Your search keyword '"Benjamin V. Gaglioti"' showing total 42 results

1. Post-fire stabilization of thaw-affected permafrost terrain in northern Alaska

Author

Benjamin M. Jones, Mikhail Z. Kanevskiy, Yuri Shur, Benjamin V. Gaglioti, M. Torre Jorgenson, Melissa K. Ward Jones, Alexandra Veremeeva, Eric A. Miller, and Randi Jandt

Subjects

Medicine, Science

Abstract

Abstract In 2007, the Anaktuvuk River fire burned more than 1000 km2 of arctic tundra in northern Alaska, ~ 50% of which occurred in an area with ice-rich syngenetic permafrost (Yedoma). By 2014, widespread degradation of ice wedges was apparent in the Yedoma region. In a 50 km2 area, thaw subsidence was detected across 15% of the land area in repeat airborne LiDAR data acquired in 2009 and 2014. Updating observations with a 2021 airborne LiDAR dataset show that additional thaw subsidence was detected in

Published

2024

2. Expanding beaver pond distribution in Arctic Alaska, 1949 to 2019

Author

Ken D. Tape, Jason A. Clark, Benjamin M. Jones, Seth Kantner, Benjamin V. Gaglioti, Guido Grosse, and Ingmar Nitze

Subjects

Medicine, Science

Abstract

Abstract Beavers were not previously recognized as an Arctic species, and their engineering in the tundra is considered negligible. Recent findings suggest that beavers have moved into Arctic tundra regions and are controlling surface water dynamics, which strongly influence permafrost and landscape stability. Here we use 70 years of satellite images and aerial photography to show the scale and magnitude of northwestward beaver expansion in Alaska, indicated by the construction of over 10,000 beaver ponds in the Arctic tundra. The number of beaver ponds doubled in most areas between ~ 2003 and ~ 2017. Earlier stages of beaver engineering are evident in ~ 1980 imagery, and there is no evidence of beaver engineering in ~ 1952 imagery, consistent with observations from Indigenous communities describing the influx of beavers over the period. Rapidly expanding beaver engineering has created a tundra disturbance regime that appears to be thawing permafrost and exacerbating the effects of climate change.

Published

2022

3. Summer warming explains widespread but not uniform greening in the Arctic tundra biome

Author

Logan T. Berner, Richard Massey, Patrick Jantz, Bruce C. Forbes, Marc Macias-Fauria, Isla Myers-Smith, Timo Kumpula, Gilles Gauthier, Laia Andreu-Hayles, Benjamin V. Gaglioti, Patrick Burns, Pentti Zetterberg, Rosanne D’Arrigo, and Scott J. Goetz

Subjects

Science

Abstract

Satellites provide clear evidence of greening trends in the Arctic, but high-resolution pan-Arctic quantification of these trends is lacking. Here the authors analyse high-resolution Landsat data to show widespread greening in the Arctic, and find that greening trends are linked to summer warming overall but not always locally.

Published

2020

4. Ice roads through lake-rich Arctic watersheds: Integrating climate uncertainty and freshwater habitat responses into adaptive management

Author

Christopher D. Arp, Matthew S. Whitman, Benjamin M. Jones, D. A. Nigro, Vladimir A. Alexeev, Anne Gädeke, Stacey Fritz, Ronald Daanen, Anna K. Liljedahl, F. J. Adams, Benjamin V. Gaglioti, Guido Grosse, Kurt C. Heim, John R. Beaver, Lei Cai, Melanie Engram, and Hannah R. Uher-Koch

Subjects

arctic watersheds, ice roads, freshwater habitat, climate change, petroleum development, adaptive management, Environmental sciences, GE1-350, Ecology, QH540-549.5

Abstract

Vast mosaics of lakes, wetlands, and rivers on the Arctic Coastal Plain give the impression of water surplus. Yet long winters lock freshwater resources in ice, limiting freshwater habitats and water supply for human uses. Increasingly the petroleum industry relies on lakes to build temporary ice roads for winter oil exploration. Permitting water withdrawal for ice roads in Arctic Alaska is dependent on lake depth, ice thickness, and the fish species present. Recent winter warming suggests that more winter water will be available for ice- road construction, yet high interannual variability in ice thickness and summer precipitation complicates habitat impact assessments. To address these concerns, multidisciplinary researchers are working to understand how Arctic freshwater habitats are responding to changes in both climate and water use in northern Alaska. The dynamics of habitat availability and connectivity are being linked to how food webs support fish and waterbirds across diverse freshwater habitats. Moving toward watershed-scale habitat classification coupled with scenario analysis of climate extremes and water withdrawal is increasingly relevant to future resource management decisions in this region. Such progressive refinement in understanding responses to change provides an example of adaptive management focused on ensuring responsible resource development in the Arctic.

Published

2019

5. Multi-Dimensional Remote Sensing Analysis Documents Beaver-Induced Permafrost Degradation, Seward Peninsula, Alaska

Author

Benjamin M. Jones, Ken D. Tape, Jason A. Clark, Allen C. Bondurant, Melissa K. Ward Jones, Benjamin V. Gaglioti, Clayton D. Elder, Chandi Witharana, and Charles E. Miller

Subjects

arctic, beavers, geomorphology, permafrost, remote sensing, thermokarst, Science

Abstract

Beavers have established themselves as a key component of low arctic ecosystems over the past several decades. Beavers are widely recognized as ecosystem engineers, but their effects on permafrost-dominated landscapes in the Arctic remain unclear. In this study, we document the occurrence, reconstruct the timing, and highlight the effects of beaver activity on a small creek valley confined by ice-rich permafrost on the Seward Peninsula, Alaska using multi-dimensional remote sensing analysis of satellite (Landsat-8, Sentinel-2, Planet CubeSat, and DigitalGlobe Inc./MAXAR) and unmanned aircraft systems (UAS) imagery. Beaver activity along the study reach of Swan Lake Creek appeared between 2006 and 2011 with the construction of three dams. Between 2011 and 2017, beaver dam numbers increased, with the peak occurring in 2017 (n = 9). Between 2017 and 2019, the number of dams decreased (n = 6), while the average length of the dams increased from 20 to 33 m. Between 4 and 20 August 2019, following a nine-day period of record rainfall (>125 mm), the well-established dam system failed, triggering the formation of a beaver-induced permafrost degradation feature. During the decade of beaver occupation between 2011 and 2021, the creek valley widened from 33 to 180 m (~450% increase) and the length of the stream channel network increased from ~0.6 km to more than 1.9 km (220% increase) as a result of beaver engineering and beaver-induced permafrost degradation. Comparing vegetation (NDVI) and snow (NDSI) derived indices from Sentinel-2 time-series data acquired between 2017 and 2021 for the beaver-induced permafrost degradation feature and a nearby unaffected control site, showed that peak growing season NDVI was lowered by 23% and that it extended the length of the snow-cover period by 19 days following the permafrost disturbance. Our analysis of multi-dimensional remote sensing data highlights several unique aspects of beaver engineering impacts on ice-rich permafrost landscapes. Our detailed reconstruction of the beaver-induced permafrost degradation event may also prove useful for identifying degradation of ice-rich permafrost in optical time-series datasets across regional scales. Future field- and remote sensing-based observations of this site, and others like it, will provide valuable information for the NSF-funded Arctic Beaver Observation Network (A-BON) and the third phase of the NASA Arctic-Boreal Vulnerability Experiment (ABoVE) Field Campaign.

Published

2021

6. Remote Sensing-Based Statistical Approach for Defining Drained Lake Basins in a Continuous Permafrost Region, North Slope of Alaska

Author

Helena Bergstedt, Benjamin M. Jones, Kenneth Hinkel, Louise Farquharson, Benjamin V. Gaglioti, Andrew D. Parsekian, Mikhail Kanevskiy, Noriaki Ohara, Amy L. Breen, Rodrigo C. Rangel, Guido Grosse, and Ingmar Nitze

Subjects

Landsat, ArcticDEM, Tasseled Cap, Arctic, drained lake basins, lakes, Science

Abstract

Lake formation and drainage are pervasive phenomena in permafrost regions. Drained lake basins (DLBs) are often the most common landforms in lowland permafrost regions in the Arctic (50% to 75% of the landscape). However, detailed assessments of DLB distribution and abundance are limited. In this study, we present a novel and scalable remote sensing-based approach to identifying DLBs in lowland permafrost regions, using the North Slope of Alaska as a case study. We validated this first North Slope-wide DLB data product against several previously published sub-regional scale datasets and manually classified points. The study area covered >71,000 km2, including a >39,000 km2 area not previously covered in existing DLB datasets. Our approach used Landsat-8 multispectral imagery and ArcticDEM data to derive a pixel-by-pixel statistical assessment of likelihood of DLB occurrence in sub-regions with different permafrost and periglacial landscape conditions, as well as to quantify aerial coverage of DLBs on the North Slope of Alaska. The results were consistent with previously published regional DLB datasets (up to 87% agreement) and showed high agreement with manually classified random points (64.4–95.5% for DLB and 83.2–95.4% for non-DLB areas). Validation of the remote sensing-based statistical approach on the North Slope of Alaska indicated that it may be possible to extend this methodology to conduct a comprehensive assessment of DLBs in pan-Arctic lowland permafrost regions. Better resolution of the spatial distribution of DLBs in lowland permafrost regions is important for quantitative studies on landscape diversity, wildlife habitat, permafrost, hydrology, geotechnical conditions, and high-latitude carbon cycling.

Published

2021

7. Timing and Potential Causes of 19th-Century Glacier Advances in Coastal Alaska Based on Tree-Ring Dating and Historical Accounts

Author

Benjamin V. Gaglioti, Daniel H. Mann, Gregory C. Wiles, Benjamin M. Jones, Josh Charlton, Nicholas Wiesenberg, and Laia Andreu-Hayles

Subjects

glaciers, dendrochronology, Little Ice Age, Southeastern Alaska, St. Elias Mountains, climate change, Science

Abstract

The Little Ice Age (LIA), ca. CE 1250–1850, was a cold period of global extent, with the nature and timing of reduced temperatures varying by region. The Gulf of Alaska (GOA) is a key location to study the climatic drivers of glacier fluctuations during the LIA because dendrochronological techniques can provide precise ages of ice advances and retreats. Here, we use dendrochronology to date the most recent advance of La Perouse Glacier in the Fairweather Range of Southeast Alaska. After maintaining a relatively contracted state since at least CE 1200, La Perouse advanced to its maximum LIA position between CE 1850 and 1895. Like many other glaciers bordering the GOA, the La Perouse Glacier reached this maximum position relatively late in the LIA compared with glaciers in other regions. This is curious because reconstructions of paleoclimate in the GOA region indicate the 19th century was not the coldest period of the LIA. Using newly available paleoclimate data, we hypothesize that a combination of moderately cool summers accompanying the Dalton Solar Minimum and exceptionally snowy winters associated with a strengthened Aleutian Low could have caused these relatively late LIA advances. Such a scenario implies that winter climate processes, which are heavily influenced by ocean-atmospheric variability in the North Pacific region, have modulated these coastal glaciers’ sensitivity to shifts in summer temperatures.

Published

2019

8. Lake and drained lake basin systems in lowland permafrost regions

Author

Benjamin M. Jones, Guido Grosse, Louise M. Farquharson, Pascale Roy-Léveillée, Alexandra Veremeeva, Mikhail Z. Kanevskiy, Benjamin V. Gaglioti, Amy L. Breen, Andrew D. Parsekian, Mathias Ulrich, and Kenneth M. Hinkel

Subjects

Atmospheric Science, Pollution, Nature and Landscape Conservation, Earth-Surface Processes

Published

2022

9. Is the modern-day dieback of yellow-cedar unprecedented?

Author

Greg Wiles, N. Wiesenberg, Benjamin V. Gaglioti, and Daniel H. Mann

Subjects

Global and Planetary Change, Geography, Ecology, biology, Forestry, Morpho, biology.organism_classification, Snag

Abstract

In Southeast Alaska, many stands of yellow-cedar (Callitropsis nootkatensis (D. Don) Oerst. ex D.P. Little; hereinafter “YC”) contain numerous standing, dead snags. Snag-age estimates based on tree morphology have been used to support the interpretation that a warming climate after ca. 1880 has triggered unprecedented YC dieback. Here, we present new estimates of YC snag longevity by cross-dating 61 snags with morphologies that suggest they stood dead for extended periods. All but four of these snags have lost their outermost rings to decay, so we estimate when they died using a new method based on wood-ablation rates measured in six living trees that display partial cambial dieback. The results indicate that ∼59% of YC snags that lost their branches to decay (Class 5 snags) have remained standing for >200 years, and some for as long as 450 years (snag longevity mean ± SD: 233 ± 92 years). These findings, along with supporting evidence from historical photos, dendrochronology, and snag-morphology surveys in the published literature suggest that episodes of YC dieback also occurred before 1880 and before significant anthropogenic warming began. The roles played by climate change in these earlier dieback events remain to be further explored.

Published

2021

10. A narrow window of summer temperatures associated with shrub growth in Arctic Alaska

Author

Laia Andreu-Hayles, Benjamin V Gaglioti, Logan T Berner, Mathieu Levesque, Kevin J Anchukaitis, Scott J Goetz, and Rosanne D’Arrigo

Subjects

Alaska, NDVI, remote sensing, shrubs, tree rings, tundra, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

Warming in recent decades has triggered shrub expansion in Arctic and alpine tundra, which is transforming these temperature-limited ecosystems and altering carbon and nutrient cycles, fire regimes, permafrost stability, land-surface climate-feedbacks, and wildlife habitat. Where and when Arctic shrub expansion happens in the future will depend in part on how different shrub communities respond to warming air temperatures. Here, we analyze a shrub ring-width network of 18 sites consisting of Salix spp. and Alnus viridis growing across the North Slope of Alaska (68–71 ° N; 164–149 ° W) to assess shrub temperature sensitivity and compare radial growth patterns with satellite NDVI (normalized difference vegetation index) data since 1982. Regardless of site conditions and taxa, all shrubs shared a common year-to-year growth variability and had a positive response to daily maximum air temperatures (Tmax) from ca. May 31 (i.e. Tmax ∼6 ° C) to early July (i.e. Tmax ∼12 ° C), two-thirds of which were significant correlations. Thus, the month of June had the highest shrub growth-temperature sensitivity. This period coincides with the seasonal increase in temperature and phenological green up on the North Slope indicated by both field observations and the seasonal cycle of NDVI (a proxy of photosynthetic activity). Nearly all of the sampled shrubs (98%) initiated their growth after 1960, with 74% initiated since 1980. This post-1980 shrub-recruitment pulse coincided with ∼2 °C warmer June temperatures compared to prior periods, as well as with positive trends in shrub basal area increments and peak summer NDVI. Significant correlations between shrub growth and peak summer NDVI indicate these radial growth patterns in shrubs reflect tundra productivity at a broader scale and that tundra vegetation on the North Slope of Alaska underwent a greening trend between 1980 and 2012.

Published

2020

11. Late Pleistocene shrub expansion preceded megafauna turnover and extinctions in eastern Beringia

Author

Alistair J. Monteath, Benjamin V. Gaglioti, Mary E. Edwards, and Duane Froese

Subjects

Mammals, Multidisciplinary, Climate, Population Dynamics, Animals, Paleontology, Biodiversity, Extinction, Biological, Tundra, Betula, History, Ancient

Abstract

Significance Megafauna strongly influence vegetation structure, and population declines can alter ecosystem functioning. Overhunting of grazing megafauna is argued to have driven the collapse of widespread, northern steppe-tundra and its replacement by woody vegetation at the end of the ice age. However, in Alaska and Yukon, mammoth and horse became extinct around the time that steppe-tundra was replaced by shrub tundra, leaving it unclear whether this vegetation change caused, or was caused by, reduced megafauna populations. Comparison of accurately dated pollen records with a radiocarbon-dated bone chronology shows that shrubs began expanding before grazer populations declined. This indicates that climate was the primary control of steppe-tundra persistence and that climate-driven vegetation change may pose threats to faunal diversity in the future.

Published

2021

12. Remote Sensing-Based Statistical Approach for Defining Drained Lake Basins in a Continuous Permafrost Region, North Slope of Alaska

Author

Louise M. Farquharson, Benjamin V. Gaglioti, R. C. Rangel, Kenneth M. Hinkel, Noriaki Ohara, Benjamin M. Jones, Helena Bergstedt, Amy L. Breen, Andrew D. Parsekian, Guido Grosse, Mikhail Kanevskiy, and Ingmar Nitze

Subjects

North Slope, 010504 meteorology & atmospheric sciences, thermokarst, Science, 0211 other engineering and technologies, drained lake basins, 02 engineering and technology, Permafrost, Spatial distribution, 01 natural sciences, Thermokarst, Hydrology (agriculture), Arctic, lakes, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences, Remote sensing, geography, geography.geographical_feature_category, Landform, 15. Life on land, Tasseled Cap, ArcticDEM, Habitat, 13. Climate action, General Earth and Planetary Sciences, Scale (map), Landsat, Alaska, Geology, permafrost, lake drainage

Abstract

Lake formation and drainage are pervasive phenomena in permafrost regions. Drained lake basins (DLBs) are often the most common landforms in lowland permafrost regions in the Arctic (50% to 75% of the landscape). However, detailed assessments of DLB distribution and abundance are limited. In this study, we present a novel and scalable remote sensing-based approach to identifying DLBs in lowland permafrost regions, using the North Slope of Alaska as a case study. We validated this first North Slope-wide DLB data product against several previously published sub-regional scale datasets and manually classified points. The study area covered >71,000 km2, including a >39,000 km2 area not previously covered in existing DLB datasets. Our approach used Landsat-8 multispectral imagery and ArcticDEM data to derive a pixel-by-pixel statistical assessment of likelihood of DLB occurrence in sub-regions with different permafrost and periglacial landscape conditions, as well as to quantify aerial coverage of DLBs on the North Slope of Alaska. The results were consistent with previously published regional DLB datasets (up to 87% agreement) and showed high agreement with manually classified random points (64.4–95.5% for DLB and 83.2–95.4% for non-DLB areas). Validation of the remote sensing-based statistical approach on the North Slope of Alaska indicated that it may be possible to extend this methodology to conduct a comprehensive assessment of DLBs in pan-Arctic lowland permafrost regions. Better resolution of the spatial distribution of DLBs in lowland permafrost regions is important for quantitative studies on landscape diversity, wildlife habitat, permafrost, hydrology, geotechnical conditions, and high-latitude carbon cycling.

Published

2021

13. Traumatic Resin Ducts in Alaska Mountain Hemlock Trees Provide a New Proxy for Winter Storminess

Author

Markus Stoffel, Daniel H. Mann, Gregory C. Wiles, A. Park Williams, Laia Andreu-Hayles, Benjamin V. Gaglioti, Rose Oelkers, and Benjamin M. Jones

Subjects

Atmospheric Science, Dendrochronology, 010504 meteorology & atmospheric sciences, Winter storm, Soil Science, Climate change, Aquatic Science, Tsuga mertensiana, 01 natural sciences, Treeline, Proxy (climate), ddc:550, Ecosystem, North Pacific, Traumatic resin ducts, 0105 earth and related environmental sciences, Water Science and Technology, ddc:333.7-333.9, Ecology, biology, Winter storminess, Paleontology, Forestry, Krummholz, biology.organism_classification, Geophysics, Environmental science, Aleutian Low, Physical geography, Pressure system

Abstract

Winter is a critical season for land‐surface feedbacks and ecosystem processes; however, most high‐latitude paleo‐environmental reconstructions are blind to cold season conditions. Here we introduce a winter‐sensitive, paleo‐proxy record that is based on the relative frequency of tangential rows of traumatic resin ducts (TRDs) in the annual growth rings of mountain hemlocks (Tsuga mertensiana) growing near treeline in Southeast Alaska. Hemlocks produce a row of TRDs in the earlywood portion of their annual rings in response to cambial damage incurred during winter. Multidecadal bouts of TRD production were followed by growth‐leader replacement, reaction wood formation, and divergence in radial growth between storm‐damaged trees and less exposed mountain hemlock forests. These patterns are consistent with TRDs being a response to tree damage caused by ice and snowstorms, a conclusion supported by the krummholz tree architecture at these sites. This relationship is further corroborated by significant correlations between our TRD record and the strength of the wintertime Aleutian Low (AL) pressure system that is linked to tree‐damaging agents like wind, precipitation, and ice storm strength in Southeast Alaska. The combined TRD/krummholz architecture record indicates that abrupt shifts between strong and weak AL phases occurred every several decades since CE 1700 and that the 1800s had relatively long AL phases with heavy snowpacks. In addition to describing the magnitude and tempo of wintertime climate change in Northwestern North America, these results suggest that North Pacific Decadal Variability underlies the long‐term dynamics of treeline ecosystems along the northeast Pacific coast.

Published

2019

14. Ice roads through lake-rich Arctic watersheds: Integrating climate uncertainty and freshwater habitat responses into adaptive management

Author

Stacey Fritz, Guido Grosse, Anne Gädeke, Vladimir A. Alexeev, Christopher D. Arp, Kurt C. Heim, Benjamin M. Jones, M. J. Engram, Hannah R. Uher-Koch, Lei Cai, Debora A. Nigro, Ronald P. Daanen, Matthew S. Whitman, Benjamin V. Gaglioti, John R. Beaver, Anna K. Liljedahl, and F. J. Adams

Subjects

adaptive management, 010506 paleontology, 010504 meteorology & atmospheric sciences, Water supply, Climate change, Wetland, 01 natural sciences, ice roads, petroleum development, lcsh:QH540-549.5, 14. Life underwater, Precipitation, arctic watersheds, lcsh:Environmental sciences, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Earth-Surface Processes, lcsh:GE1-350, Global and Planetary Change, geography, geography.geographical_feature_category, business.industry, 15. Life on land, Fishery, Adaptive management, climate change, Arctic, Habitat, 13. Climate action, freshwater habitat, Environmental science, lcsh:Ecology, business, Water use

Abstract

Vast mosaics of lakes, wetlands, and rivers on the Arctic Coastal Plain give the impression of water surplus. Yet long winters lock freshwater resources in ice, limiting freshwater habitats and water supply for human uses. Increasingly the petroleum industry relies on lakes to build temporary ice roads for winter oil exploration. Permitting water withdrawal for ice roads in Arctic Alaska is dependent on lake depth, ice thickness, and the fish species present. Recent winter warming suggests that more winter water will be available for ice- road construction, yet high interannual variability in ice thickness and summer precipitation complicates habitat impact assessments. To address these concerns, multidisciplinary researchers are working to understand how Arctic freshwater habitats are responding to changes in both climate and water use in northern Alaska. The dynamics of habitat availability and connectivity are being linked to how food webs support fish and waterbirds across diverse freshwater habitats. Moving toward watershed-scale habitat classification coupled with scenario analysis of climate extremes and water withdrawal is increasingly relevant to future resource management decisions in this region. Such progressive refinement in understanding responses to change provides an example of adaptive management focused on ensuring responsible resource development in the Arctic.

Published

2019

15. Tussocks Enduring or Shrubs Greening: Alternate Responses to Changing Fire Regimes in the Noatak River Valley, Alaska

Author

Benjamin M. Jones, Daniel H. Mann, Laia Andreu-Hayles, Logan T. Berner, Rosanne D'Arrigo, A. P. Williams, Benjamin V. Gaglioti, Scott J. Goetz, and K. M. Orndahl

Subjects

Hydrology, Atmospheric Science, River valley, Ecology, Fire regime, Tussock, Paleontology, Soil Science, Forestry, Aquatic Science, Permafrost, Greening, Environmental science, Fire ecology, Water Science and Technology

Published

2021

16. Geophysical Observations of Taliks Below Drained Lake Basins on the Arctic Coastal Plain of Alaska

Author

Andrew D. Parsekian, Vladimir E. Romanovsky, K. M. Hinkel, Mikhail Kanevskiy, R. C. Rangel, Benjamin V. Gaglioti, Noriaki Ohara, A. Creighton, Helena Bergstedt, Benjamin M. Jones, Amy L. Breen, and Louise M. Farquharson

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Coastal plain, 010502 geochemistry & geophysics, 01 natural sciences, The arctic, Geophysics, Oceanography, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Geology, 0105 earth and related environmental sciences

Published

2021

17. Aeolian stratigraphy describes ice-age paleoenvironments in unglaciated Arctic Alaska

Author

Michael L. Kunz, Pamela Groves, Benjamin V. Gaglioti, Benjamin M. Jones, Louise M. Farquharson, Richard E. Reanier, Matthew J. Wooller, and Daniel H. Mann

Subjects

010506 paleontology, Archeology, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Yedoma, Geology, Last Glacial Maximum, 15. Life on land, Permafrost, 01 natural sciences, Arctic, 13. Climate action, Loess, Ice age, Aeolian processes, Physical geography, Ecology, Evolution, Behavior and Systematics, Holocene, 0105 earth and related environmental sciences

Abstract

Terrestrial paleoenvironmental records with high dating resolution extending into the last ice age are rare from the western Arctic. Such records can test the synchronicity and extent of ice-age climatic events and define how Arctic landscapes respond to rapid climate changes. Here we describe the stratigraphy and sedimentology of a yedoma deposit in Arctic Alaska (the Carter Section) dating to between 37,000 and 9000 calibrated radiocarbon years BP (37–9 ka) and containing detailed records of loess and sand-sheet sedimentation, soil development, carbon storage, and permafrost dynamics. Alternation between sand-sheet and loess deposition provides a proxy for the extent and activity of the Ikpikpuk Sand Sea (ISS), a large dune field located immediately upwind. Warm, moist interstadial times (ca. 37, 36.3–32.5, and 15–13 ka) triggered floodplain aggradation, permafrost thaw, reduced loess deposition, increased vegetation cover, and rapid soil development accompanied by enhanced carbon storage. During the Last Glacial Maximum (LGM, ca. 28–18 ka), rapid loess deposition took place on a landscape where vegetation was sparse and non-woody. The most intense aeolian activity occurred after the LGM between ca. 18 and 15 ka when sand sheets fringing the ISS expanded over the site, possibly in response to increasingly droughty conditions as summers warmed and active layers deepened. With the exception of this lagged LGM response, the record of aeolian activity at the Carter Section correlates with other paleoenvironmental records from unglaciated Siberia and Alaska. Overall, rapid shifts in geomorphology, soils, vegetation, and permafrost portray an ice-age landscape where, in contrast to the Holocene, environmental change was chronic and dominated by aeolian processes.

Published

2018

18. Greenhouse gas emissions from diverse Arctic Alaskan lakes are dominated by young carbon

Author

Christopher D. Arp, Jordan L. Schnell, John W. Pohlman, C. Elder, Benjamin V. Gaglioti, Amy Townsend-Small, Kenneth M. Hinkel, Xiaomei Xu, Claudia I. Czimczik, and Jennifer Walker

Subjects

chemistry.chemical_classification, 010504 meteorology & atmospheric sciences, Pleistocene, Earth science, Flux, Environmental Science (miscellaneous), 010502 geochemistry & geophysics, Permafrost, 01 natural sciences, Substrate (marine biology), Current (stream), chemistry, Arctic, Greenhouse gas, Environmental science, Organic matter, Social Sciences (miscellaneous), 0105 earth and related environmental sciences

Abstract

Climate-sensitive Arctic lakes have been identified as conduits for ancient permafrost-carbon (C) emissions and as such accelerate warming. However, the environmental factors that control emission pathways and their sources are unclear; this complicates upscaling, forecasting and climate-impact-assessment efforts. Here we show that current whole-lake CH4 and CO2 emissions from widespread lakes in Arctic Alaska primarily originate from organic matter fixed within the past 3–4 millennia (modern to 3,300 ± 70 years before the present), and not from Pleistocene permafrost C. Furthermore, almost 100% of the annual diffusive C flux is emitted as CO2. Although the lakes mostly processed younger C (89 ± 3% of total C emissions), minor contributions from ancient C sources were two times greater in fine-textured versus coarse-textured Pleistocene sediments, which emphasizes the importance of the underlying geological substrate in current and future emissions. This spatially extensive survey considered the environmental and temporal variability necessary to monitor and forecast the fate of ancient permafrost C as Arctic warming progresses. A spatially extensive survey of lake CH4 and CO2 emissions in Arctic Alaska shows the source material to be primarily relatively young organic matter (up to about 3,500 years old). Contributions from ancient C sources were twice as large in fine textured sediments.

Published

2018

19. Multi-Dimensional Remote Sensing Analysis Documents Beaver-Induced Permafrost Degradation, Seward Peninsula, Alaska

Author

Jason A. Clark, Benjamin V. Gaglioti, Benjamin M. Jones, Charles E. Miller, Melissa K. Ward Jones, Ken D. Tape, Chandi Witharana, C. Elder, and Allen C. Bondurant

Subjects

geography, Beaver, geography.geographical_feature_category, biology, thermokarst, Science, Beaver dam, geomorphology, Vegetation, Permafrost, Tundra, Normalized Difference Vegetation Index, Thermokarst, remote sensing, arctic, beavers, permafrost, tundra, Arctic, biology.animal, General Earth and Planetary Sciences, Environmental science, Remote sensing

Abstract

Beavers have established themselves as a key component of low arctic ecosystems over the past several decades. Beavers are widely recognized as ecosystem engineers, but their effects on permafrost-dominated landscapes in the Arctic remain unclear. In this study, we document the occurrence, reconstruct the timing, and highlight the effects of beaver activity on a small creek valley confined by ice-rich permafrost on the Seward Peninsula, Alaska using multi-dimensional remote sensing analysis of satellite (Landsat-8, Sentinel-2, Planet CubeSat, and DigitalGlobe Inc./MAXAR) and unmanned aircraft systems (UAS) imagery. Beaver activity along the study reach of Swan Lake Creek appeared between 2006 and 2011 with the construction of three dams. Between 2011 and 2017, beaver dam numbers increased, with the peak occurring in 2017 (n = 9). Between 2017 and 2019, the number of dams decreased (n = 6), while the average length of the dams increased from 20 to 33 m. Between 4 and 20 August 2019, following a nine-day period of record rainfall (>125 mm), the well-established dam system failed, triggering the formation of a beaver-induced permafrost degradation feature. During the decade of beaver occupation between 2011 and 2021, the creek valley widened from 33 to 180 m (~450% increase) and the length of the stream channel network increased from ~0.6 km to more than 1.9 km (220% increase) as a result of beaver engineering and beaver-induced permafrost degradation. Comparing vegetation (NDVI) and snow (NDSI) derived indices from Sentinel-2 time-series data acquired between 2017 and 2021 for the beaver-induced permafrost degradation feature and a nearby unaffected control site, showed that peak growing season NDVI was lowered by 23% and that it extended the length of the snow-cover period by 19 days following the permafrost disturbance. Our analysis of multi-dimensional remote sensing data highlights several unique aspects of beaver engineering impacts on ice-rich permafrost landscapes. Our detailed reconstruction of the beaver-induced permafrost degradation event may also prove useful for identifying degradation of ice-rich permafrost in optical time-series datasets across regional scales. Future field- and remote sensing-based observations of this site, and others like it, will provide valuable information for the NSF-funded Arctic Beaver Observation Network (A-BON) and the third phase of the NASA Arctic-Boreal Vulnerability Experiment (ABoVE) Field Campaign.

Published

2021

20. Younger-Dryas cooling and sea-ice feedbacks were prominent features of the Pleistocene-Holocene transition in Arctic Alaska

Author

Pamela Groves, Michael L. Kunz, Richard E. Reanier, Daniel H. Mann, Benjamin M. Jones, Gregory C. Wiles, Matthew J. Wooller, Benjamin V. Gaglioti, and Carson A. Baughman

Subjects

Arctic sea ice decline, 010506 paleontology, Archeology, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Arctic dipole anomaly, Geology, 15. Life on land, 01 natural sciences, Arctic geoengineering, Oceanography, Arctic, 13. Climate action, Glacial period, Younger Dryas, Arctic ecology, Ecology, Evolution, Behavior and Systematics, Holocene, 0105 earth and related environmental sciences

Abstract

Declining sea-ice extent is currently amplifying climate warming in the Arctic. Instrumental records at high latitudes are too short-term to provide sufficient historical context for these trends, so paleoclimate archives are needed to better understand the functioning of the sea ice-albedo feedback. Here we use the oxygen isotope values of wood cellulose in living and sub-fossil willow shrubs (δ18Owc) (Salix spp.) that have been radiocarbon-dated (14C) to produce a multi-millennial record of climatic change on Alaska's North Slope during the Pleistocene-Holocene transition (13,500–7500 calibrated 14C years before present; 13.5–7.5 ka). We first analyzed the spatial and temporal patterns of δ18Owc in living willows growing at upland sites and found that over the last 30 years δ18Owc values in individual growth rings correlate with local summer temperature and inter-annual variations in summer sea-ice extent. Deglacial δ18Owc values from 145 samples of subfossil willows clearly record the Allerod warm period (∼13.2 ka), the Younger Dryas cold period (12.9–11.7 ka), and the Holocene Thermal Maximum (11.7–9.0 ka). The magnitudes of isotopic changes over these rapid climate oscillations were ∼4.5‰, which is about 60% of the differences in δ18Owc between those willows growing during the last glacial period and today. Modeling of isotope-precipitation relationships based on Rayleigh distillation processes suggests that during the Younger Dryas these large shifts in δ18Owc values were caused by interactions between local temperature and changes in evaporative moisture sources, the latter controlled by sea ice extent in the Arctic Ocean and Bering Sea. Based on these results and on the effects that sea-ice have on climate today, we infer that ocean-derived feedbacks amplified temperature changes and enhanced precipitation in coastal regions of Arctic Alaska during warm times in the past. Today, isotope values in willows on the North Slope of Alaska are similar to those growing during the warmest times of the Pleistocene-Holocene transition, which were times of widespread permafrost thaw and striking ecological changes.

Published

2017

21. Yellow-cedar blue intensity tree ring chronologies as records of climate, Juneau, Alaska, USA

Author

Gregory C. Wiles, Brian Buma, Rose Oelkers, N. Wiesenberg, John Krapek, Benjamin V. Gaglioti, Rob Wilson, Rosanne D'Arrigo, Joshua Charlton, University of St Andrews. School of Earth & Environmental Sciences, University of St Andrews. Scottish Oceans Institute, and University of St Andrews. St Andrews Sustainability Institute

Subjects

010506 paleontology, Global and Planetary Change, GE, 010504 meteorology & atmospheric sciences, Ecology, Tree rings, Dendroclimatology, NDAS, Forestry, Forest health, 01 natural sciences, Blue intensity, Dendrochronology, SDG 13 - Climate Action, Environmental science, Physical geography, Intensity (heat transfer), Alaska, 0105 earth and related environmental sciences, Woody plant, Yellow cedar, GE Environmental Sciences

Abstract

This work was supported by the National Science Foundation’s Paleoclimatic Perspectives on Climatic Change (P2C2) Program grant nos. AGS 1159430, AGS 1502186, AGS 1502150, and PLR 15-04134 and by the Keck Geology Consortium funded by The National Science Foundation under Grant No. (NSF-REU #1358987). This is the first study to generate and analyze the climate signal in Blue Intensity (BI) tree-ring chronologies from Alaskan yellow-cedar (Callitropsis nootkatensis D. Don; Oerst. ex D.P. Little). The latewood BI chronology shows a much stronger temperature sensitivity than ring-widths (RW), and thus can provide information on past climate. The well-replicated BI chronology exhibits a positive January-August average maximum temperature signal for 1900-1975, after which it loses temperature sensitivity following the 1976/77 shift in northeast Pacific climate. The positive temperature response appears to recover and remains strong for the most recent decades although the coming years will continue to test this observation. This temporary loss of temperature sensitivity from about 1976 to 1999 is not evident in RW or in a change in forest health, but is consistent with prior work linking cedar decline to warming. A confounding factor is the uncertain influence of a shift in color variation from the heartwood/sapwood boundary. Future expansion of the yellow-cedar BI network and further investigation of the influence of the heartwood/sapwood transitions in the BI signal will lead to a better understanding of the utility of this species as a climate proxy. Postprint

Published

2019

22. Timing and Potential Causes of 19th-Century Glacier Advances in Coastal Alaska Based on Tree-Ring Dating and Historical Accounts

Author

Gregory C. Wiles, Laia Andreu-Hayles, Benjamin V. Gaglioti, N. Wiesenberg, Benjamin M. Jones, Josh Charlton, and Daniel H. Mann

Subjects

Solar minimum, geography, geography.geographical_feature_category, St. Elias Mountains, 010504 meteorology & atmospheric sciences, Range (biology), Southeastern Alaska, dendrochronology, Climate change, Glacier, 010502 geochemistry & geophysics, 01 natural sciences, climate change, Paleoclimatology, Dendrochronology, Period (geology), Little Ice Age, General Earth and Planetary Sciences, glaciers, lcsh:Q, Physical geography, Little ice age, lcsh:Science, Geology, 0105 earth and related environmental sciences

Abstract

The Little Ice Age (LIA), ca. CE 1250-1850, was a cold period of global extent, with the nature and timing of reduced temperatures varying by region. The Gulf of Alaska (GOA) is a key location to study the climatic drivers of glacier fluctuations during the LIA because dendrochronologogical techniques can provide precise ages of ice advances and retreats. Here, we use dendrochronology to date the most recent advance of La Perouse Glacier in the Fairweather Range of Southeast Alaska. After maintaining a relatively contracted state since at least CE 1200, La Perouse advanced to its maximum LIA position between CE 1850 and 1895. Like many other glaciers bordering the GOA, the La Perouse Glacier reached this maximum position relatively late in the LIA compared with glaciers in other regions. This is curious because reconstructions of paleoclimate in the GOA region indicate the 19th century was not the coldest period of the LIA. Using newly available paleoclimate data, we hypothesize that a combination of moderately cool summers accompanying the Dalton Solar Minimum and exceptionally snowy winters associated with a strengthened Aleutian Low could have caused these relatively late LIA advances. Such a scenario implies that winter climate processes, which are heavily influenced by ocean-atmospheric variability in the North Pacific region, have modulated these coastal glaciers’ sensitivity to shifts in summer temperatures.

Published

2019

23. Climate-driven ecological stability as a globally shared cause of Late Quaternary megafaunal extinctions: the Plaids and Stripes Hypothesis

Author

Beth Shapiro, Daniel H. Mann, Benjamin V. Gaglioti, and Pamela Groves

Subjects

0106 biological sciences, Life on Land, Endangered species, Climate change, 010603 evolutionary biology, 01 natural sciences, terrestrial mammals, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, megafauna, Megafauna, Ice age, allometry, 030304 developmental biology, Ecological stability, 0303 health sciences, ecological disequilibrium, Evolutionary Biology, Extinction, Resistance (ecology), Ecology, extinction, Original Articles, Late Quaternary, Biological Sciences, Geography, Habitat destruction, climate change, Original Article, General Agricultural and Biological Sciences

Abstract

Controversy persists about why so many large‐bodied mammal species went extinct around the end of the last ice age. Resolving this is important for understanding extinction processes in general, for assessing the ecological roles of humans, and for conserving remaining megafaunal species, many of which are endangered today. Here we explore an integrative hypothesis that asserts that an underlying cause of Late Quaternary megafaunal extinctions was a fundamental shift in the spatio‐temporal fabric of ecosystems worldwide. This shift was triggered by the loss of the millennial‐scale climate fluctuations that were characteristic of the ice age but ceased approximately 11700 years ago on most continents. Under ice‐age conditions, which prevailed for much of the preceding 2.6 Ma, these radical and rapid climate changes prevented many ecosystems from fully equilibrating with their contemporary climates. Instead of today's ‘striped’ world in which species' ranges have equilibrated with gradients of temperature, moisture, and seasonality, the ice‐age world was a disequilibrial ‘plaid’ in which species' ranges shifted rapidly and repeatedly over time and space, rarely catching up with contemporary climate. In the transient ecosystems that resulted, certain physiological, anatomical, and ecological attributes shared by megafaunal species pre‐adapted them for success. These traits included greater metabolic and locomotory efficiency, increased resistance to starvation, longer life spans, greater sensory ranges, and the ability to be nomadic or migratory. When the plaid world of the ice age ended, many of the advantages of being large were either lost or became disadvantages. For instance in a striped world, the low population densities and slow reproductive rates associated with large body size reduced the resiliency of megafaunal species to population bottlenecks. As the ice age ended, the downsides of being large in striped environments lowered the extinction thresholds of megafauna worldwide, which then increased the vulnerability of individual species to a variety of proximate threats they had previously tolerated, such as human predation, competition with other species, and habitat loss. For many megafaunal species, the plaid‐to‐stripes transition may have been near the base of a hierarchy of extinction causes whose relative importances varied geographically, temporally, and taxonomically.

Published

2019

24. Inundation, sedimentation, and subsidence creates goose habitat along the Arctic coast of Alaska

Author

Ken D Tape, Paul L Flint, Brandt W Meixell, and Benjamin V Gaglioti

Subjects

coastal erosion, geese, grazing lawn, landscape change, permafrost, subsidence, Environmental technology. Sanitary engineering, TD1-1066, Environmental sciences, GE1-350, Science, Physics, QC1-999

Abstract

The Arctic Coastal Plain of Alaska is characterized by thermokarst lakes and drained lake basins, and the rate of coastal erosion has increased during the last half-century. Portions of the coast are

Published

2013

25. Methane turnover and environmental change from Holocene lipid biomarker records in a thermokarst lake in Arctic Alaska

Author

Kai-Uwe Hinrichs, Matthew J. Wooller, Kevin W. Becker, Benjamin V. Gaglioti, John W. Pohlman, and Marcus Elvert

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Ecology, Environmental change, Paleontology, Climate change, Wetland, 010502 geochemistry & geophysics, 01 natural sciences, Carbon cycle, Thermokarst, Oceanography, Arctic, Anaerobic oxidation of methane, Environmental science, Holocene, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Arctic lakes and wetlands contribute a substantial amount of methane to the contemporary atmosphere, yet profound knowledge gaps remain regarding the intensity and climatic control of past methane emissions from this source. In this study, we reconstruct methane turnover and environmental conditions, including estimates of mean annual and summer temperature, from a thermokarst lake (Lake Qalluuraq) on the Arctic Coastal Plain of northern Alaska for the Holocene by using source-specific lipid biomarkers preserved in a radiocarbon-dated sediment core. Our results document a more prominent role for methane in the carbon cycle when the lake basin was an emergent fen habitat between ~12,300 and ~10,000 cal yr BP, a time period closely coinciding with the Holocene Thermal Maximum (HTM) in North Alaska. Enhanced methane turnover was stimulated by relatively warm temperatures, increased moisture, nutrient supply, and primary productivity. After ~10,000 cal yr BP, a thermokarst lake with abundant submerged mosses evolved, and through the mid-Holocene temperatures were approximately 3°C cooler. Under these conditions, organic matter decomposition was attenuated, which facilitated the accumulation of submerged mosses within a shallower Lake Qalluuraq. Reduced methane assimilation into biomass during the mid-Holocene suggests that thermokarst lakes are carbon sinks during cold periods. In the late-Holocene from ~2700 cal yr BP to the most recent time, however, temperatures and carbon deposition rose and methane oxidation intensified, indicating that more rapid organic matter decomposition and enhanced methane production could amplify climate feedback via potential methane emissions in the future.

Published

2016

26. High-resolution records detect human-caused changes to the boreal forest wildfire regime in interior Alaska

Author

Matthew J. Wooller, Benjamin V. Gaglioti, Bruce P. Finney, Daniel H. Mann, and Benjamin M. Jones

Subjects

0106 biological sciences, Archeology, Global and Planetary Change, Varve, 010504 meteorology & atmospheric sciences, Ecology, Fire regime, Taiga, Paleontology, Climate change, 010603 evolutionary biology, 01 natural sciences, Disturbance (ecology), visual_art, Climatology, visual_art.visual_art_medium, Environmental science, Physical geography, Wildland–urban interface, Surge, Charcoal, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Stand-replacing wildfires are a keystone disturbance in the boreal forest, and they are becoming more common as the climate warms. Paleo-fire archives from the wildland–urban interface can quantify the prehistoric fire regime and assess how both human land-use and climate change impact ecosystem dynamics. Here, we use a combination of a sedimentary charcoal record preserved in varved lake sediments (annually layered) and fire scars in living trees to document changes in local fire return intervals (FRIs) and regional fire activity over the last 500 years. Ace Lake is within the boreal forest, located near the town of Fairbanks in interior Alaska, which was settled by gold miners in AD 1902. In the 400 years before settlement, fires occurred near the lake on average every 58 years. After settlement, fires became much more frequent (average every 18 years), and background charcoal flux rates rose to four times their preindustrial levels, indicating a region-wide increase in burning. Despite this surge in burning, the preindustrial boreal forest ecosystem and permafrost in the watershed have remained intact. Although fire suppression has reduced charcoal influx since the 1950s, an aging fuel load experiencing increasingly warm summers may pose management problems for this and other boreal sites that have similar land-use and fire histories. The large human-caused fire events that we identify can be used to test how increasingly common megafires may alter ecosystem dynamics in the future.

Published

2016

27. Life and extinction of megafauna in the ice-age Arctic

Author

Benjamin V. Gaglioti, Beth Shapiro, Richard E. Reanier, Pamela Groves, Michael L. Kunz, and Daniel H. Mann

Subjects

Climate Change, Climate change, Extinction, Biological, ice age, mammoth steppe, paleoecology, megafauna, Megafauna, Ice age, Animals, Mammoth steppe, Multidisciplinary, Fossils, Arctic Regions, extinction, Ecology, Biological Sciences, Biological, humanities, Climate Action, Arctic, Interglacial, Biological dispersal, Arctic ecology, geographic locations, Geology

Abstract

Understanding the population dynamics of megafauna that inhabited the mammoth steppe provides insights into the causes of extinctions during both the terminal Pleistocene and today. Our study area is Alaska's North Slope, a place where humans were rare when these extinctions occurred. After developing a statistical approach to remove the age artifacts caused by radiocarbon calibration from a large series of dated megafaunal bones, we compare the temporal patterns of bone abundance with climate records. Megafaunal abundance tracked ice age climate, peaking during transitions from cold to warm periods. These results suggest that a defining characteristic of the mammoth steppe was its temporal instability and imply that regional extinctions followed by population reestablishment from distant refugia were characteristic features of ice-age biogeography at high latitudes. It follows that long-distance dispersal was crucial for the long-term persistence of megafaunal species living in the Arctic. Such dispersal was only possible when their rapidly shifting range lands were geographically interconnected. The end of the last ice age was fatally unique because the geographic ranges of arctic megafauna became permanently fragmented after stable, interglacial climate engendered the spread of peatlands at the same time that rising sea level severed former dispersal routes.

Published

2015

28. Distribution and biophysical processes of beaded streams in Arctic permafrost landscapes

Author

Guido Grosse, Christopher D. Arp, Benjamin M. Jones, Kurt C. Heim, Benjamin V. Gaglioti, and Matthew S. Whitman

Subjects

010504 meteorology & atmospheric sciences, lcsh:Life, 0207 environmental engineering, Drainage basin, 02 engineering and technology, STREAMS, Permafrost, 01 natural sciences, Thermokarst, lcsh:QH540-549.5, 020701 environmental engineering, Ecology, Evolution, Behavior and Systematics, 0105 earth and related environmental sciences, Earth-Surface Processes, Riparian zone, Hydrology, geography, geography.geographical_feature_category, Landform, lcsh:QE1-996.5, 15. Life on land, lcsh:Geology, lcsh:QH501-531, Arctic, lcsh:Ecology, Geology, Drainage density

Abstract

Beaded streams are widespread in permafrost regions and are considered a common thermokarst landform. However, little is known about their distribution, how and under what conditions they form, and how their intriguing morphology translates to ecosystem functions and habitat. Here we report on a circum-Arctic survey of beaded streams and a watershed-scale analysis in northern Alaska using remote sensing and field studies. We mapped over 400 channel networks with beaded morphology throughout the continuous permafrost zone of northern Alaska, Canada, and Russia and found the highest abundance associated with medium to high ground-ice content permafrost in moderately sloping terrain. In one Arctic coastal plain watershed, beaded streams accounted for half of the drainage density, occurring primarily as low-order channels initiating from lakes and drained lake basins. Beaded streams predictably transition to alluvial channels with increasing drainage area and decreasing channel slope, although this transition is modified by local controls on water and sediment delivery. The comparisons of one beaded channel using repeat photography between 1948 and 2013 indicate a relatively stable landform, and 14C dating of basal sediments suggest channel formation may be as early as the Pleistocene–Holocene transition. Contemporary processes, such as deep snow accumulation in riparian zones, effectively insulate channel ice and allows for perennial liquid water below most beaded stream pools. Because of this, mean annual temperatures in pool beds are greater than 2 °C, leading to the development of perennial thaw bulbs or taliks underlying these thermokarst features that range from 0.7 to 1.6 m. In the summer, some pools thermally stratify, which reduces permafrost thaw and maintains cold-water habitats. Snowmelt-generated peak flows decrease rapidly by two or more orders of magnitude to summer low flows with slow reach-scale velocity distributions ranging from 0.01 to 0.1 m s−1, yet channel runs still move water rapidly between pools. The repeating spatial pattern associated with beaded stream morphology and hydrological dynamics may provide abundant and optimal foraging habitat for fish. Beaded streams may create important ecosystem functions and habitat in many permafrost landscapes and their distribution and dynamics are only beginning to be recognized in Arctic research.

Published

2015

29. Radiocarbon age-offsets in an arctic lake reveal the long-term response of permafrost carbon to climate change

Author

Michael L. Kunz, Benjamin M. Jones, Benjamin V. Gaglioti, John W. Pohlman, Daniel H. Mann, and Matthew J. Wooller

Subjects

Atmospheric Science, Ecology, Global warming, Paleontology, Soil Science, Climate change, Forestry, Soil carbon, Aquatic Science, Permafrost, Carbon cycle, Oceanography, Arctic, Paleoclimatology, Younger Dryas, Geology, Water Science and Technology

Abstract

Continued warming of the Arctic may cause permafrost to thaw and speed the decomposition of large stores of soil organic carbon (OC), thereby accentuating global warming. However, it is unclear if recent warming has raised the current rates of permafrost OC release to anomalous levels or to what extent soil carbon release is sensitive to climate forcing. Here we use a time series of radiocarbon age-offsets (14C) between the bulk lake sediment and plant macrofossils deposited in an arctic lake as an archive for soil and permafrost OC release over the last 14,500 years. The lake traps and archives OC imported from the watershed and allows us to test whether prior warming events stimulated old carbon release and heightened age-offsets. Today, the age-offset (2 ka; thousand of calibrated years before A.D. 1950) and the depositional rate of ancient OC from the watershed into the lake are relatively low and similar to those during the Younger Dryas cold interval (occurring 12.9–11.7 ka). In contrast, age-offsets were higher (3.0–5.0 ka) when summer air temperatures were warmer than present during the Holocene Thermal Maximum (11.7–9.0 ka) and Bolling-Allerod periods (14.5–12.9 ka). During these warm times, permafrost thaw contributed to ancient OC depositional rates that were ~10 times greater than today. Although permafrost OC was vulnerable to climate warming in the past, we suggest surface soil organic horizons and peat are presently limiting summer thaw and carbon release. As a result, the temperature threshold to trigger widespread permafrost OC release is higher than during previous warming events.

Published

2014

30. Classification of freshwater ice conditions on the Alaskan Arctic Coastal Plain using ground penetrating radar and TerraSAR-X satellite data

Author

Benjamin M. Jones, Guido Grosse, Christopher D. Arp, Benjamin V. Gaglioti, Tazio Strozzi, Alessio Gusmeroli, and Matthew S. Whitman

Subjects

Hydrology, geography, geography.geographical_feature_category, Arctic, Coastal plain, General Earth and Planetary Sciences, Cryosphere, Environmental science, Alluvial river, Freshwater ecosystem, Arctic ice pack, Surface water, Channel (geography)

Abstract

Arctic freshwater ecosystems have responded rapidly to climatic changes over the last half century. Lakes and rivers are experiencing a thinning of the seasonal ice cover, which may increase potential over-wintering freshwater habitat, winter water supply for industrial withdrawal, and permafrost degradation. Here, we combined the use of ground penetrating radar GPR and high-resolution HR spotlight TerraSAR-X TSX satellite data 1.25 m resolution to identify and characterize floating ice and grounded ice conditions in lakes, ponds, beaded stream pools, and an alluvial river channel. Classified ice conditions from the GPR and the TSX data showed excellent agreement: 90.6% for a predominantly floating ice lake, 99.7% for a grounded ice lake, 79.0% for a beaded stream course, and 92.1% for the alluvial river channel. A GIS-based analysis of 890 surface water features larger than 0.01 ha showed that 42% of the total surface water area potentially provided over-wintering habitat during the 2012/2013 winter. Lakes accounted for 89% of this area, whereas the alluvial river channel accounted for 10% and ponds and beaded stream pools each accounted for

Published

2013

31. Identification of unrecognized tundra fire events on the north slope of Alaska

Author

Amy L. Breen, Benjamin M. Jones, Michael L. Kunz, Guido Grosse, Christopher D. Arp, Donald A. Walker, Adrian V. Rocha, Benjamin V. Gaglioti, and Daniel H. Mann

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Ecology, Fire regime, Chronosequence, Paleontology, Soil Science, Forestry, Vegetation, Aquatic Science, Tundra, Thermokarst, Arctic, Physical geography, Arctic vegetation, Geomorphology, Arctic ecology, Geology, Water Science and Technology

Abstract

[1] Characteristics of the natural fire regime are poorly resolved in the Arctic, even though fire may play an important role cycling carbon stored in tundra vegetation and soils to the atmosphere. In the course of studying vegetation and permafrost-terrain characteristics along a chronosequence of tundra burn sites from AD 1977, 1993, and 2007 on the North Slope of Alaska, we discovered two large, previously unrecognized tundra fires. The Meade River fire burned an estimated 500 km2 and the Ketik River fire burned an estimated 1200 km2. Based on radiocarbon dating of charred twigs, analysis of historic aerial photography, and regional climate proxy data, these fires likely occurred between AD 1880 and 1920. Together, these events double the estimated burn area on the North Slope of Alaska over the last ~100 to 130 years. Assessment of vegetation succession along the century-scale chronosequence of tundra fire disturbances demonstrates for the first time on the North Slope of Alaska that tundra fires can facilitate the invasion of tundra by shrubs. Degradation of ice-rich permafrost was also evident at the fire sites and likely aided in the presumed changes of the tundra vegetation postfire. Other previously unrecognized tundra fire events likely exist in Alaska and other Arctic regions and identification of these sites is important for better understanding disturbance regimes and carbon cycling in Arctic tundra.

Published

2013

32. Ice-age megafauna in Arctic Alaska: extinction, invasion, survival

Author

Pamela Groves, Daniel H. Mann, Richard E. Reanier, Benjamin V. Gaglioti, and Michael L. Kunz

Subjects

Archeology, Global and Planetary Change, Woolly mammoth, biology, Pleistocene, Ecology, Geology, Steppe bison, biology.organism_classification, Arctic, Megafauna, Ice age, Younger Dryas, Ecology, Evolution, Behavior and Systematics, Mammoth

Abstract

Radical restructuring of the terrestrial, large mammal fauna living in arctic Alaska occurred between 14,000 and 10,000 years ago at the end of the last ice age. Steppe bison, horse, and woolly mammoth became extinct, moose and humans invaded, while muskox and caribou persisted. The ice age megafauna was more diverse in species and possibly contained 6× more individual animals than live in the region today. Megafaunal biomass during the last ice age may have been 30× greater than present. Horse was the dominant species in terms of number of individuals. Lions, short-faced bears, wolves, and possibly grizzly bears comprised the predator/scavenger guild. The youngest mammoth so far discovered lived ca 13,800 years ago, while horses and bison persisted on the North Slope until at least 12,500 years ago during the Younger Dryas cold interval. The first people arrived on the North Slope ca 13,500 years ago. Bone-isotope measurements and foot-loading characteristics suggest megafaunal niches were segregated along a moisture gradient, with the surviving species (muskox and caribou) utilizing the warmer and moister portions of the vegetation mosaic. As the ice age ended, the moisture gradient shifted and eliminated habitats utilized by the dryland, grazing species (bison, horse, mammoth). The proximate cause for this change was regional paludification, the spread of organic soil horizons and peat. End-Pleistocene extinctions in arctic Alaska represent local, not global extinctions since the megafaunal species lost there persisted to later times elsewhere. Hunting seems unlikely as the cause of these extinctions, but it cannot be ruled out as the final blow to megafaunal populations that were already functionally extinct by the time humans arrived in the region.

Published

2013

33. Inland waters and their role in the carbon cycle of Alaska

Author

Kristine L. Verdin, Benjamin V. Gaglioti, Hélène Genet, David Butman, Sarah M. Stackpoole, Robert G. Striegl, and David W. Clow

Subjects

0106 biological sciences, Biogeochemical cycle, 010504 meteorology & atmospheric sciences, Ecology, 010604 marine biology & hydrobiology, Global warming, Primary production, Climate change, Permafrost, 01 natural sciences, Freshwater ecosystem, Carbon cycle, Carbon Cycle, Greenhouse Gases, Lakes, Rivers, Environmental science, Ecosystem, Methane, Alaska, 0105 earth and related environmental sciences

Abstract

The magnitude of Alaska (AK) inland waters carbon (C) fluxes is likely to change in the future due to amplified climate warming impacts on the hydrology and biogeochemical processes in high latitude regions. Although current estimates of major aquatic C fluxes represent an essential baseline against which future change can be compared, a comprehensive assessment for AK has not yet been completed. To address this gap, we combined available data sets and applied consistent methodologies to estimate river lateral C export to the coast, river and lake carbon dioxide (CO2 ) and methane (CH4 ) emissions, and C burial in lakes for the six major hydrologic regions in the state. Estimated total aquatic C flux for AK was 41 Tg C/yr. Major components of this total flux, in Tg C/yr, were 18 for river lateral export, 17 for river CO2 emissions, and 8 for lake CO2 emissions. Lake C burial offset these fluxes by 2 Tg C/yr. River and lake CH4 emissions were 0.03 and 0.10 Tg C/yr, respectively. The Southeast and South central regions had the highest temperature, precipitation, terrestrial net primary productivity (NPP), and C yields (fluxes normalized to land area) were 77 and 42 g C·m-2 ·yr-1 , respectively. Lake CO2 emissions represented over half of the total aquatic flux from the Southwest (37 g C·m-2 ·yr-1 ). The North Slope, Northwest, and Yukon regions had lesser yields (11, 15, and 17 g C·m2 ·yr-1 ), but these estimates may be the most vulnerable to future climate change, because of the heightened sensitivity of arctic and boreal ecosystems to intensified warming. Total aquatic C yield for AK was 27 g C·m-2 ·yr-1 , which represented 16% of the estimated terrestrial NPP. Freshwater ecosystems represent a significant conduit for C loss, and a more comprehensive view of land-water-atmosphere interactions is necessary to predict future climate change impacts on the Alaskan ecosystem C balance.

Published

2016

34. An ~11,200 year paleolimnological perspective for emerging archaeological findings at Quartz Lake, Alaska

Author

Les C. Cwynar, Joshua Kurek, Nancy H. Bigelow, Benjamin V. Gaglioti, Joshua D. Reuther, Carol Gelvin-Reymiller, John P. Smol, and Matthew J. Wooller

Subjects

Total organic carbon, chemistry.chemical_classification, geography, geography.geographical_feature_category, δ13C, δ18O, Sediment, Wetland, Context (language use), Aquatic Science, Archaeology, Oceanography, chemistry, Littoral zone, Organic matter, Geology, Earth-Surface Processes

Abstract

Wetlands and lakes in the Tanana Valley, Alaska, have provided important resources for prehistoric humans who inhabited this region. We examine an ~11,200 cal yr BP record of environmental and paleolimnological changes from Quartz Lake in the middle Tanana Valley. Our data are also presented in the context of recent archaeological findings in the lake’s general vicinity that have 18 associated AMS 14C dates. We analyzed the stable-carbon and nitrogen isotope composition of total organic matter from the core, coupled with oxygen and carbon isotope analyses of Pisidiidae shells (fingernail clams), in addition to chironomid assemblage changes. Lacustrine sediments began to accumulate at ~11,200 cal yr BP. Initially, autochthonous production was low and allochthonous organic input was negligible between 11,000 and 10,500 cal yr BP, and were associated with relatively cool conditions at Quartz Lake at ~10,700 cal yr BP. After 10,500 cal yr BP, autochthonous production was higher coincident with a shift to chironomid assemblages dominated by taxa associated with warmer summer climates. A decrease in δ13C values of total organic carbon (TOC) and organic content of the sediment between 9,000 and 4,000 cal yr BP may indicate declining autochthonous primary production. This period ended with an abrupt (~7 ‰) decrease in the δ18O values from Pisidiidae shells at ~3,000 cal yr BP, which we hypothesize represented an episodic connection (flood) of the lake with flow from the nearby (~6 km) Tanana River. Our findings coincide with evidence for major flooding at other locations connected to the Tanana River and further afield in Alaska. From ~3,000 cal yr BP Quartz Lake subsequently appeared to become a relatively closed system, as indicated by the δ18OPisidiidae and δ13CPisidiidae data that are positively correlated and generally higher, which also correlates with a shift to moderately higher abundances of littoral chironomids. The cause of the transition to closed-basin conditions may have been geomorphic rather than climatic. This evidence of a progressively stronger evaporative influence on the lake’s closed hydrology after ~3,000 cal yr BP is consistent with our modern δ18O and δD water data from Quartz Lake that plot along a regional evaporative line we base on isotopic measurements from other local lakes and rivers.

Published

2012

35. Reconstruction of past methane availability in an Arctic Alaska wetland indicates climate influenced methane release during the past ~12,000 years

Author

John W. Pohlman, Matthew J. Wooller, Benjamin V. Gaglioti, Kai-Uwe Hinrichs, Kevin W. Becker, Marcus Elvert, Katey M. Walter Anthony, Peter G. Langdon, and Miriam C. Jones

Subjects

geography, geography.geographical_feature_category, δ13C, Macrofossil, Wetland, Aquatic Science, Tundra, Methane, law.invention, chemistry.chemical_compound, Oceanography, chemistry, Arctic, law, Environmental science, Radiocarbon dating, Holocene, Earth-Surface Processes

Abstract

Atmospheric contributions of methane from Arctic wetlands during the Holocene are dynamic and linked to climate oscillations. However, long-term records linking climate variability to methane availability in Arctic wetlands are lacking. We present a multi-proxy ~12,000 year paleoecological reconstruction of intermittent methane availability from a radiocarbon-dated sediment core (LQ-West) taken from a shallow tundra lake (Qalluuraq Lake) in Arctic Alaska. Specifically, stable carbon isotopic values of photosynthetic biomarkers and methane are utilized to estimate the proportional contribution of methane-derived carbon to lake-sediment-preserved benthic (chironomids) and pelagic (cladocerans) components over the last ~12,000 years. These results were compared to temperature, hydrologic, and habitat reconstructions from the same site using chironomid assemblage data, oxygen isotopes of chironomid head capsules, and radiocarbon ages of plant macrofossils. Cladoceran ephippia from ~4,000 cal year BP sediments have δ13C values that range from ~−39 to −31‰, suggesting peak methane carbon assimilation at that time. These low δ13C values coincide with an apparent decrease in effective moisture and development of a wetland that included Sphagnum subsecundum. Incorporation of methane-derived carbon by chironomids and cladocerans decreased from ~2,500 to 1,500 cal year BP, coinciding with a temperature decrease. Live-collected chironomids with a radiocarbon age of 1,640 cal year BP, and fossil chironomids from 1,500 cal year BP in the core illustrate that ‘old’ carbon has also contributed to the development of the aquatic ecosystem since ~1,500 cal year BP. The relatively low δ13C values of aquatic invertebrates (as low as −40.5‰) provide evidence of methane incorporation by lake invertebrates, and suggest intermittent climate-linked methane release from the lake throughout the Holocene.

Published

2012

36. Late Pleistocene paleoecology of arctic ground squirrel (Urocitellus parryii) caches and nests from Interior Alaska's mammoth steppe ecosystem, USA

Author

Brian M. Barnes, Benjamin V. Gaglioti, Grant D. Zazula, Matthew J. Wooller, and Alwynne B. Beaudoin

Subjects

Mammoth steppe, Carex albonigra, 010506 paleontology, 010504 meteorology & atmospheric sciences, biology, Ecology, Arctic ground squirrel, Macrofossil, Graminoid, biology.organism_classification, 01 natural sciences, Beringia, Tundra, Arts and Humanities (miscellaneous), Paleoecology, General Earth and Planetary Sciences, Geology, 0105 earth and related environmental sciences, Earth-Surface Processes

Abstract

Botanical analyses of fossil and modern arctic ground squirrel (Urocitellus parryii) caches and nests have been used to reconstruct the past vegetation from some parts of Beringia, but such archives are understudied in Alaska. Five modern and four fossil samples from arctic ground squirrel caches and nests provide information on late Pleistocene vegetation in Eastern Beringia. Modern arctic ground squirrel caches from Alaska's arctic tundra were dominated by willow and grass leaves and grass seeds and bearberries, which were widespread in the local vegetation as confirmed by vegetation surveys. Late Pleistocene caches from Interior Alaska were primarily composed of steppe and dry tundra graminoid and herb seeds. Graminoid cuticle analysis of fossil leaves identifiedCalamagrostis canadensis,Koeleriasp. andCarex albonigraas being common in the fossil samples. Stable carbon isotopes analysis of these graminoid specimens indicated that plants using the C3photosynthetic pathways were present and functioning with medium to high water-use efficiency. Fossil plant taxa and environments from ground squirrel caches in Alaska are similar to other macrofossil assemblages from the Yukon Territory, which supports the existence of a widespread mammoth steppe ecosystem type in Eastern Beringia that persisted throughout much of the late Pleistocene.

Published

2011

37. Pleistocene graminoid-dominated ecosystems in the Arctic

Author

Matthew J. Wooller, Benjamin V. Gaglioti, Grant D. Zazula, Mikhail S. Blinnikov, and Donald A. Walker

Subjects

Archeology, Global and Planetary Change, geography, geography.geographical_feature_category, biology, Ecology, Biome, Macrofossil, Geology, biology.organism_classification, Beringia, Grassland, Spatial heterogeneity, Arctic, Arctic vegetation, Ecology, Evolution, Behavior and Systematics, Mammoth

Abstract

We review evidence obtained from analyses of multiple proxies (floristics, mammal remains, paleoinsects, pollen, macrofossils, plant cuticles, phytoliths, stable isotopes, and modeling) that elucidate the composition and character of the graminoid-dominated ecosystems of the Pleistocene Arctic. The past thirty years have seen a renewed interest in this now-extinct biome, sometimes referred to as “tundra-steppe” (steppe-tundra in North American sources). While many questions remain, converging evidence from many new terrestrial records and proxies coupled with better understanding of paleoclimate dynamics point to the predominance of xeric and cold adapted grassland as the key former vegetation type in the Arctic confirming earlier conjectures completed in the 1960s–1980s. A variety of still existing species of grasses and forbs played key roles in the species assemblages of the time, but their mixtures were not analogous to the tundras of today. Local mosaics based on topography, proximity to the ice sheets and coasts, soil heterogeneity, animal disturbance, and fire regimes were undoubtedly present. However, inadequate coverage of terrestrial proxies exist to resolve this spatial heterogeneity. These past ecosystems were maintained by a combination of dry and cold climate and grazing pressure/disturbance by large (e.g., mammoth and horse) and small (e.g., ground squirrels) mammals. Some recent studies from Eastern Beringia (Alaska) suggest that more progress will be possible when analyses of many proxies are combined at local scales.

Published

2011

38. The detailed palaeoecology of a mid-Wisconsinan interstadial (ca. 32 000 14 C a BP) vegetation surface from interior Alaska

Author

Nancy H. Bigelow, Benjamin V. Gaglioti, Grant D. Zazula, Svetlana Kuzmina, Misha. Blinnikov, Catherine La Farge, Paul Sanborn, and Matthew J. Wooller

Subjects

Ecology, Paleontology, Growing season, Macrofossil, Graminoid, Permafrost, Beringia, Arts and Humanities (miscellaneous), Phytolith, Earth and Planetary Sciences (miscellaneous), medicine, Physical geography, medicine.symptom, Vegetation (pathology), Meltwater, Geology

Abstract

We present a multi-proxy reconstruction from a well-preserved vegetation surface (ca. 32 000 14C a BP) from the Fox Permafrost tunnel near Fairbanks, Alaska. A thick litter layer of plant material on the vegetation surface is consistent with the vegetation lacking evidence of disturbance. Plant macrofossils and graminoid cuticle analysis show the presence of a graminoid assemblage consistent with phytolith data. The pollen data indicate that trees were not local to the site and that Artemisia sp. was present in the region. The insect and bryophyte reconstructions are consistent with the vascular plant reconstruction, indicating the site was at least periodically wet. δ13C values from the graminoids present show a large range encompassing both the wet and dry range displayed by modern graminoids in Alaska. Sequential δ13C analyses conducted along the length of leaves attached to the vegetation surface indicate a seasonal shift towards relatively higher water use efficiency. The lower water use efficiency earlier in the growing season may have stemmed from the use of winter season meltwater by plants at the site – a scenario consistent with the site's cryostratigraphy. Our multi-proxy reconstruction contributes to the limited palaeoecological data available for graminoid-dominated vegetation present in Eastern Beringia and particularly the interior of Alaska during the mid-Wisconsinan interstadial. Copyright © 2011 John Wiley & Sons, Ltd.

Published

2011

39. Developing graminoid cuticle analysis for application to Beringian palaeoecology

Author

K. Severin, Matthew J. Wooller, and Benjamin V. Gaglioti

Subjects

Herbarium, Plant cuticle, Ecology, Cuticle, Botany, Paleoecology, Paleontology, Macrofossil, Vegetation, Biology, Graminoid, Ecology, Evolution, Behavior and Systematics, Beringia

Abstract

Much of Beringia was composed of graminoid (grass and sedge) dominated habitats during the Late-Pleistocene, yet the account of the actual gramioids that were present is relatively vague. The spatial and temporal variabilities of palaeoclimate, mega-fauna, archaeology, and vegetation interactions could be significantly enhanced with accounts of Beringian graminoids. Fossil graminoid foliage is well preserved in permafrost sediments from Beringia and is available for identification using the micro-morphologies of the leaf epidermis (cuticles), which are often consistent with taxonomic identity. We present a scanning electron microscope (SEM) guide to the leaf cuticles of 38 graminoid species shown to be, or suspected of being present in former Eastern Beringian habitats during marine isotope stages (MIS) 2 and 3 (∼ 56,000–12,000 cal. yrs BP). We examine whether modern specimens have sufficient cuticle variability to identify fossil foliage. We surveyed SEM images from herbarium specimens for 50 quantitative and qualitative features on both sides (adaxial and abaxial) of leaves, and entered these into an interactive key program (Delta Editor). Individual species were unique based on the combined presence of 2–4 cuticle features. Replicate samples (n = 5) of 10 species were integrated into a cluster analysis and visually compared using a dendrogram. Overall, fossils that match modern specimens with a Gower's similarity coefficient of 0.80 or higher can be considered a reliable identification match. Several fossil graminoid specimens were compared and identified with our reference collection. Cuticle identification appears to be a viable method for future macrofossil analysis in Beringia.

Published

2010

40. Post-glacial dispersal patterns of Northern pike inferred from an 8800 year old pike (Esox cf. lucius) skull from interior Alaska

Author

Tara L. Fulton, Andres Lopez, Matthew J. Wooller, Beth Shapiro, and Benjamin V. Gaglioti

Subjects

Archeology, Northern pike, Biology, Beringia, law.invention, law, Radiocarbon dating, Glacial period, Paleolimnology, Ecology, Evolution, Behavior and Systematics, Esox, Pike, computer.programming_language, Stable isotopes, Global and Planetary Change, Ancient DNA, Holocene, Ecology, History and Archaeology, Macrofossil, Paleontology, Geology, biology.organism_classification, Esox lucius, Biogeography, Earth Sciences, Biological dispersal, computer, Alaska

Abstract

The biogeography of freshwater fish species during and after late-Pleistocene glaciations relate to how these species are genetically organized today, and the management of these often disjunct populations. Debate exists concerning the biogeography and routes of dispersal for Northern pike (Esox lucius) after the last glaciation. A hypothesis to account for the relatively low modern genetic diversity for E. lucius is post-glacial radiation from refugia, including lakes from within the un-glaciated portions of eastern Beringia. We report the remains of a Northern pike (E. cf. lucius) skull, including bones, teeth, bone collagen and ancient DNA. The remains were preserved at a depth of between 440 and 446 cm in a 670 cm long core of sediment from Quartz Lake, which initiated at ∼11,200 cal yr BP in interior Alaska. A calibrated accelerator mass spectrometer (AMS) radiocarbon age of the collagen extracted from the preserved bones indicated that the organism was dated to 8820 cal yr BP and is bracketed by AMS values from analyses of terrestrial plant macrofossils, avoiding any potential aquatic reservoir effect that could have influenced the radiocarbon age of the bones. Scanning electron microscope images of the specimen show the hinged tooth anatomy typically of E. lucius. Molar C:N (3.5, 1σ = 0.1) value of the collagen from the specimen indicated well-preserved collagen and its mean stable nitrogen isotope value is consistent with the known predatory feeding ecology of E. lucius. Ancient DNA in the bones showed that the specimen was identical to modern E. lucius. Our record of E. lucius from interior Alaska is consistent with a biogeographic scenario involving rapid dispersal of this species from glacial refugia in the northern hemisphere after the last glaciation.

Published

2015

41. Beaded streams of Arctic permafrost landscapes

Author

Benjamin V. Gaglioti, Benjamin M. Jones, Kurt C. Heim, Guido Grosse, Christopher D. Arp, and Matthew S. Whitman

Subjects

Arctic, Ecology, Physical geography, STREAMS, Permafrost, Geology

Abstract

Beaded streams are widespread in permafrost regions and are considered a common thermokarst landform. However, little is known about their distribution, how and under what conditions they form, and how their intriguing morphology translates to ecosystem functions and habitat. Here we report on a Circum-Arctic inventory of beaded streams and a watershed-scale analysis in northern Alaska using remote sensing and field studies. We mapped over 400 channel networks with beaded morphology throughout the continuous permafrost zone of northern Alaska, Canada, and Russia and found the highest abundance associated with medium- to high-ice content permafrost in moderately sloping terrain. In the Fish Creek watershed, beaded streams accounted for half of the drainage density, occurring primarily as low-order channels initiating from lakes and drained lake basins. Beaded streams predictably transition to alluvial channels with increasing drainage area and decreasing channel slope, although this transition is modified by local controls on water and sediment delivery. Comparison of one beaded channel using repeat photography between 1948 and 2013 indicate relatively stable form and 14C dating of basal sediments suggest channel formation may be as early as the Pleistocene–Holocene transition. Contemporary processes, such as deep snow accumulation in stream gulches effectively insulates river ice and allows for perennial liquid water below most beaded stream pools. Because of this, mean annual temperatures in pool beds are greater than 2 °C, leading to the development of perennial thaw bulbs or taliks underlying these thermokarst features. In the summer, some pools stratify thermally, which reduces permafrost thaw and maintains coldwater habitats. Snowmelt generated peak-flows decrease rapidly by two or more orders of magnitude to summer low flows with slow reach-scale velocity distributions ranging from 0.1 to 0.01 m s−1, yet channel runs still move water rapidly between pools. This repeating spatial pattern associated with beaded stream morphology and hydrological dynamics may provide abundant and optimal foraging habitat for fish. Thus, beaded streams may create important ecosystem functions and habitat in many permafrost landscapes and their distribution and dynamics are only beginning to be recognized in Arctic research.

Published

2014

42. Inundation, sedimentation, and subsidence creates goose habitat along the Arctic coast of Alaska

Author

Benjamin V. Gaglioti, Paul L. Flint, Brandt W. Meixell, and Ken D. Tape

Subjects

Black brant, geography, geography.geographical_feature_category, Marsh, Renewable Energy, Sustainability and the Environment, Coastal plain, Public Health, Environmental and Occupational Health, Subsidence, Permafrost, Coastal erosion, Thermokarst, Oceanography, Salt marsh, Geology, General Environmental Science

Abstract

The Arctic Coastal Plain of Alaska is characterized by thermokarst lakes and drained lake basins, and the rate of coastal erosion has increased during the last half-century. Portions of the coast are

Published

2013