface velocity. The model is calibrated and validated using observational data from the Chilean Andes and the Swiss Alps. We apply the model to five rock glaciers in the Khumbu and Lhotse valleys, northeastern Nepal. The velocity constraints applied to the model are derived from interferometric synthetic aperture radar (InSAR) measurements. The volume of rock glacier is estimated based on an existing scaling approach. The inferred volumetric ice fraction in the Khumbu and Lhotse valleys ranges from 70 ± 8 % to 74 ± 8 %, and the water volume equivalents lie between 1.4±0.2 and 5.9±0.6×106 m 3 for the coherently moving parts of individual rock glaciers. Due to the accessibility of the model inputs, our approach is applicable to permafrost regions where observational data are lacking, which is valuable for estimating the water storage potential of rock glaciers in remote areas. [ABSTRACT FROM AUTHOR]

Published

2023

6. Millennial variability of terrigenous transport to the central–southern Peruvian margin during the last deglaciation (18–13 kyr BP).

Author

Yseki, Marco, Turcq, Bruno, Caquineau, Sandrine, Salvatteci, Renato, Solis, José, Skilbeck, C. Gregory, Velazco, Federico, and Gutiérrez, Dimitri

Subjects

MERIDIONAL overturning circulation, INTERTROPICAL convergence zone, WALKER circulation, PRECIPITATION variability, MARINE sediments, GLACIAL melting

Abstract

Reconstructing precipitation and wind from the geological record could help researchers understand the potential changes in precipitation and wind dynamics in response to climate change in Peru. The last deglaciation offers natural experimental conditions to test the response of precipitation and wind dynamics to high-latitude forcing. While considerable research has been done to reconstruct precipitation variability during the last deglaciation in the Atlantic sector of South America, the Pacific sector of South America has received little attention. This work aims to fill this gap by reconstructing types of terrigenous transport to the central–southern Peruvian margin (12 and 14 ∘ S) during the last deglaciation (18–13 kyr BP). For this purpose, we used grain-size distribution in sediments of marine core M77/2-005-3 (Callao, 12 ∘ S) and core G14 (Pisco, 14 ∘ S). We analyzed end-members (EMs) to identify grain-size components and reconstruct potential sources and transport processes of terrigenous material across time. We identified four end-members for both Callao and Pisco sediments. In Callao, we propose that the changes in the contributions of EM4 (101 µm) and EM2 (58 µm) mainly reflect the hydrodynamic energy and diffuse sources, respectively, while the variations in EM3 (77 µm) and EM1 (11 µm) reflect changes in the eolian and fluvial inputs, respectively. In Pisco, where there are strong winds and an extensive coastal desert, changes in the contribution of EM1 (10 µm) reflect changes in river inputs, while EM2 (52 µm), EM3 (75 µm), and EM4 (94 µm) reflect an eolian origin. At millennial scale, our record shows an increase in the fluvial inputs during the last part of Heinrich Stadial 1 (∼16 –14.7 kyr BP) at both locations. This increase was linked to higher precipitation in the Andes related to a reduction of the Atlantic Meridional Overturning Circulation and meltwater discharge in the North Atlantic. In contrast, during the Bølling–Allerød interstadial (∼14.7 –13 kyr BP), there was an eolian input increase, associated with stronger winds and lower precipitation that indicate an expansion of the South Pacific Subtropical High. These conditions would correspond to a northern displacement of the Intertropical Convergence Zone–South Pacific Subtropical High system associated with a stronger Walker circulation. Our results suggest that variations in river discharge and changes in surface wind intensity in the western margin of South America during the last deglaciation were sensitive to Atlantic Meridional Overturning Circulation variations and the Walker circulation on millennial timescales. In the context of global warming, large-scale increases in precipitation and fluvial discharge in the Andes as a result of a declining Atlantic Meridional Overturning Circulation and southward displacement of the Intertropical Convergence Zone should be considered. [ABSTRACT FROM AUTHOR]

Published

2022

7. Refinement of the tephrostratigraphy straddling the northern Patagonian Andes (40–41°S): new tephra markers, reconciling different archives and ascertaining the timing of piedmont deglaciation.

Author

Alloway, Brent V., Pearce, Nicholas J. G., Moreno, Patricio I., Villarosa, Gustavo, Jara, Ignacio A., Henríquez, Carla A., Sagredo, Esteban A., Ryan, Matthew T., and Outes, Valeria

Subjects

VOLCANIC ash, tuff, etc., GLACIAL melting, SOIL formation, WATERSHEDS, GEOCHEMISTRY, REGOLITH

Abstract

We describe the stratigraphy, age, geochemistry and correlation of tephra from west to east across the northern Patagonian Andes (c. 40–41°S) with a view to further refining the eruptive history of this region back to the onset of the Last Glacial Termination (~18 cal. ka). Eastwards across the Andes, rhyodacite to rhyolitic tephra markers of dominantly Puyehue‐Cordón Caulle source are persistently recognised and provide a stratigraphic context for more numerously erupted intervening tephra of basalt to basaltic–andesite composition. Tephra from distal eruptive centres are also recognised. West of the Andean Cordillera, organic‐rich cores from a small closed lake basin (Lago Pichilafquén) reveal an exceptional high‐resolution record of lowland vegetation–climate change and eruptive activity spanning the last 15 400 years. Three new rhyodacite tephra (BT6‐T1, ‐T2 and ‐T4) identified near the base of the Pichilafquén record, spanning 13.2 to 13.9 cal. ka bp, can be geochemically matched with correlatives in basal andic soil sequences closely overlying regolith and/or basement rock. The repetitiveness of this tephrostratigraphy across this Andean transect suggests near‐synchronous tephra accretion and onset of up‐building soil formation under more stable (revegetating) ground‐surface conditions following rapid piedmont deglaciation on both sides of the Cordillera by at least ~14 cal. ka bp. [ABSTRACT FROM AUTHOR]

Published

2022

8. Development and resilience of deciduous Nothofagus forests since the Last Glacial Termination and deglaciation of the central Patagonian Andes.

Author

Villa-Martínez, Rodrigo and Moreno, Patricio I.

Subjects

*DECIDUOUS forests, *CONIFERS, *LAST Glacial Maximum, *GLACIAL melting, *GLACIAL landforms, *WESTERLIES, *GLACIERS, *GADOLINIUM

Abstract

Resolving the history of vegetation, fire, and glaciation on the eastern slope of the central Patagonian Andes (44°-49°S) since the Last Glacial Termination (T1) has proved difficult. This is due to the steep environmental gradients, vegetation heterogeneity, and scarcity of dated glacial deposits and geomorphic features. Unsurprisingly, published records show important heterogeneities which limit our understanding of the timing and magnitude of climate and vegetation changes, and their driving mechanisms since T1. In this paper, we describe sediment cores from small closed-basin lakes located in the deciduous Nothofagus forest zone near Coyhaique, Chile. Our results indicate that the Coyhaique glacier lobe abandoned its final Last Glacial Maximum position just before ~17.9 cal kyr BP and underwent a step-wise recession that included a halt/readvance that culminated at ~16.8 cal kyr BP, contemporaneous with the formation of an ice-dammed proglacial lake in the Coyhaique/Balmaceda sector. This glacial lake stood at its highest level between ~17.9–17.2 cal kyr BP (<726 and > 650 m.a.s.l.), lowered between ~17.2–16.2 cal kyr BP (<650 and > 570 m.a.s.l.), and disappeared thereafter. Herbs and shrubs, currently dominant in high Andean and Patagonian steppe environments, colonized the ice-free terrains distal to the glacier margins and proglacial lakes under cold and dry conditions. This was followed by a steady increase in Nothofagus between ~16.6–14.8 cal kyr BP that led to the establishment of forests starting at ~14.8 cal kyr BP. The Holocene started with a sudden increase in Nothofagus and disappearance of conifers in the context of increase fire activity between ~11.7–9.4 cal kyr BP. Closed-canopy Nothofagus forests persisted virtually unaltered from ~9.4 cal kyr BP to the present day, despite frequent explosive volcanism and millennial-scale variations in fire regimes, attesting to their extraordinary postglacial resilience which contrasts with their behavior during T1. Recent large-scale deforestation by fire, livestock grazing, and the spread of non-native invasive plant species drove the fastest and largest-magnitude shifts seen during the last ~16,500 years. • Glacial retreat began at ~17.9 ka and followed a stepwise pattern until ~16.2 ka. • Arboreal Pollen rose at ~16.6 ka driven by stronger Southern Westerly Winds (SWW). • Rainforest conifers peaked between ~14.8–11.7 ka suggesting maximum SWW influence. • Fires and disappearance of conifers suggest weak SWW between ~11.7–9.4 ka. • Extraordinarily resilient Nothofagus forests have persisted since ~9.4 ka. [ABSTRACT FROM AUTHOR]

Published

2021

9. Effects of climate variability on mercury deposition during the Older Dryas and Younger Dryas in the Venezuelan Andes.

Author

Schneider, Larissa, Cooke, Colin A., Stansell, Nathan D., and Haberle, Simon G.

Subjects

MERCURY, CLIMATOLOGY, ATMOSPHERIC deposition, CLIMATE change, GLACIAL melting, SEDIMENTS

Abstract

We present a high-resolution record of Late Glacial and Early Holocene mercury (Hg) accumulation within the sediments of Laguna de Los Anteojos, a small headwater alpine lake in Venezuela. Our sediment core spans the Older Dryas (OD) and Younger Dryas (YD) climate reversals, providing new insight into the effects of abrupt climatic transitions on atmospheric Hg deposition. Sediment Hg concentrations and accumulation rates (fluxes) increased sharply after regional deglaciation and then peaked immediately prior to onset of both the OD and YD. Mercury concentrations and fluxes then decreased through cold OD and YD conditions. Both Hg concentrations and fluxes increased rapidly with warming, rising two-fold in about 100 years after the OD and nearly four-fold in about 500 years during the latter-half of the YD. This lake-sediment record of Hg dynamics during the Glacial–Holocene transition suggests atmospheric Hg cycling is affected by abrupt climate change. [ABSTRACT FROM AUTHOR]

Published

2020

10. Deglaciation in the semi-arid Andes of Chile (32°–34° S) – results from geomorphological mapping and geochronology.

Author

Fernández, Hans, García, Juan Luis, Gärtner-Roer, Isabelle, and Nussbaumer, Samuel U.

Subjects

*ABLATION (Glaciology), *GLACIAL melting, *COSMOGENIC nuclides, *ICE cores, *CLIMATE change, *GLACIERS

Abstract

Reconstructing the evolution of the glacial landscape of the semi-arid Andes (32°–34° S) during phases of Holocene deglaciation is key to understand the responses of the cryosphere during warmer periods such as the current one. Despite having geomorphological records with good degrees of preservation, few studies have addressed the changes of the Andes during the glacial-paraglacial transition. In this paper, we investigate and compare geomorphological mappings of four glacial sub-basins of the central Andes of Chile: Juncal Norte (32° S, glacier terminus at ~ 3000 m asl.), Loma Larga (33° S, terminus at ~ 3000 m asl.), Nieves Negras (33° S, terminus at ~ 3000 m asl.), and Universidad (34° S, terminus at ~ 2500 m asl.). The ablation zones of Loma Larga and Nieves Negras glaciers have a mantle of debris, which suggests a process of ablation in situ rather than retreat of the glacier tongue. Both glaciers have a morphology of internal collapse in their debris-covered section. On the other hand, Juncal Norte and Universidad glaciers both have lateral moraines with ice cores, where the differential ablation has triggered backwasting and downwasting processes. The presence of ice-cored lateral moraines indicates greater activity of processes in the lateral sections. The Universidad glacier is characterized by two branches feeding the glacier tongue which shows a prominent medial moraine.For the first time in this part of the Andes, we used 36Cl terrestrial cosmogenic nuclides (TCN) for dating deglaciation geomorphology. We complement our 36Cl data with 14C ages that suggest that glaciers advanced before ~2500 and then before ~850/1000 years BP.The combination of the geomorphology and the geochronology in the different proglacial areas allows the analysis of the deglaciation history and related processes. Identifying how ablation occurs in semi-arid mountain environments is important to assess the behaviour of ice under changing climatic conditions and its preservation under a cover of debris. One of the characteristics and challenges of the deglaciation in the semi-arid Andes is the high production of debris in the ablation zones. [ABSTRACT FROM AUTHOR]

Published

2019

11. Groundwater Buffers Decreasing Glacier Melt in an Andean Watershed—But Not Forever.

Author

Somers, Lauren D., McKenzie, Jeffrey M., Mark, Bryan G., Lagos, Pablo, Ng, Gene‐Hua Crystal, Wickert, Andrew D., Yarleque, Christian, Baraër, Michel, and Silva, Yamina

Subjects

ALPINE glaciers, MELTWATER, GROUNDWATER, GLACIAL melting, WATER, WATER supply, GROUNDWATER recharge, GLACIOLOGY

Abstract

Accelerating mountain glacier recession in a warming climate threatens the sustainability of mountain water resources. The extent to which groundwater will provide resilience to these water resources is unknown, in part due to a lack of data and poorly understood interactions between groundwater and surface water. Here we address this knowledge gap by linking climate, glaciers, surface water, and groundwater into an integrated model of the Shullcas Watershed, Peru, in the tropical Andes, the region experiencing the most rapid mountain‐glacier retreat on Earth. For a range of climate scenarios, our model projects that glaciers will disappear by 2100. The loss of glacial meltwater will be buffered by relatively consistent groundwater discharge, which only receives minor recharge (~2%) from glacier melt. However, increasing temperature and associated evapotranspiration, alongside potential decreases in precipitation, will decrease groundwater recharge and streamflow, particularly for the RCP 8.5 emission scenario. Plain Language Summary: Mountain regions play an important role in water supply, because meltwater from snow and ice feeds rivers during dry periods. Groundwater (water stored in the pore spaces of soils and rock), which flows into rivers, is also an important store of water in mountain areas and may help to protect water resources against the negative impacts of shrinking mountain glaciers. We used extensive field measurements and computer modeling of the Shullcas Watershed in the Peruvian Andes to determine the current and future role of groundwater in the face of climate change. Our model projects that glaciers in our study area will disappear by 2100. The loss of glacier meltwater is buffered in the short term (~30 years) by consistent groundwater flow to rivers. However, in the long term (>60 years), precipitation is expected to decrease and rising temperatures lead to increased evaporation and water use by plants. These factors reduce groundwater recharge and storage, causing dry season streamflow to drop. Key Points: Groundwater accounts for a large fraction of streamflow and only receives minor (~2%) recharge from glaciers in the study catchment in PeruAs meltwater decreases, groundwater provides consistent discharge in the near term (~30 years), becoming a larger fraction of streamflowIn the long term (>60 years), groundwater storage and discharge decrease in response to higher evapotranspiration and lower precipitation [ABSTRACT FROM AUTHOR]

Published

2019

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

Author

da Rocha, Nájila Souza, Veettil, Bijeesh K, Grondona, Atilio, and Rolim, Silvia

Subjects

WATER levels, GLACIERS, EL Nino, GLACIAL melting, HYDROLOGY, WATERSHEDS

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2019

13. Rewriting conservation landscapes: protected areas and glacial retreat in the high Andes.

Author

Rasmussen, Mattias Borg

Subjects

GLACIAL melting, GLACIERS & climate, CLIMATE change, GLACIERS

Abstract

Glacial retreat reveals the unsettling effects of anthropogenic climate change, and challenges deeply seated cultural ideas about static landscapes. Glaciers have thus emerged as key signifiers of environmental loss. Because they are the outcomes of Westernized visions of the relationship between nature and culture, protected areas are important sites for understanding how notions of the Anthropocene come to reshape ideas about the future of glaciated landscapes. This article explores one particular conservation initiative, that of the establishment of the tourist and educational facility known as the Route of Climate Change in Peru's Huascarán National Park. It asks how we can understand the production of conservation landscapes in a context where the framing of glaciers as an endangered species denies their fluctuating dynamics and imparts to them a directionality toward irreversible change. Focusing on the contentious production of conservation landscapes through interaction between the park administration and a local community, the article is based on ethnographic fieldwork consisting of semi-structured interviews (48), informal conversations, and participant observation over multiple visits to the area between 2013 and 2015. The study finds that while the production of new conservation narratives certainly resituates the sites in time and place, it also produces uncertain environmental futures that may be molded to secure a rapprochement between park administrations and communities based on mutual alignment of conservation and community practices. It is thus argued that an underlying shift in orientation—from preserving what is to countering what might otherwise come to be—results in the production of new imaginaries about conservation landscapes that are both a condition and an outcome of protected area management in times of glacial retreat. [ABSTRACT FROM AUTHOR]

Published

2019

14. The last glacial termination on the eastern flank of the central Patagonian Andes (47° S).

Author

Henríquez, William I., Villa-Martínez, Rodrigo, Vilanova, Isabel, De Pol-Holz, Ricardo, and Moreno, Patricio I.

Subjects

GLACIAL melting, RAIN forests, TREES, SEDIMENTATION & deposition

Abstract

Few studies have examined in detail the sequence of events during the last glacial termination (T1) in the core sector of the Patagonian Ice Sheet (PIS), the largest ice mass in the Southern Hemisphere outside of Antarctica. Here we report results from Lago Edita (47°80 S, 72°250W, 570ma.s.l.), a small closed-basin lake located in a valley overridden by eastward-flowing Andean glaciers during the Last Glacial Maximum (LGM). The Lago Edita record shows glaciolacustrine sedimentation until 19 400 yr BP, followed by organic sedimentation in a closed-basin lake and a mosaic of cold-resistant hygrophilous conifers and rainforest trees, along with alpine herbs between 19 400 and 11 000 yr BP. Our data suggest that the PIS retreated at least ~90 km from its LGM limit between ~21 000 and 19 400 yr BP and that scattered, low-density populations of cold-resistant hygrophilous conifers, rainforest trees, high-Andean and steppe herbs thrived east of the Andes during the LGM and T1, implying high precipitation levels and southern westerly wind (SWW) influence at 47° S. The conifer Podocarpus nubigena increased between 14 500 and 13 000 yr BP, suggesting even stronger SWW influence during the Antarctic Cold Reversal, after which it declined and persisted until 11 000 yr BP. Large increases in arboreal pollen at ~13 000 and ~11 000 yr BP led to the establishment of forests near Lago Edita between 10 000 and 9000 yr BP, suggesting a rise in the regional tree line along the eastern Andean slopes driven by warming pulses at ~13 000 and ~11 000 yr BP and a subsequent decline in SWW influence at ~11 000 yr BP. We propose that the PIS imposed a regional cooling signal along its eastern, downwind margin through T1 that lasted until the separation of the northern and southern Patagonian ice fields along the Andes during the Younger Dryas period. We posit that the withdrawal of glacial and associated glaciolacustrine environments through T1 provided a route for the dispersal of hygrophilous trees and herbs from the eastern flank of the central Patagonian Andes, contributing to the afforestation of the western Andean slopes and pacific coasts of central Patagonia during T1. [ABSTRACT FROM AUTHOR]

Published

2017

15. Local perceptions in climate change debates: insights from case studies in the Alps and the Andes.

Author

Jurt, Christine, Burga, Maria, Vicuña, Luis, Huggel, Christian, and Orlove, Ben

Subjects

PUBLIC opinion on climate change, ATTITUDES toward the environment, ENVIRONMENTAL psychology, SOCIAL perception, GLACIAL melting

Abstract

The importance of integrating local perspectives into international debates about climate change has received increasing attention. Local perspectives on the impacts of climate change often focus on issues of loss and harm and support the widely recognized need for global responses to climate change as suggested by scientists and international institutions. Here we argue that local perspectives need to be addressed not only from outside communities but also from inside in order to understand people's responses to climate change: their concerns, their understanding of themselves as members of particular groups and their position in the world, their view on responsibilities for causing climate change, and their perceptions of possible responses. The ethnographic work at two study sites, one in Carhuaz, Cordillera Blanca, Peru, and one in Stilfs, South Tyrolean Alps, Italy, identifies dominant perceptions on climate change at each site with a particular focus on glacier retreat. The case studies show that the view on the need for global action as response to climate change is not necessarily shared throughout the world, and thus presents a challenge to global collaboration. [ABSTRACT FROM AUTHOR]

Published

2015

16. Can glacial retreat lead to migration? A critical discussion of the impact of glacier shrinkage upon population mobility in the Bolivian Andes.

Author

Raoul, Kaenzig

Subjects

GLACIAL melting, CLIMATE change, HUMAN migrations, EMIGRATION & immigration

Abstract

This article examines the role of glacial retreat on human migration in the Bolivian Andes-a topic with virtually no scholarly focus, yet of critical importance in the era of global climate change. Glacial melting has increased since the 1980s, and popular reports often suggest there will be significant impacts on local populations, including migration. Based on interviews with local residents, both migrants and nonmigrants, as well as topical experts, this study suggests that residents do, indeed, have serious concerns about future livelihood conditions in the Bolivian Andes. Even so, glacial retreat has not triggered new migration flows and has had a limited impact on the existing migratory patterns. [ABSTRACT FROM AUTHOR]

Published

2015