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1. Glacial Water: A Dynamic Microbial Medium

Author

Gilda Varliero, Pedro H. Lebre, Beat Frey, Andrew G. Fountain, Alexandre M. Anesio, and Don A. Cowan

Subjects
glacial microorganisms, glacier, meltwater, proglacial environment, water residence time, Biology (General), QH301-705.5
Abstract

Microbial communities and nutrient dynamics in glaciers and ice sheets continuously change as the hydrological conditions within and on the ice change. Glaciers and ice sheets can be considered bioreactors as microbiomes transform nutrients that enter these icy systems and alter the meltwater chemistry. Global warming is increasing meltwater discharge, affecting nutrient and cell export, and altering proglacial systems. In this review, we integrate the current understanding of glacial hydrology, microbial activity, and nutrient and carbon dynamics to highlight their interdependence and variability on daily and seasonal time scales, as well as their impact on proglacial environments.

Published
2023
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2. Glacier clear ice bands indicate englacial channel microbial distribution

Author

Gilda Varliero, Gary L A Barker, Andrew G. Fountain, Alexandra Holland, Marian L. Yallop, and Alexandre M. Anesio

Subjects
0301 basic medicine, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, microbiology, Biogeochemistry, Glacier, Spatial distribution, 01 natural sciences, Coring, 03 medical and health sciences, ice biology, 030104 developmental biology, Ice core, biogeochemistry, Glacial period, Physical geography, Arctic glaciology, Clear ice, ice core, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Ablation zone
Abstract

Distant glacial areas are interconnected by a complex system of fractures and water channels which run in the glacier interior and characterize the englacial realm. Water can slowly freeze in these channels where the slow freezing excludes air bubbles giving the ice a clear aspect. This ice is uplifted to the surface ablation zone by glacial movements and can therefore be observed in the form of clear surface ice bands. We employed an indirect method to sample englacial water by coring these ice bands. We were able, for the first time, to compare microbial communities sampled from clear (i.e. frozen englacial water bands) and cloudy ice (i.e. meteoric ice) through 16S rRNA gene sequencing. Although microbial communities were primarily shaped and structured by their spatial distribution on the glacier, ice type was a clear secondary factor. One area of the glacier, in particular, presented significant microbial community clear/cloudy ice differences. Although the clear ice and supraglacial communities showed typical cold-adapted glacial communities, the cloudy ice had a less defined glacial community and ubiquitous environmental organisms. These results highlight the role of englacial channels in the microbial dispersion within the glacier and, possibly, in the shaping of glacial microbial communities.

Published
2021
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4. Reanalysis of the US Geological Survey Benchmark Glaciers: long-term insight into climate forcing of glacier mass balance

Author

Emily Baker, Shad O'Neel, C. McNeil, Erich H. Peitzsch, Andrew G. Fountain, Daniel McGrath, Daniel B. Fagre, Caitlyn Florentine, and L. Sass

Subjects
geography, Humid continental climate, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Elevation, Glacier, 02 engineering and technology, Radiative forcing, Snow, 01 natural sciences, 020801 environmental engineering, Latitude, Glacier mass balance, Climatology, Geological survey, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Mountain glaciers integrate climate processes to provide an unmatched signal of regional climate forcing. However, extracting the climate signal via intercomparison of regional glacier mass-balance records can be problematic when methods for extrapolating and calibrating direct glaciological measurements are mixed or inconsistent. To address this problem, we reanalyzed and compared long-term mass-balance records from the US Geological Survey Benchmark Glaciers. These five glaciers span maritime and continental climate regimes of the western United States and Alaska. Each glacier exhibits cumulative mass loss since the mid-20th century, with average rates ranging from −0.58 to −0.30 m w.e. a−1. We produced a set of solutions using different extrapolation and calibration methods to inform uncertainty estimates, which range from 0.22 to 0.44 m w.e. a−1. Mass losses are primarily driven by increasing summer warming. Continentality exerts a stronger control on mass loss than latitude. Similar to elevation, topographic shading, snow redistribution and glacier surface features often exert important mass-balance controls. The reanalysis underscores the value of geodetic calibration to resolve mass-balance magnitude, as well as the irreplaceable value of direct measurements in contributing to the process-based understanding of glacier mass balance.

Published
2019
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5. Glaciers of the Olympic Mountains, Washington- the past and future 100 years

Author

Brian Menounos, Andrew G. Fountain, Justin Pflug, Bryce Glenn, Jon L. Riedel, and Christina Gray

Subjects
geography, geography.geographical_feature_category, Perennial plant, Glacier, Physical geography
Abstract

In 2015, the Olympic Mountains contain 255 glaciers and perennial snowfields totaling 25.34 ± 0.27 km2, half of the area in 1900, and about 0.75 ± 0.19 km

Published
2021
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6. Biological albedo reduction on ice sheets, glaciers, and snowfields

Author

Nozomu Takeuchi, Jenine McCutcheon, Alexandre M. Anesio, Trinity L. Hamilton, Andrew G. Fountain, Scott Hotaling, Liane G. Benning, S. McKenzie Skiles, Roman J. Dial, Joanna L. Kelley, and Stefanie Lutz

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Earth science, Biome, Ice algae, Cryoconite, Glacier, Albedo, 010502 geochemistry & geophysics, Snow, 01 natural sciences, Biogeophysical feedback, Snow algae, General Earth and Planetary Sciences, Environmental science, Cryosphere, Ecosystem, Glacier biology, Ice sheet, 0105 earth and related environmental sciences
Abstract

The global cryosphere, Earth's frozen water, is in precipitous decline. The ongoing and predicted impacts of cryosphere loss are diverse, ranging from disappearance of entire biomes to crises of water availability. Covering approximately one-fifth of the planet, mass loss from the terrestrial cryosphere is driven primarily by a warming atmosphere but reductions in albedo (the proportion of reflected light) also contribute by increasing absorption of solar radiation. In addition to dust and other abiotic impurities, biological communities substantially reduce albedo worldwide. In this review, we provide a global synthesis of biological albedo reduction (BAR) in terrestrial snow and ice ecosystems. We first focus on known drivers—algal blooms and cryoconite (granular sediment on the ice that includes both mineral and biological material)—as they account for much of the biological albedo variability in snow and ice habitats. We then consider an array of potential drivers of BAR whose impacts may be overlooked, such as arthropod deposition, resident organisms (e.g., dark-bodied glacier ice worms), and larger vertebrates, including humans, that transiently visit the cryosphere. We consider both primary (e.g., BAR due to the presence of pigmented algal cells) and indirect (e.g., nutrient addition from arthropod deposition) effects, as well as interactions among biological groups (e.g., birds feeding on ice worms). Collectively, we highlight that in many cases, overlooked drivers and interactions among factors have considerable potential to alter BAR, perhaps rivaling the direct effects of algal blooms and cryoconite. We conclude by highlighting knowledge gaps for the field with an emphasis on the underrepresentation of genomic tools, understudied areas (particularly high-elevation glaciers at tropical latitudes), and a dearth of temporal sampling in current efforts. We detail a global framework for long-term BAR monitoring that, if implemented, would yield a tremendous amount of insight for BAR and would be particularly valuable in light of the rapid ecological and physical changes occurring in the contemporary cryosphere.

Published
2021
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8. Rock glaciers and related cold rocky landforms: Overlooked climate refugia for mountain biodiversity

Author

Jasmine E. Saros, Andrew G. Fountain, S. Brighenti, David B. Herbst, Scott Hotaling, Constance I. Millar, Lusha M. Tronstad, Masaki Hayashi, and Debra S. Finn

Subjects
0106 biological sciences, 010504 meteorology & atmospheric sciences, Climate, Climate Change, Biodiversity, Rock glacier, 010603 evolutionary biology, 01 natural sciences, Environmental Chemistry, Animals, Ecosystem, Ice Cover, 0105 earth and related environmental sciences, General Environmental Science, Global and Planetary Change, geography.geographical_feature_category, Ecology, Global warming, Glacier, Geography, Habitat, Refugium, Threatened species, Global biodiversity
Abstract

Mountains are global biodiversity hotspots where cold environments and their associated ecological communities are threatened by climate warming. Considerable research attention has been devoted to understanding the ecological effects of alpine glacier and snowfield recession. However, much less attention has been given 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 and stable habitats for aquatic and terrestrial biodiversity. CRLs are less responsive to atmospheric warming than alpine glaciers and snowfields due to the insulating nature and thermal inertia of their debris cover paired with their internal ventilation patterns. Thus, CRLs are likely to remain on the landscape after adjacent glaciers and snowfields have melted, thereby providing longer-term cold habitat for biodiversity living on and downstream of them. Here, we show that CRLs will likely act as key climate refugia for terrestrial and aquatic biodiversity in mountain ecosystems, offer guidelines for incorporating CRLs into conservation practices, and identify areas for future research.

Published
2020

9. Rock glaciers of the contiguous United States: GIS inventory and spatial distribution patterns

Author

Gunnar Johnson, Heejun Chang, and Andrew G. Fountain

Subjects
geography, Training set, geography.geographical_feature_category, business.industry, Distribution (economics), Rock glacier, Glacier, Vegetation, Arid, Remote sensing (archaeology), Regional studies, Physical geography, business, Geology
Abstract

Continental-scale inventories of glaciers are available, but no analogous rock glacier inventories exist. We present the Portland State University Rock Glacier Inventory (n = 10,343) for the contiguous United States, derived from the manual classification of remote sensing imagery (Johnson 2020, https://doi.pangaea.de/10.1594/PANGAEA.918585). Individually, these rock glaciers are found across widely disparate montane environments, but their overall distribution unambiguously favors relatively high, arid mountain ranges with sparse vegetation. While at least one rock glacier is identified in each of the 11 westernmost states, nearly 88 % are found in just five states: Colorado (n = 3889), Montana (n = 1813), Idaho (n = 1689), Wyoming (n = 850), and Utah (n = 834). Mean rock glacier area is estimated at 0.10 km2, with cumulative rock glacier area totaling 1008.91 km2. Rock glaciers are assigned to a three-tier classification system based on area thresholds and surface characteristics known to correlate with downslope movement. Class 1 features (n = 7052, average area = 0.12 km2) appear to be highly active, Class 2 features (n = 2416, average area = 0.05 km2) appear to be intermediately active and Class 3 features (n = 875, average area = 0.04 km2) appear to be minimally active. This geospatial inventory will allow past rock glacier research findings to be spatially extrapolated, help facilitate further rock glacier research by identifying field study sites, and serve as a valuable training set for the development of automated rock glacier identification and classification methods applicable to other large regional studies.

Published
2020

10. Decadal topographic change in the McMurdo Dry Valleys of Antarctica: Thermokarst subsidence, glacier thinning, and transfer of water storage from the cryosphere to the hydrosphere

Author

Joseph S. Levy, Maciej K. Obryk, Andrew G. Fountain, J. W. Telling, Rickard Pettersson, D. J. Van Horn, Michael N. Gooseff, and Craig Glennie

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Subsidence (atmosphere), Glacier, 010502 geochemistry & geophysics, Permafrost, 01 natural sciences, Thermokarst, Groundwater-related subsidence, Cryosphere, Glacial period, Physical geography, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Hydrosphere
Abstract

Recent local-scale observations of glaciers, streams, and soil surfaces in the McMurdo Dry Valleys of Antarctica (MDV) have documented evidence for rapid ice loss, glacial thinning, and ground surface subsidence associated with melting of ground ice. To evaluate the extent, magnitude, and location of decadal-scale landscape change in the MDV, we collected airborne lidar elevation data in 2014–2015 and compared these data to a 2001–2002 airborne lidar campaign. This regional assessment of elevation change spans the recent acceleration of warming and melting observed by long-term meteorological and ecosystem response experiments, allowing us to assess the response of MDV surfaces to warming and potential thawing feedbacks. We find that locations of thermokarst subsidence are strongly associated with the presence of excess ground ice and with proximity to surface or shallow subsurface (active layer) water. Subsidence occurs across soil types and landforms, in low-lying, low-slope areas with impeded drainage and also high on steep valley walls. Glacier thinning is widespread and is associated with the growth of fine-scale roughness. Pond levels are rising in most closed-basin lakes in the MDV, across all microclimate zones. These observations highlight the continued importance of insolation-driven melting in the MDV. The regional melt pattern is consistent with an overall transition of water storage from the local cryosphere (glaciers, permafrost) to the hydrosphere (closed basin lakes and ponds as well as the Ross Sea). We interpret this regional melting pattern to reflect a transition to Arctic and alpine-style, hydrologically mediated permafrost and glacial melt.

Published
2018
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11. Glacier Recession and the Response of Summer Streamflow in the Pacific Northwest United States, 1960–2099

Author

Jon L. Riedel, C. D. Frans, Andrew G. Fountain, Dennis P. Lettenmaier, and Erkan Istanbulluoglu

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Glacier recession, 0208 environmental biotechnology, Climate change, Glacier, 02 engineering and technology, STREAMS, 01 natural sciences, 020801 environmental engineering, Streamflow, Air temperature, Stream flow, Environmental science, Physical geography, Surface runoff, 0105 earth and related environmental sciences, Water Science and Technology
Published
2018
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12. The changing extent of the glaciers along the western Ross Sea, Antarctica

Author

Ted Scambos, Bryce Glenn, and Andrew G. Fountain

Subjects
geography, Oceanography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Geology, Glacier, 02 engineering and technology, 01 natural sciences, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences
Published
2017
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13. The Geography of Glaciers and Perennial Snowfields in the American West

Author

Andrew G. Fountain, Bryce Glenn, and Hassan J. Basagic

Subjects
Global and Planetary Change, geography, education.field_of_study, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Perennial plant, Population, Oceanic climate, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, Climatology, Geological survey, Period (geology), Precipitation, education, American west, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

A comprehensive mid-20th century inventory of glaciers and perennial snowfields (G&PS) was compiled for the American West, west of the 100° meridian. The inventory was derived from U.S. Geological Survey 1:24,000 topographic maps based on aerial photographs acquired during 35 years, 1955–1990, of which the first 20 years or more was a cool period with little glacier change. The mapped features were filtered for those greater than 0.01 km2. Results show that 5036 G&PS (672 km2, 14 km3) populate eight states, of which about 1276 (554 km2, 12 km3) are glaciers. Uncertainty is estimated at ±9% for area and ±20% for volume. Two populations of G&PS were identified based on air temperature and precipitation. The larger is found in a maritime climate of the Pacific Northwest, characterized by warm winter air temperatures and high winter precipitation (~2100 mm). The other population is continental in climate, characterized by cold winter air temperatures, relatively low winter precipitation (~880 mm), an...

Published
2017
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14. The Scientific Discovery of Glaciers in the American West

Author

Andrew G. Fountain

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 05 social sciences, Geography, Planning and Development, Scientific discovery, 0507 social and economic geography, Glacier, 01 natural sciences, Archaeology, 050703 geography, American west, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

The American West has been the proving ground for a number of earth sciences, including the study of glaciers. From their discovery by Western science in the late 1800s and continuing to the presen...

Published
2017
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17. Glaciers in equilibrium, McMurdo Dry Valleys, Antarctica

Author

Spencer Niebuhr, Andrew G. Fountain, and Hassan J. Basagic

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Excursion, Elevation, Winter storm, Glacier, 010502 geochemistry & geophysics, Snow, 01 natural sciences, Equilibrium line altitude, Physical geography, Geomorphology, Geology, Polar desert, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

The McMurdo Dry Valleys are a cold, dry polar desert and the alpine glaciers therein exhibit small annual and seasonal mass balances, often

Published
2016
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18. The differing biogeochemical and microbial signatures of glaciers and rock glaciers

Author

Edward K. Hall, Andrew G. Fountain, Timothy S. Fegel, Gunnar Johnson, and Jill S. Baron

Subjects
Atmospheric Science, geography, Biogeochemical cycle, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Paleontology, Soil Science, Rock glacier, Biogeochemistry, Forestry, Glacier, 010501 environmental sciences, Aquatic Science, Glacier morphology, 01 natural sciences, Oceanography, Physical geography, Glacial period, Meltwater, Mountain range, Geology, 0105 earth and related environmental sciences, Water Science and Technology
Abstract

Glaciers and rock glaciers supply water and bioavailable nutrients to headwater mountain lakes and streams across all regions of the American West. Here we present a comparative study of the metal, nutrient, and microbial characteristics of glacial and rock glacial influence on headwater ecosystems in three mountain ranges of the contiguous U.S.: the Cascade Mountains, Rocky Mountains, and Sierra Nevada. Several meltwater characteristics (water temperature, conductivity, pH, metals, nutrients, complexity of dissolved organic matter (DOM), and bacterial richness and diversity) differed significantly between glacier and rock glacier meltwaters, while other characteristics (Ca, Fe, SiO2 concentrations, reactive nitrogen, and microbial processing of DOM) showed distinct trends between mountain ranges regardless of meltwater source. Some characteristics were affected both by glacier type and mountain range (e.g., temperature, ammonium (NH4 ) and nitrate (NO3 ) concentrations, and bacterial diversity). Due to the ubiquity of rock glaciers and the accelerating loss of the low-latitude glaciers, our results point to the important and changing influence that these frozen features place on headwater ecosystems.

Published
2016
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19. Distributed modeling of ablation (1996–2011) and climate sensitivity on the glaciers of Taylor Valley, Antarctica

Author

Glen E. Liston, Andrew G. Fountain, and Matthew J. Hoffman

Subjects
geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0208 environmental biotechnology, Microclimate, Glacier, 02 engineering and technology, Atmospheric sciences, 01 natural sciences, 020801 environmental engineering, Glacier mass balance, Climate sensitivity, Spatial variability, Glacial period, Surface runoff, Geomorphology, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes, Ablation zone
Abstract

The McMurdo Dry Valleys of Antarctica host the coldest and driest ecosystem on Earth, which is acutely sensitive to the availability of water coming from glacial runoff. We modeled the spatial variability in ablation and assessed climate sensitivity of the glacier ablation zones using 16 years of meteorological and surface mass-balance observations collected in Taylor Valley. Sublimation was the primary form of mass loss over much of the ablation zones, except for near the termini where melt, primarily below the surface, dominated. Microclimates in ~10 m scale topographic basins generated melt rates up to ten times higher than over smooth glacier surfaces. In contrast, the vertical terminal cliffs on the glaciers can have higher or lower melt rates than the horizontal surfaces due to differences in incoming solar radiation. The model systematically underpredicted ablation for the final 5 years studied, possibly due to an increase of windblown sediment. Surface mass-balance sensitivity to temperature was ~−0.02 m w.e. K−1, which is among the smallest magnitudes observed globally. We also identified a high sensitivity to ice albedo, with a decrease of 0.02 having similar effects as a 1 K increase in temperature, and a complex sensitivity to wind speed.

Published
2016
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20. 20th Century Retreat and Recent Drought Accelerated Extinction of Mountain Glaciers and Perennial Snowfields in the Trinity Alps, California

Author

Hassan J. Basagic, Justin M. Garwood, Michael van Hattem, Kenneth T. Lindke, and Andrew G. Fountain

Subjects
0106 biological sciences, Canyon, geography, geography.geographical_feature_category, Extinction, Perennial plant, 010604 marine biology & hydrobiology, Biodiversity, Glacier, Snow, 010603 evolutionary biology, 01 natural sciences, Moraine, Physical geography, Precipitation, Ecology, Evolution, Behavior and Systematics, Geology
Abstract

The Trinity Alps is a compact glaciated subrange of the Klamath Mountains in northwest California with elevations < 2,750 m making it a unique location in the western US to study glacier change. We examined glacier change since the last Little Ice Age advance in the late 19th century by mapping historic glacier areas using clearly defined moraines. At least six glaciers existed in the Trinity Alps around the 1880s and estimated glacier cover was at least 55.4 ha (0.554 km2). We tracked changes in two glaciers and two perennial snowfields since that time. Total glacier area decreased by 79% (43.8 ha to 9.1 ha) from the 1880s to 1994. By 2013, glacier area decreased another 7% of the 1880s area to 6.0 ha. Overall, retreat was similar for Salmon Glacier (–89%) and Grizzly Glacier (–84%), but since 1994 Salmon retreat has been much faster, 53% versus 16% for Grizzly. The extended 2012 to 2016 drought resulted in catastrophic retreat of both glaciers such that by 2015 Salmon Glacier disappeared and Grizzly Glacier retreated to 1.67 ha and partially stagnated, a –97% loss of total glacier area since the 1880s. Two snowfields (3.02 ha total area in 1955) were tracked since 1955, the Mirror Lake snowfield disappeared by the summer of 2013 and the Canyon Creek snowfield disappeared by October 2014. The unusually warm summer temperatures since 2005 combined with extremely low winter precipitation from 2013 to 2015 caused rapid retreat and near elimination of the Trinity Alps perennial snow and ice threatening local biodiversity that depends on these features.

Published
2020
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21. Comparison of Microbial Communities in the Sediments and Water Columns of Frozen Cryoconite Holes in the McMurdo Dry Valleys, Antarctica

Author

Dorota L. Porazinska, Adam J. Solon, Eli M. S. Gendron, Kaelin M. Cawley, Pacifica Sommers, Jenna Ryder, Felix Jacob Zamora, Kim Vincent, Andrew G. Fountain, Steven K. Schmidt, John L. Darcy, and Lara Vimercati

Subjects
Microbiology (medical), Earth science, lcsh:QR1-502, Biodiversity, ciliate, Microbiology, lcsh:Microbiology, 03 medical and health sciences, Water column, Cryoconite, bacteria, 030304 developmental biology, Original Research, 0303 health sciences, geography, Biomass (ecology), geography.geographical_feature_category, 030306 microbiology, Sediment, Glacier, Spatial ecology, Environmental science, Antarctica, niche partitioning, Species richness, cryoconite, extremophile
Abstract

Although cryoconite holes, sediment-filled melt holes on glacier surfaces, appear small and homogenous, their microbial inhabitants may be spatially partitioned. This partitioning could be particularly important for maintaining biodiversity in holes that remain isolated for many years, such as in Antarctica. We hypothesized that cryoconite holes with greater species richness and biomass should exhibit greater partitioning between the sediments and water, promoting greater biodiversity through spatial niche partitioning. We tested this hypothesis by sampling frozen cryoconite holes along a gradient of biomass and biodiversity in the Taylor Valley, Antarctica, where ice-lidded cryoconite holes are a ubiquitous feature of glaciers. We extracted DNA and chlorophyll a from the sediments and water of these samples to describe biodiversity and quantify proxies for biomass. Contrary to our expectation, we found that cryoconite holes with greater richness and biomass showed less partitioning of phylotypes by the sediments versus the water, perhaps indicating that the probability of sediment microbes being mixed into the water is higher from richer sediments. Another explanation may be that organisms from the water were compressed by freezing down to the sediment layer, leaving primarily relic DNA of dead cells to be detected higher in the frozen water. Further evidence of this explanation is that the dominant sequences unique to water closely matched organisms that do not live in cryoconite holes or the Dry Valleys (e.g., vertebrates); so this cryptic biodiversity could represent unknown microbial animals or DNA from atmospheric deposition of dead biomass in the otherwise low-biomass water. Although we cannot rule out spatial niche partitioning occurring at finer scales or in melted cryoconite holes, we found no evidence of partitioning between the sediments and water in frozen holes. Future work should include more sampling of cryoconite holes at a finer spatial scale, and characterizing the communities of the sediments and water when cryoconite holes are melted and active.

Published
2018

22. A century of glacier change in the Wind River Range, WY

Author

Andrew G. Fountain and Mark H. DeVisser

Subjects
Glacier mass balance, geography, geography.geographical_feature_category, Moraine, Ice stream, Climatology, Tidewater glacier cycle, Rock glacier, Glacier, Cirque glacier, Glacier morphology, Geology, Earth-Surface Processes
Abstract

The Wind River Range spans roughly 200 km along the continental divide in western Wyoming and encompasses at least 269 glaciers and perennial snowfields totaling 34.34 ± 0.13 km 2 (2006), including Gannett Glacier, the largest glacier (2.81 km 2 ) in the continental U.S. outside of Washington State. To track changing glacier and perennial snow surface area over the past century we used historic maps, aerial photography, and geologic evidence evident in said imagery. Since the end of the Little Ice Age (~ 1900), when the glaciers retreated from their moraines, to 2006 the ice-covered area shrank by ~ 47%. The main driver of surface area change was air temperature, with glaciers at lower elevations shrinking faster than those at higher elevations. The total contribution of ice wastage to late summer stream flow ranged from 0.4 to 1.5%, 0.9 to 2.8%, 1.7 to 5.4%, and 3.4 to 10.9% in four different watersheds, none of which exceeded 7% glacier cover. Results from previous studies were difficult to include because of differences in interpretation of glacier boundaries, because of poor imagery, or to extensive seasonal snow. These difficulties highlight potential problems in combining data sets from different studies and underscores the importance of reexamining past observations to ensure consistent interpretation.

Published
2015
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23. Glacier status and contribution to streamflow in the Olympic Mountains, Washington, USA

Author

Jon L. Riedel, William D. Baccus, Andrew G. Fountain, Steve Wilson, Michael Larrabee, and Tyler J. Fudge

Subjects
Hydrology, 010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Firn, Climate change, Glacier, Snow, Glacier morphology, 01 natural sciences, Streamflow, Glacial period, Surge, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

The Olympic Peninsula, Washington, USA, currently holds 184 alpine glaciers larger than 0.01 km2 and their combined area is 30.2 ± 0.95 km2. Only four glaciers are >1 km2 and 120 of the others are 2. This represents a loss of 82 glaciers and a 34% decrease in combined area since 1980, with the most pronounced losses occurring on south-facing aspects and in the more arid northeastern part of the range. Annual rate of loss in glacier area for seven of the largest glaciers accelerated from 0.26 km2 a−1 (1900–80) to 0.54 km2 a−1 (1980–2009). Thinning rates on four of the largest glaciers averaged nearly 1 ma−1 from 1987 to 2010, resulting in estimated volume losses of 17–24%. Combined glacial snow, firn and ice melt in the Hoh watershed is in the range 63–79 ± 7 × 106 m3, or 9–15% of total May–September streamflow. In the critical August–September period, the glacial fraction of total basin runoff increases to 18–30%, with one-third of the water directly from glacial ice (i.e. not snow and firn). Glaciers in the Elwha basin produce 12–15 ± 1.3 × 106 m3 (2.5–4.0%), while those in the Dungeness basin contribute 2.5–3.1 ± 0.28 × 106 m3 (3.0–3.8%).

Published
2015
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24. Analyzing Glacier Surface Motion Using LiDAR Data

Author

David C. Finnegan, J. W. Telling, Craig Glennie, and Andrew G. Fountain

Subjects
LiDAR, 010504 meteorology & atmospheric sciences, Point cloud, airborne laser scanning, 010502 geochemistry & geophysics, Tracking (particle physics), 01 natural sciences, morphology, Surface roughness, lcsh:Science, 0105 earth and related environmental sciences, Remote sensing, terrestrial laser scanning, glacier surface velocity, geography, geography.geographical_feature_category, business.industry, Glacier, Lidar, Particle image velocimetry, Temporal resolution, Global Positioning System, General Earth and Planetary Sciences, lcsh:Q, business, Geology
Abstract

Understanding glacier motion is key to understanding how glaciers are growing, shrinking, and responding to changing environmental conditions. In situ observations are often difficult to collect and offer an analysis of glacier surface motion only at a few discrete points. Using light detection and ranging (LiDAR) data collected from surveys over six glaciers in Greenland and Antarctica, particle image velocimetry (PIV) was applied to temporally-spaced point clouds to detect and measure surface motion. The type and distribution of surface features, surface roughness, and spatial and temporal resolution of the data were all found to be important factors, which limited the use of PIV to four of the original six glaciers. The PIV results were found to be in good agreement with other, widely accepted, measurement techniques, including manual tracking and GPS, and offered a comprehensive distribution of velocity data points across glacier surfaces. For three glaciers in Taylor Valley, Antarctica, average velocities ranged from 0.8–2.1 m/year. For one glacier in Greenland, the average velocity was 22.1 m/day (8067 m/year).

Published
2017

30. The McMurdo Dry Valleys: A landscape on the threshold of change

Author

David J. Van Horn, Joseph S. Levy, Michael N. Gooseff, and Andrew G. Fountain

Subjects
Canyon, Hydrology, geography, geography.geographical_feature_category, Global warming, Climate change, Sediment, Glacier, STREAMS, Permafrost, Hydrology (agriculture), Physical geography, Geology, Earth-Surface Processes
Abstract

Field observations of coastal and lowland regions in the McMurdo Dry Valleys suggest they are on the threshold of rapid topographic change, in contrast to the high elevation upland landscape that represents some of the lowest rates of surface change on Earth. A number of landscapes have undergone dramatic and unprecedented landscape changes over the past decade including, the Wright Lower Glacier (Wright Valley) — ablated several tens of meters, the Garwood River (Garwood Valley) has incised > 3 m into massive ice permafrost, smaller streams in Taylor Valley (Crescent, Lawson, and Lost Seal Streams) have experienced extensive down-cutting and/or bank undercutting, and Canada Glacier (Taylor Valley) has formed sheer, > 4 meter deep canyons. The commonality between all these landscape changes appears to be sediment on ice acting as a catalyst for melting, including ice-cement permafrost thaw. We attribute these changes to increasing solar radiation over the past decade despite no significant trend in summer air temperature. To infer possible future landscape changes in the McMurdo Dry Valleys, due to anticipated climate warming, we map ‘at risk’ landscapes defined as those with buried massive ice in relative warm regions of the valleys. Results show that large regions of the valley bottoms are ‘at risk’. Changes in surface topography will trigger important responses in hydrology, geochemistry, and biological community structure and function.

Published
2014
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31. Near-surface internal melting: a substantial mass loss on Antarctic Dry Valley glaciers

Author

Glen E. Liston, Andrew G. Fountain, and Matthew J. Hoffman

Subjects
010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Glacier, STREAMS, Annual cycle, Atmospheric sciences, 01 natural sciences, Ecosystem, Sublimation (phase transition), Drainage, Surface runoff, Geomorphology, Geology, Polar desert, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

The McMurdo Dry Valleys, southern Victoria Land, East Antarctica, are a polar desert, and melt from glacial ice is the primary source of water to streams, lakes and associated ecosystems. Previous work found that to adequately model glacier ablation and subsurface ice temperatures with a surface energy-balance model required including the transmission of solar radiation into the ice. Here we investigate the contribution of subsurface melt to the mass balance of (and runoff from) Dry Valley glaciers by including a drainage process in the model and applying the model to three glacier sites using 13 years of hourly meteorological data. Model results for the smooth glacier surfaces common to many glaciers in the Dry Valleys showed that sublimation was typically the largest component of surface lowering, with rare episodes of surface melting, consistent with anecdotal field observations. Results also showed extensive internal melting 5–15 cm below the ice surface, the drainage of which accounted for ~50% of summer ablation. This is consistent with field observations of subsurface streams and formation of a weathering crust. We identify an annual cycle of weathering crust formation in summer and its removal during the 10 months of winter sublimation.

Published
2014
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32. Do Cryoconite Holes have the Potential to be Significant Sources of C, N, and P to Downstream Depauperate Ecosystems of Taylor Valley, Antarctica?

Author

W. Berry Lyons, Hassan J. Basagic, Elizabeth Bagshaw, Kathleen A. Welch, Andrew G. Fountain, and Martyn Tranter

Subjects
Hydrology, Global and Planetary Change, Biogeochemical cycle, geography, Nutrient cycle, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Glacier, Particulates, 010502 geochemistry & geophysics, 01 natural sciences, Nutrient, Drainage system (geomorphology), Cryoconite, Ecosystem, Ecology, Evolution, Behavior and Systematics, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Nutrient recycling occurs in hydrologically isolated cryoconite holes on the glaciers of the McMurdo Dry Valleys, Antarctica. Biogeochemical processes enrich the cryoconite holes with solute and nutrients compared to the source sediment and glacier ice. The position of the glacier within the landscape affects the physical and biogeochemical character of the cryoconite holes, with those found in more biologically productive areas of the valley having higher concentrations of C., N, and P and higher pH. Comprehensive assessment of the quality and quantity of bioavailable C, N, and P shows that the cryoconite holes represent a significant store of nutrient in this depauperate landscape, since the total mass of C and N is similar to that found in the ephemeral streams. The dissolved nutrients within the holes, and a significant proportion of the particulate store, are released to the valley ecosystem via the network of ephemeral streams and perennially ice-covered lakes as a result of hydrological connection with the supraglacial drainage system. In most cases, cryoconite holes are flushed every several years, but during warm periods which occur with near decadal frequency, all holes connect and flush their contents off the glaciers. Simple mass balance modeling shows that an increase in primary productivity observed in Lake Fryxell that followed such a melt event in 2001/2002 can be explained by an influx of nutrients (specifically N) generated in the cryoconite holes. These features are hence an integral part of the Dry Valley ecosystem and should be considered in models of downstream biological processes.

Published
2013
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33. Garwood Valley, Antarctica: A new record of Last Glacial Maximum to Holocene glaciofluvial processes in the McMurdo Dry Valleys

Author

Jim E. O'Connor, Joseph S. Levy, W. Berry Lyons, Kathy A. Welch, and Andrew G. Fountain

Subjects
geography, geography.geographical_feature_category, Ice stream, Geology, Glacier, Last Glacial Maximum, Antarctic sea ice, Ice shelf, Paleontology, Oceanography, Sea ice, Cryosphere, Ice sheet
Abstract

We document the age and extent of late Quaternary glaciofluvial processes in Garwood Valley, McMurdo Dry Valleys, Antarctica, using mapping, stratigraphy, geochronology, and geochemical analysis of sedimentary and ice deposits. Geomorphic and stratigraphic evidence indicates damming of the valley at its Ross Sea outlet by the expanded Ross Sea ice sheet during the Last Glacial Maximum. Damming resulted in development of a proglacial lake in Garwood Valley that persisted from late Pleistocene to mid-Holocene time, and in the formation of a multilevel delta complex that overlies intact, supraglacial till and buried glacier ice detached from the Ross Sea ice sheet. Radiocarbon dating of delta deposits and inferred relationships between paleolake level and Ross Sea ice sheet grounding line positions indicate that the Ross Sea ice sheet advanced north of Garwood Valley at ca. 21.5 ka and retreated south of the valley between 7.3 and 5.5 ka. Buried ice remaining in Garwood Valley has a similar geochemical fingerprint to grounded Ross Sea ice sheet material elsewhere in the southern Dry Valleys. The sedimentary sequence in Garwood Valley preserves evidence of glaciofluvial interactions and climate-driven hydrological activity from the end of the Pleistocene through the mid-Holocene, making it an unusually complete record of climate activity and paleoenvironmental conditions from the terrestrial Antarctic.

Published
2013
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34. Decadal ecosystem response to an anomalous melt season in a polar desert in Antarctica

Author

Byron J. Adams, W. Berry Lyons, Michael N. Gooseff, John E. Barrett, John C. Priscu, Peter T. Doran, Martijn L. Vandegehuchte, Ross A. Virginia, Eric R. Sokol, Diana H. Wall, Cristina D. Takacs-Vesbach, Diane M. McKnight, and Andrew G. Fountain

Subjects
0106 biological sciences, Time Factors, 010504 meteorology & atmospheric sciences, Climate Change, Climate change, Antarctic Regions, STREAMS, Cyanobacteria, 01 natural sciences, Rivers, Animals, Ecosystem, Glacial period, Meltwater, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Ecology, Desert climate, 010604 marine biology & hydrobiology, Glacier, Biota, Invertebrates, Lakes, Oceanography, Environmental science, Seasons, Polar desert
Abstract

Amplified climate change in polar regions is significantly altering regional ecosystems, yet there are few long-term records documenting these responses. The McMurdo Dry Valleys (MDV) cold desert ecosystem is the largest ice-free area of Antarctica, comprising soils, glaciers, meltwater streams and permanently ice-covered lakes. Multi-decadal records indicate that the MDV exhibited a distinct ecosystem response to an uncharacteristic austral summer and ensuing climatic shift. A decadal summer cooling phase ended in 2002 with intense glacial melt (‘flood year’)—a step-change in water availability triggering distinct changes in the ecosystem. Before 2002, the ecosystem exhibited synchronous behaviour: declining stream flow, decreasing lake levels, thickening lake ice cover, decreasing primary production in lakes and streams, and diminishing soil secondary production. Since 2002, summer air temperatures and solar flux have been relatively consistent, leading to lake level rise, lake ice thinning and elevated stream flow. Biological responses varied; one stream cyanobacterial mat type immediately increased production, but another stream mat type, soil invertebrates and lake primary productivity responded asynchronously a few years after 2002. This ecosystem response to a climatic anomaly demonstrates differential biological community responses to substantial perturbations, and the mediation of biological responses to climate change by changes in physical ecosystem properties. The McMurdo Dry Valleys is the largest ice-free ecosystem in Antarctica. Here, the varied community responses to an anomalous melt season are documented.

Published
2016

35. Processes controlling carbon cycling in Antarctic glacier surface ecosystems

Author

A. Dubnick, Elizabeth Bagshaw, Sean J. Fitzsimons, Martyn Tranter, Jemma L. Wadham, and Andrew G. Fountain

Subjects
Total organic carbon, chemistry.chemical_classification, geography, geography.geographical_feature_category, Geology, Glacier, Carbon cycle, Oceanography, chemistry, Geochemistry and Petrology, Environmental chemistry, Cryoconite, Dissolved organic carbon, Environmental Chemistry, Environmental science, QE, Organic matter, Ecosystem, Autotroph
Abstract

Glacier surface ecosystems, including cryoconite holes and cryolakes, are significant contributors to regional carbon cycles. Incubation experiments to determine the net production (NEP) of organic matter in cryoconite typically have durations of 6-24 hours, and produce a wide range of results, many of which indicate that the system is net heterotrophic. We employ longer term incubations to examine the temporal variation of NEP in cryoconite from the McMurdo Dry Valleys, Antarctica to examine the effect of sediment disturbance on system production, and to understand processes controlling production over the lifetimes of glacier surface ecosystems. The shorter-term incubations have durations of one week and show net heterotrophy. The longer term incubations of approximately one year show net autotrophy, but only after a period of about 40 days (~1000 hours). The control on net organic carbon production is a combination of the rate of diffusion of dissolved inorganic carbon from heterotrophic activity within cryoconite into the water, the rate of carbonate dissolution, and the saturation of carbonate in the water (which is a result of photosynthesis in a closed system). We demonstrate that sediment on glacier surfaces has the potential to accumulate carbon over timescales of months to years.

Published
2016
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36. The Disappearing Cryosphere: Impacts and Ecosystem Responses to Rapid Cryosphere Loss

Author

Sharon Stammerjohn, Andrew G. Fountain, Hugh W. Ducklow, Edward A. G. Schuur, John Campbell, and Mark W. Williams

Subjects
geography, Biogeochemical cycle, geography.geographical_feature_category, Ecology, Global warming, Climate change, Glacier, Habitat destruction, Sea ice, Environmental science, Cryosphere, Ecosystem, sense organs, skin and connective tissue diseases, General Agricultural and Biological Sciences
Abstract

The cryosphere—the portion of the Earth's surface where water is in solid form for at least one month of the year—has been shrinking in response to climate warming. The extents of sea ice, snow, and glaciers, for example, have been decreasing. In response, the ecosystems within the cryosphere and those that depend on the cryosphere have been changing. We identify two principal aspects of ecosystem-level responses to cryosphere loss: (1) trophodynamic alterations resulting from the loss of habitat and species loss or replacement and (2) changes in the rates and mechanisms of biogeochemical storage and cycling of carbon and nutrients, caused by changes in physical forcings or ecological community functioning. These changes affect biota in positive or negative ways, depending on how they interact with the cryosphere. The important outcome, however, is the change and the response the human social system (infrastructure, food, water, recreation) will have to that change.

Published
2012
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37. Hydrological Connectivity of the Landscape of the McMurdo Dry Valleys, Antarctica

Author

W. Berry Lyons, Diane M. McKnight, Michael N. Gooseff, Andrew G. Fountain, and Peter T. Doran

Subjects
Hydrology, Atmospheric Science, geography, geography.geographical_feature_category, Desert climate, General Social Sciences, Climate change, Glacier, STREAMS, Permafrost, Snow, Environmental science, Ecosystem, Computers in Earth Sciences, Water cycle, Earth-Surface Processes, Water Science and Technology
Abstract

The McMurdo Dry Valleys (MDV) of Antarctica are composed of nearly 2000 km 2 of ice-free terrain, supporting a vibrant cold desert ecosystem despite harsh conditions. The ecosystem is largely regulated by the hydrologic cycle within the MDV, which is controlled by climate dynamics. The strength and timing of connections among the hydrologic reservoirs of the MDV (atmosphere, glaciers, soils and permafrost, streams and their hyporheic zones, and lakes) are dependent upon daily, seasonal, and annual surface energy balance. For example, glacier melt occurs during short periods in the summer, providing stream flow to closed-basin lakes. Similarly, the magnitude of sublimation of snow on valley floors and perennial ice covers on lakes is a function of wind, temperature, radiation, and atmospheric water content (humidity). Here, we describe these reservoirs and connections across the landscape to provide an overview of our current understanding of the system, as it is poised to change in response to changing climate in the coming decades. Measurement of hydrologic fluxes and states of hydrologic reservoirs in the MDV provides both a context for quantifying responses to climate change and a careful characterization of the potential direct drivers of ecosystem response. The MDV also provide a unique real-world laboratory in which to study fundamental hydrologic processes (with the exception of rainfall).

Published
2011
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38. Quantifying 20th Century Glacier Change in the Sierra Nevada, California

Author

Hassan J. Basagic and Andrew G. Fountain

Subjects
010506 paleontology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Area change, Magnitude (mathematics), Glacier, Volume change, 01 natural sciences, Climatology, High elevation, Field mapping, Physical geography, Volume loss, Ecology, Evolution, Behavior and Systematics, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Numerous small alpine glaciers occupy the high elevation regions of the central and southern Sierra Nevada, California. An inventory based on 1∶24,000 topographic maps revealed 1719 glaciers and perennial snowfields for a total area of 39.15 ± 0.13 km2. The number of ‘true’ glaciers, versus non-moving ice, is estimated to be 122 covering 14.89 ± 0.08 km2 or 38% of the ice-covered area. Historic photographs, geologic evidence, and field mapping were used to determine the magnitude of area change over the past century at 14 glaciers. The area change between 1903 and 2004 ranged from −31% to −78%, averaging −55%. Based on these values rough estimates of volume change suggest an ice volume loss from 1903 (1.09 km3) to 2004 (0.43 km3) of 0.66 km3 (0.59 km3 water). Rapid retreat occurred over the first half of the 20th century beginning in the 1920s and continued through the 1960s after which recession ceased by the early 1980s and some glaciers advanced. Since the late 1980s glaciers resumed retreat w...

Published
2011
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39. Twentieth Century Glacier Change on Mount Adams, Washington, USA

Author

Matthew J. Hoffman, Danielle J. Sitts, and Andrew G. Fountain

Subjects
geography, Glacier mass balance, geography.geographical_feature_category, Period (geology), Tidewater glacier cycle, Stratovolcano, Glacier, Physical geography, Precipitation, Surge, Ecology, Evolution, Behavior and Systematics, Geology, Mount
Abstract

Mount Adams is a large glacier-clad stratovolcano located in southern Washington, USA. We examined the area change of the 12 glaciers on the mountain during the 20th century using historical topographic maps and aerial photographs. The total glacier area decreased by 49% (31.5 km2 to 16.2 km2) from 1904 to 2006. The glaciers showed a period of retreat during the first half of the century, followed by either a slowing of retreat or an advance from the 1960s to the 1990s. Subsequently, the glaciers resumed their rapid retreat. Glaciers on Mt. Adams show similar trends to those on both Mt. Hood and Mt. Rainier. The qualitative correlation between area change and trends in winter precipitation and summer temperature indicate a largely temperature-driven glacier shrinkage as the climate warmed since the Little Ice Age of the late 19th Century. No century-scale trends were noted in precipitation but decadal-scale variations in winter precipitation appear to enhance or buffer the effects of temperature ...

Published
2010
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40. Trace element and major ion concentrations and dynamics in glacier snow and melt: Eliot Glacier, Oregon Cascades

Author

Andrew G. Fountain, Natalie Kehrwald, Kathleen A. Welch, W. Berry Lyons, and Sarah K. Fortner

Subjects
Hydrology, Strontium, geography, geography.geographical_feature_category, Trace element, chemistry.chemical_element, Weathering, Glacier, STREAMS, Snow, chemistry.chemical_compound, chemistry, Sulfate, Meltwater, Geology, Water Science and Technology
Abstract

We present concentrations of environmentally available (unfiltered acidified 2% v/v HNO3) As, Cu, Cd, Pb, V, Sr, and major ions including Ca2+, Cl−, and SO42− in a July 2005 and a March 2006 shallow snow profile from the lower Eliot Glacier, Mount Hood, Oregon, and its proglacial stream, Eliot Creek. Low enrichment factors (EF) with respect to crustal averages suggests that in fresh March 2006 snow environmentally available elements are derived primarily from lithogenic sources. Soluble salts occurred in lower and less variable concentrations in July 2005 snow than March 2006. Conversely, environmentally available trace elements occurred in greater and more variable concentrations in July 2005 than March 2006 snow. Unlike major solutes, particulate-associated trace elements are not readily eluted during the melt season. Additionally, elevated surface concentrations suggest that they are likely added throughout the year via dry deposition. In a 1-h stream sampling, ratios of dissolved (

Published
2009
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41. A latest Pleistocene and Holocene glacial history and paleoclimate reconstruction at Three Sisters and Broken Top Volcanoes, Oregon, U.S.A

Author

Shaun A. Marcott, Peter J. Sniffen, Andrew G. Fountain, Jim E. O'Connor, and David P. Dethier

Subjects
010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Pleistocene, Glacier, Last Glacial Maximum, 01 natural sciences, Three Sisters, Arts and Humanities (miscellaneous), Moraine, Climatology, Paleoclimatology, General Earth and Planetary Sciences, Physical geography, Glacial period, Geology, Holocene, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

At least three sets of moraines mark distinct glacial stands since the last glacial maximum (LGM) in the Three Sisters region of the Oregon Cascade Range. The oldest stand predates 8.1 ka (defined here as post-LGM), followed by a second between ∼ 2 and 8 ka (Neoglacial) and a third from the Little Ice Age (LIA) advance of the last 300 years. The post-LGM equilibrium line altitudes were 260 ± 100 m lower than that of modern glaciers, requiring 23 ± 9% increased winter snowfall and 1.4 ± 0.5°C cooler summer temperatures than at present. The LIA advance had equilibrium line altitudes 110 ± 40 m lower than at present, implying 10 ± 4% greater winter snowfall and 0.6 ± 0.2°C cooler summer temperatures.

Published
2009
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42. The ‘benchmark glacier’ concept – does it work? Lessons from the North Cascade Range, USA

Author

Frank Granshaw, Andrew G. Fountain, Jon L. Riedel, and Matthew J. Hoffman

Subjects
010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Tidewater glacier cycle, Magnitude (mathematics), Rock glacier, Glacier, Cirque glacier, Glacier morphology, 01 natural sciences, Glacier mass balance, Climatology, Physical geography, Surge, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Benchmark glaciers were established in many alpine areas during the 1960s as part of the International Hydrological Decade to represent ‘typical’ mass and energy processes on glaciers in different climatic regions around the world. These glaciers have received new interest in the past decade because they are used to infer the contribution of alpine glacier wastage to global sea-level rise. We compare South Cascade Glacier, the benchmark glacier for the northwest contiguous USA, and four other secondary glaciers, against the topographic, area and mass changes of 321 glaciers in the surrounding region. Results show that South Cascade Glacier is unusually large, of lower slope and much larger area and had mass losses greater than most other glaciers in the region. Three of the four secondary glaciers were much more typical. Year-to-year variations in mass balance were highly correlated between all five glaciers, and any of these glaciers, including the benchmark glacier, could be used to infer temporal mass variations in the region. However, the use of South Cascade Glacier to estimate area/mass losses for the region would result in overestimating the area/mass changes by a factor of three. Local differences in the magnitude of annual glacier mass balance control cumulative mass changes and area changes. There appears to be no way to select a representative glacier a priori, and knowledge of changes over the region is required. Therefore, there may be great uncertainty in estimates of sea-level rise from the wastage of alpine glaciers based on the benchmark approach. We recommend re-evaluation of regional glacier mass changes inferred from benchmark glaciers in critical regions.

Published
2009
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43. Glacier change in western North America: influences on hydrology, geomorphic hazards and water quality

Author

Sean W. Fleming, R. D. Moore, Roger Wheate, Brian Menounos, Kerstin Stahl, K. Holm, M. Jakob, and Andrew G. Fountain

Subjects
Water resources, Hydrology, geography, geography.geographical_feature_category, Hydrology (agriculture), Moraine, Streamflow, Climate change, Glacier, Surge, Debris, Geology, Water Science and Technology
Abstract

The glaciers of western Canada and the conterminous United States have dominantly retreated since the end of the Little Ice Age (LIA) in the nineteenth century, although average rates of retreat varied from strong in the first-half of the twentieth century, with glaciers stabilizing or even advancing until 1980, and then resuming consistent recession. This retreat has been accompanied by statistically detectable declines in late-summer streamflow from glacier-fed catchments over much of the study area, although there is some geographical variation: over recent decades, glaciers in northwest BC and southwest Yukon have lost mass dominantly by thinning with relatively low rates of terminal retreat, and glacier-fed streams in that region have experienced increasing flows. In many valleys, glacier retreat has produced geomorphic hazards, including outburst floods from moraine-dammed lakes, mass failures from oversteepened valley walls and debris flows generated on moraines. In addition to these hydrologic and geomorphic changes, evidence is presented that glacier retreat will result in higher stream temperatures, possibly transient increases in suspended sediment fluxes and concentrations, and changes in water chemistry. With climate projected to continue warming over the twenty-first century, current trends in hydrology, geomorphology and water quality should continue, with a range of implications for water resources availability and management and hydroecology, particularly for cool and cold-water species such as salmonids. Copyright © 2008 John Wiley & Sons, Ltd.

Published
2009
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44. Hydrologic response to extreme warm and cold summers in the McMurdo Dry Valleys, East Antarctica

Author

Diane M. McKnight, Andrew G. Fountain, Peter T. Doran, Christopher P. McKay, Thomas H. Nylen, Chris Jaros, and John E. Barrett

Subjects
geography, geography.geographical_feature_category, Geology, Last Glacial Maximum, Glacier, Oceanography, Atmospheric temperature, Water level, Ice core, Climatology, Paleoclimatology, Glacial period, Physical geography, Ecology, Evolution, Behavior and Systematics, Sea level
Abstract

The meteorological characteristics and hydrological response of an extreme warm, and cold summer in the McMurdo Dry Valleys are compared. The driver behind the warmer summer conditions was the occurrence of down-valley winds, which were not present during the colder summer. Occurrence of the summer down-valley winds coincided with lower than typical mean sea level pressure in the Ross Sea region. There was no significant difference in the amount of solar radiation received during the two summers. Compared to the cold summer, glaciological and hydrological response to the warm summer in Taylor Valley included significant glacier mass loss, and 3- to nearly 6000-fold increase in annual streamflow. Lake levels decreased slightly during the cold summer, and increased between 0.54 and 1.01 m during the warm summer, effectively erasing the prior 14 years of lake level lowering in a period of three months. Lake level rise during the warm summer was shown to be strongly associated with and increase in degree days above freezing at higher elevations. We suggest that strong summer down-valley winds may have been responsible for the generation of large glacial lakes during the Last Glacial Maximum when ice core records recorded annual temperatures significantly colder than present.

Published
2008
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45. Solute and isotope geochemistry of subsurface ice melt seeps in Taylor Valley, Antarctica

Author

Kathleen A. Welch, W. Berry Lyons, Katherine J. Harris, Anne E. Carey, and Andrew G. Fountain

Subjects
geography, geography.geographical_feature_category, Geochemistry, Geology, Glacier, Permafrost, Petroleum seep, Isotope geochemistry, Glacial period, Water cycle, Geomorphology, Groundwater, Polar desert
Abstract

The McMurdo Dry Valleys of Antarctica are a polar desert region with watersheds dominated by glacial melt. Recent ground exploration reveals unusual surface-fl ow-seep features not directly supplied by glacial melt. Much of this seep water is potentially derived from permafrost, snow patches, refrozen precipitation accumulated in the subsurface, buried glacier ice, or even groundwater from the deep subsurface. Flow features that lack obvious glacier melt sources were identifi ed in archived aerial photographs of Taylor Valley. This valley was surveyed for extant and extinct seeps, and the locations of geomorphic features in fi active seeps were documented. Water samples from seeps were analyzed for major ions and stable isotopes of hydrogen and oxygen. Solute chemistry and isotopic signatures of seeps are distinct from those of nearby streams and glaciers, with the seeps having elevated solute concentrations. All but one seep had water isotopically heavier than water from nearby glaciers and streams, suggesting that seep waters have been substantially modifi ed if they had been derived originally from the same meteoric sources that supply local glaciers and streams. The seeps are important because they compose a previously overlooked component of the desert hydrological cycle. Seep features in the dry valleys are potential terrestrial analogs for the geologically young gullies observed on Mars, which are thought to be evidence of groundwater seepage and surface runoff.

Published
2007
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46. Spatial and morphological change on Eliot Glacier, Mount Hood, Oregon, USA

Author

Keith M. Jackson and Andrew G. Fountain

Subjects
Glacier ice accumulation, 010506 paleontology, geography, Glacier terminus, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Accumulation zone, Tidewater glacier cycle, Rock glacier, Glacier, Glacier morphology, 01 natural sciences, Glacier mass balance, Geomorphology, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Eliot Glacier is a small (1.6 km2) glacier on Mount Hood, Oregon, USA, and its ablation zone is largely covered with rock debris. We examine the interrelated processes of ablation rates, ice thickness and surface velocities to understand the retreat rate of this glacier. Since measurements began in 1901, the glacier has retreated 680 m, lost 19% of its area and thinned by about 50 m at the lower glacier profile before the terminus retreated past that point. The upper profile, 800m up-glacier, has shown thinning and thickening due to a kinematic wave resulting from a cool period during the 1940s–70s, and is currently about the same thickness as in 1940. Overall, the glacier has retreated at a slower rate than other glaciers on Mount Hood. We hypothesize that the rock debris covering the ablation zone reduces Eliot Glacier’s sensitivity to global warming and slows its retreat rate compared to other glaciers on Mount Hood. Spatial variations in debris thickness are the primary factor in controlling spatial variations in melt. A continuity model of debris thickness shows the rate of debris thickening down-glacier is roughly constant and is a result of the compensating effects of strain thickening and debris melt-out from the ice.

Published
2007
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47. 20th-century variations in area of cirque glaciers and glacierets, Rocky Mountain National Park, Rocky Mountains, Colorado, USA

Author

Matthew J. Hoffman, Andrew G. Fountain, and Jonathan M. Achuff

Subjects
010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Range (biology), National park, Cloud cover, Glacier, Cirque glacier, Snow, 01 natural sciences, Climatology, Spring (hydrology), Precipitation, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

Comparison of historic maps and aerial and ground-based photographs for the small cirque glaciers and glacierets of Rocky Mountain National Park in the northern Front Range of Colorado, USA, indicates modest change during the 20th century. The glaciers retreated through the first half of the 20th century, advanced slightly from the mid-1940s to the end of the century and have retreated slightly since. High interannual variability in area and temporal gaps in data complicate the trends. Local climate records indicate a lack of systematic change between 1950 and 1975, but significant warming afterwards. Local topographic effects (e.g. wind redistribution of snow and avalanching) are important influences. These small glaciers respond to changes in regional climate; summer temperature alone is a good predictor of the mass balance of Andrews Glacier (r = -0.93). Spring snowfall is also an important factor. That winter precipitation is not statistically significant supports the notion that these small glaciers gain much snow from wind drift and avalanching, making winter snow accumulation almost indifferent to variations in direct snowfall. Less than expected glacier retreat may be due to increased summer cloudiness.

Published
2007
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48. The aeolian flux of calcium, chloride and nitrate to the McMurdo Dry Valleys landscape: evidence from snow pit analysis

Author

Thomas H. Nylen, Andrew G. Fountain, Nancy A. N. Bertler, Sharon B. Sneed, W. Berry Lyons, Kathleen A. Welch, Michael Handley, Rebecca A. Witherow, and Paul Andrew Mayewski

Subjects
Hydrology, geography, geography.geographical_feature_category, chemistry.chemical_element, Geology, Glacier, Oceanography, Snow, Nitrogen, chemistry.chemical_compound, Flux (metallurgy), chemistry, Nitrate, Soil water, Aeolian processes, Chemical composition, Ecology, Evolution, Behavior and Systematics
Abstract

We have determined the flux of calcium, chloride and nitrate to the McMurdo Dry Valleys region by analysing snow pits for their chemical composition and their snow accumulation using multiple records spanning up to 48 years. The fluxes demonstrate patterns related to elevation and proximity to the ocean. In general, there is a strong relationship between the nitrate flux and snow accumulation, indicating that precipitation rates may have a great influence over the nitrogen concentrations in the soils of the valleys. Aeolian dust transport plays an important role in the deposition of some elements (e.g. Ca2+) into the McMurdo Dry Valleys' soils. Because of the antiquity of some of the soil surfaces in the McMurdo Dry Valleys regions, the accumulated atmospheric flux of salts to the soils has important ecological consequences. Although precipitation may be an important mechanism of salt deposition to the McMurdo Dry Valley surfaces, it is poorly understood because of difficulties in measurement and high losses from sublimation.

Published
2006
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49. A Stable Isotopic Investigation of a Polar Desert Hydrologic System, McMurdo Dry Valleys, Antarctica

Author

Bruce H. Vaughn, Carolyn B. Dowling, W. Berry Lyons, Diane M. McKnight, Michael N. Gooseff, and Andrew G. Fountain

Subjects
Hydrology, Global and Planetary Change, geography, geography.geographical_feature_category, Glacier melt, Stable isotope ratio, Glacier, Inflow, Snow, Oceanography, Glacial period, Meltwater, Ecology, Evolution, Behavior and Systematics, Polar desert, Geology, Earth-Surface Processes
Abstract

The hydrologic system of the coastal McMurdo Dry Valleys, Antarctica, is defined by snow accumulation, glacier melt, stream flow, and retention in closed-basin, ice-covered lakes. During the austral summers from 1993–1996 and 1999–2000 to 2002–2003, fresh snow, snow pits, glacier ice, stream water, and lake waters were sampled for the stable isotopes deuterium (D) and 18O in order to resolve sources of meltwater and the interactions among the various hydrologic reservoirs in the dry valleys. This data set provides a survey of the distribution of natural water isotope abundances within the well-defined dry valley hydrologic system in Taylor Valley, which extends 20 km inland from McMurdo Sound. The three major Taylor Valley lakes are not connected to one another hydrologically, and their levels are maintained by glacial meltwater inflow and perennial ice-cover sublimation. At the valley scale, glacial ice, snow, stream, and lake waters become more depleted in δD with increasing distance from McMur...

Published
2006
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50. Glacier change (1958–1998) in the North Cascades National Park Complex, Washington, USA

Author

Andrew G. Fountain and Frank Granshaw

Subjects
010506 paleontology, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, National park, Elevation, Magnitude (mathematics), Glacier, 01 natural sciences, Glacier mass balance, Period (geology), Precipitation, Physical geography, Surge, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes
Abstract

The spatial characteristics for all glaciers in the North Cascades National Park Complex, USA, were estimated in 1958 and again in 1998. The total glacier area in 1958 was 117.3 ± 1.1 km2; by 1998 the glacier area had decreased to 109.1 ± 1.1 km2, a reduction of 8.2 ± 0.1 km2 (7%). Estimated volume loss during the 40 year period was 0.8 ± 0.1 km3 of ice. This volume loss contributes up to 6% of the August–September stream-flow and equals 16% of the August–September precipitation. No significant correlations were found between magnitude of glacier shrinkage and topographic characteristics of elevation, aspect or slope. However, the smaller glaciers lost proportionally more area than the larger glaciers and had a greater variability in fractional change than larger glaciers. Most of the well-studied alpine glaciers are much larger than the population median, so global estimates of glacier shrinkage, based on these well-studied glaciers, probably underestimate the true magnitude of regional glacier change.

Published
2006
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