Harry Stern Principal Mathematician harry@apl.washington.edu Phone 206-543-7253 |
Biosketch
Harry Stern studies Arctic sea ice and climate using satellite data. Current interests include the changing sea ice habitat of polar bears and narwhals, and the history of Arctic exploration. He participated in the Around the Americas expedition, sailing through the eastern half of the Northwest Passage in 2009. He served as an Associate Editor for the Journal of Geophysical Research—Oceans (2007–2010). He helped to launch the annual Polar Science Weekend at Seattle's Pacific Science Center, and now runs the event. He has a B.S. in mathematics and M.S. in applied mathematics. He has been with the Polar Science Center since 1987 and with the University since 1980.
Department Affiliation
Polar Science Center |
Education
B.S. Mathematics, Stanford University, 1980
M.S. Applied Mathematics, University of Washington, 1982
Projects
RADARSAT Geophysical Processor System at the Polar Science Center |
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Arctic Surface Air Temperatures for the Past 100 Years Accurate fields of Arctic surface air temperature (SAT) are needed for climate studies, but a robust gridded data set of SAT of sufficient length is not available over the entire Arctic. We plan to produce authoritative SAT data sets covering the Arctic Ocean from 1901 to present, which will be used to better understand Arctic climate change. |
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Videos
Polar Science Weekend @ Pacific Science Center This annual event at the Pacific Science Center shares polar science with thousands of visitors. APL-UW researchers inspire appreciation and interest in polar science through dozens of live demonstrations and hands-on activities. |
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10 Mar 2017
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Polar research and technology were presented to thousands of visitors by APL-UW staff during the Polar Science Weekend at Seattle's Pacific Science Center. The goal of is to inspire an appreciation and interest in science through one-on-one, face-to-face interactions between visitors and scientists. Guided by their 'polar passports', over 10,000 visitors learned about the Greenland ice sheet, the diving behavior of narwhals, the difference between sea ice and freshwater ice, how Seagliders work, and much more as they visited dozens of live demonstrations and activities. |
A Look Back to Arctic Climate in the 18th Century Captain James Cook’s logs and maps give insight to late-18th century sea ice conditions north of Bering Strait. |
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15 Nov 2016
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Polar Science Center mathematician Harry Stern used these records to plot the sea ice edge that Cook encountered in 1778. These earliest records of summer ice extent in the Chukchi Sea underscore the dramatic recent changes in arctic climate. |
Focus on Arctic Sea Ice: Current and Future States of a Diminished Sea Ice Cover APL-UW polar scientists are featured in the March edition of the UW TV news magazine UW|360, where they discuss their research on the current and future states of a diminished sea ice cover in the Arctic. |
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7 Mar 2012
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The dramatic melting of Arctic sea ice over the past several summers has generated great interest and concern in the scientific community and among the public. Here, APL-UW polar scientists present their research on the current state of Arctic sea ice. A long-term, downward trend in sea ice volume is clear. |
Publications |
2000-present and while at APL-UW |
Characterizing southeast Greenland fjord surface ice and freshwater flux to support biological applications Moon, T.A., B. Cohen, T.E. Black, K.L. Laidre, H.L. Stern, and I. Joughin, "Characterizing southeast Greenland fjord surface ice and freshwater flux to support biological applications," Cryosphere, 18, 4845-4872, doi:10.5194/tc-18-4845-2024, 2024. |
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29 Oct 2024 |
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Southeast Greenland (SEG) is characterized by complex morphology and environmental processes that create dynamic habitats for top marine predators. Active glaciers producing solid-ice discharge, freshwater flux, offshore sea ice transport, and seasonal landfast-ice formation all contribute to a variable, transient environment within SEG fjord systems. Here, we investigate a selection of physical processes in SEG to provide a regional characterization that reveals physical system processes and supports biological research. SEG fjords exhibit high fjord-to-fjord variability regarding bathymetry, size, shape, and glacial setting, influencing some processes more than others. For example, during fall, the timing of offshore sea ice formation near SEG fjords progresses temporally when moving southward across latitudes, while the timing of offshore sea ice disappearance is less dependent on latitude. The rates of annual freshwater flux into fjords, however, are highly variable across SEG, with annual average input values ranging from ~1 x 108 to ~1.25 x 1010 m3 (~0.112.5 Gt) for individual fjords. Similarly, the rates of solid-ice discharge in SEG fjords vary widely partly due to the irregular distribution of active glaciers across the study area (6070°N). Landfast sea ice, assessed for eight focus fjords, is seasonal and has a spatial distribution highly dependent on individual fjord topography. Conversely, glacial ice is deposited into fjord systems year-round, with the spatial distribution of glacier-derived ice depending on the location of glacier termini. As climate change continues to affect SEG, the evolution of these metrics will vary individually in their response, and next steps should include moving from characterization to system projection. Due to the projected regional ice sheet persistence that will continue to feed glacial ice into fjords, it is possible that SEG could remain a long-term refugium for polar bears and other ice-dependent species on a centennial to millennial scale, demonstrating a need for continued research into the SEG physical environment. |
Narwhal (Monodon monoceros) associations with Greenland summer meltwater release Laidre, K.L. M.J. Zahn, M. Simon, M. Ladegaard, K.M. Stafford, E. Phillips, T. Moon, H.L. Stern, and B. Cohen, "Narwhal (Monodon monoceros) associations with Greenland summer meltwater release," Ecosphere, 15, doi:10.1002/ecs2.70024, 2024. |
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14 Oct 2024 |
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Climate change is rapidly transforming the coastal margins of Greenland. At the same time, there is increasing recognition that marine-terminating glaciers provide unique and critical habitats to ice-associated top predators. We investigated the connection between a top predator occupying glacial fjord systems in Northwest Greenland and the properties of Atlantic-origin water and marine-terminating glaciers through a multiyear interdisciplinary project. Using passive acoustic monitoring, we quantified the summer presence and autumn departure of narwhals (Monodon monoceros) at glacier fronts in Melville Bay and modeled what glacier fjord physical attributes are associated with narwhal occurrence. We found that narwhals are present at glacier fronts after Greenland Ice Sheet peak summer runoff and they remain there during the period when the water column is becoming colder and fresher. Narwhals occupied glacier fronts when ocean temperatures ranged from 0.6 to 0.8°C and salinities between 33.2 and 34.0 psu at around 200 m depth and they departed on their southbound migration between October and November. Narwhals' departure was approximately 4 weeks later in 2019 than in 2018, after an extreme 2019 summer heatwave event that also delayed sea ice formation by 2 months. Our study provides further support for the niche conservative narwhal's preference for cold ocean temperatures. These results may inform projections about how future changes will impact narwhal subpopulations, especially those occupying Greenland glacial fjords. |
A demographic survey of the Davis Strait polar bear subpopulation using physical and genetic capture-recapture-recovery sampling Dunham, K.D., M.G. Dyck, J.V. Ware, A.E. Derocher, E.V. Regehr, H.L. Stern, G.B. Stenson, and D.N. Koons, "A demographic survey of the Davis Strait polar bear subpopulation using physical and genetic capture-recapture-recovery sampling," Mar. Mam. Sci., 40, doi:10.1111/mms.13107, 2024. |
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1 Jul 2024 |
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Conducting assessments to understand the effects of changing environmental conditions on polar bear (Ursus maritimus) demography has become increasingly important to inform management and conservation. Here, we combined physical (20052007) and genetic (20172018) mark-recapture with harvest recovery data (20052018) to estimate demographic rates of the Davis Strait polar bear subpopulation and examine the possible effects of climate, dynamic ice habitat, and prey resources on survival. Large sample sizes (e.g., 2,513 marked animals) allowed us to estimate temporal variation in annual survival rates using multistate mark-recapture-recovery models. We did not detect statistically significant effects of climate, ice habitat, and prey during the 13-year study. Estimated total abundance in 2006 was 2,190, credible interval (CRI) [1,954, 2,454] and 1,944, CRI [1,593, 2,366] in 2018. Geometric mean population growth rate (0.99, 95% CRI [0.97, 1.01]) indicated the subpopulation may have declined slightly between 2006 and 2018. However, we did not detect a declining trend in survival or substantial change in reproductive metrics over this period. Given forecasts of major environmental change we emphasize the need to review monitoring programs for this subpopulation. |
Demographic response of a high-Arctic polar bear (Ursus martitimus) subpopulation to changes in sea ice and subsistence harvest Laidre, K.L., T.W. Arnold, E.V. Regehr, S.N. Atkinson, E.W. Born, O. Wiig, N.J. Lunn, M. Dyck, H.L. Stern, S. Stapleton, B. Cohen, and D. Paetkau, "Demographic response of a high-Arctic polar bear (Ursus martitimus) subpopulation to changes in sea ice and subsistence harvest," Endanger. Species Res., 51, 73-81, doi:10.3354/esr01239, 2023. |
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25 May 2023 |
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Climate change is a long-term threat to polar bears. However, sea-ice loss is hypothesized to provide transient benefits in high latitudes, where thick multiyear ice historically limited biological productivity and seal abundance. We used joint live-recapture and dead-recovery mark-recapture models to analyze data for one of the most northerly polar bear subpopulations, Kane Basin. The data consisted of 277 initial live captures and genetic identifications (19921997 = 150, 2012-2014 = 127), 89 recaptures or re-identifications (19921997 = 53, 20122014 = 36), and 24 harvest returns of research-marked bears during 19922014. We estimated mean annual abundance of 357 bears (95% CI: 221493) for 20132014. This suggests a likely increase relative to our estimate of 224 (95% CI: 145303) bears in the mid-1990s and relative to a previously published estimate of 164 (95% CI: 94234) bears in the mid-1990s that used some of the same data. This is also supported by an apparent increase in the density of bears in eastern Kane Basin during 20122014. Estimates of total survival for females ≥3 yr old (mean ± SE: 0.95 ± 0.04) and their dependent offspring were similar to previous estimates from the 1990s, and estimates of unharvested survival for females ≥3 yr (0.96 ± 0.04) appear sufficient for positive population growth. Estimates of total survival were lower for males ≥3 yr (0.87 ± 0.06). We documented a reduction in mortality associated with subsistence harvest, likely attributable to implementation of a harvest quota by Greenland in 2006. Our findings, together with evidence for increased range sizes, improved body condition for all sex and age classes, and stable reproductive metrics, show that this small high-Arctic polar bear subpopulation remains productive and healthy. These benefits are likely temporary given predictions for continued climate change. |
Glacial ice supports a distinct and undocumented polar bear subpopulation persisting in late 21st-century sea-ice conditions Laidre, K.L. and 18 others including E.V. Regehr, B. Cohen, and H.L. Stern, "Glacial ice supports a distinct and undocumented polar bear subpopulation persisting in late 21st-century sea-ice conditions," Science, 376, 1333-1338, doi:10.1126/science.abk2793, 2022. |
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17 Jun 2022 |
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Polar bears are susceptible to climate warming because of their dependence on sea ice, which is declining rapidly. We present the first evidence for a genetically distinct and functionally isolated group of polar bears in Southeast Greenland. These bears occupy sea-ice conditions resembling those projected for the High Arctic in the late 21st century, with an annual ice-free period that is >100 days longer than the estimated fasting threshold for the species. Whereas polar bears in most of the Arctic depend on annual sea ice to catch seals, Southeast Greenland bears have a year-round hunting platform in the form of freshwater glacial mélange. This suggests that marine-terminating glaciers, although of limited availability, may serve as previously unrecognized climate refugia. Conservation of Southeast Greenland polar bears, which meet criteria for recognition as the world’s 20th polar bear subpopulation, is necessary to preserve the genetic diversity and evolutionary potential of the species. |
Float your boat launching students into the Arctic Ocean Forcucci, D., I. Rigor, W. Ermold, and H. Stern, "Float your boat launching students into the Arctic Ocean," Oceanography, 35, doi:10.5670/oceanog.2022.102, 2022. |
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1 Jun 2022 |
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Our understanding of Arctic sea ice and ocean circulation began with the drift of two wooden boats. Following the legacy of the early Arctic explorers, Float Your Boat (FYB) is a unique and fun outreach program that provides a novel opportunity for students and the public to learn about the Arctic Ocean. Participants decorate toy wooden boats with words and art, and the boats are deployed on Arctic Ocean ice floes by icebreakers. Personal connections to the Arctic develop with the anticipation and excitement of the boats being reported on distant shores years later by beachcombers. |
A novel mark-recapture-recovery survey using genetic sampling for polar bears Ursus maritimus in Baffin Bay Atkinson, S.N., K.L. Laidre, T.W. Arnold, S. Stapleton, E.V. Regehr, E.W. Born, Ø. Wiig, M. Dyck, N.J. Lunn, H.L. Stern, and D. Paetkau, "A novel mark-recapture-recovery survey using genetic sampling for polar bears Ursus maritimus in Baffin Bay," Endanger. Species Res., 46, 105-120, doi:10.3354/esr01148, 2021. |
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7 Oct 2021 |
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Changes in sea-ice dynamics are affecting polar bears Ursus maritimus across their circumpolar range, which highlights the importance of periodic demographic assessments to inform management and conservation. We used genetic mark-recapture-recovery to derive estimates of abundance and survival for the Baffin Bay (BB) polar bear subpopulation the first time this method has been used successfully for this species. Genetic data from tissue samples we collected via biopsy darting were combined with historical physical capture and harvest recovery data. The combined data set consisted of 1410 genetic samples (20112013), 914 physical captures (19931995, 1997), and 234 harvest returns of marked bears (19932013). The estimate of mean subpopulation abundance was 2826 (95% CI = 22843367) in 20122013. Estimates of annual survival (mean ñ SE) were 0.90 ñ 0.05 and 0.78 ñ 0.06 for females and males age >= 2 yr, respectively. The proportion of total mortality of adult females and males that was attributed to legal harvest was 0.16 ñ 0.05 and 0.26 ñ 0.06, respectively. Remote sensing sea-ice data, telemetry data, and spatial distribution of onshore sampling indicated that polar bears were more likely to use offshore sea-ice habitat during the 1990s sampling period compared to the 2010s. Furthermore, in the 1990s, sampling of deep fjords and inland areas was limited, and no offshore sampling occurred in either time period, which precluded comparisons of abundance between the 19931997 and 20112013 study periods. Our findings demonstrate that genetic sampling can be a practical method for demographic assessment of polar bears over large spatial and temporal scales. |
Transient benefits of climate change for a high-Arctic polar bear (Ursus maritimus) subpopulation Laidre, K.L., S.N. Atkinson, E.V. Regehr, H.L. Stern, E.W. Born, Ø. Wiig, N.J. Lunn, M Dyck, P. Heagerty, B.R. Cohen, "Transient benefits of climate change for a high-Arctic polar bear (Ursus maritimus) subpopulation," Global Change Biol., 26, 6251-6265, doi:10.1111/gcb.15286, 2020. |
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1 Nov 2020 |
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Kane Basin (KB) is one of the world's most northerly polar bear (Ursus maritimus) subpopulations, where bears have historically inhabited a mix of thick multiyear and annual sea ice year‐round. Currently, KB is transitioning to a seasonally ice‐free region because of climate change. This ecological shift has been hypothesized to benefit polar bears in the near‐term due to thinner ice with increased biological production, although this has not been demonstrated empirically. We assess sea‐ice changes in KB together with changes in polar bear movements, seasonal ranges, body condition, and reproductive metrics obtained from capturerecapture (physical and genetic) and satellite telemetry studies during two study periods (19931997 and 20122016). The annual cycle of sea‐ice habitat in KB shifted from a year‐round ice platform (~50% coverage in summer) in the 1990s to nearly complete melt‐out in summer (<5% coverage) in the 2010s. The mean duration between sea‐ice retreat and advance increased from 109 to 160 days (p = .004). Between the 1990s and 2010s, adult female (AF) seasonal ranges more than doubled in spring and summer and were significantly larger in all months. Body condition scores improved for all ages and both sexes. Mean litter sizes of cubs‐of‐the‐year (C0s) and yearlings (C1s), and the number of C1s per AF, did not change between decades. The date of spring sea‐ice retreat in the previous year was positively correlated with C1 litter size, suggesting smaller litters following years with earlier sea‐ice breakup. Our study provides evidence for range expansion, improved body condition, and stable reproductive performance in the KB polar bear subpopulation. These changes, together with a likely increasing subpopulation abundance, may reflect the shift from thick, multiyear ice to thinner, seasonal ice with higher biological productivity. The duration of these benefits is unknown because, under unmitigated climate change, continued sea‐ice loss is expected to eventually have negative demographic and ecological effects on all polar bears. |
Estimating statistical errors in retrievals of ice velocity and deformation parameters from satellite images and buoy arrays Dierking, W., H.L. Stern, and J.K. Hutchings, "Estimating statistical errors in retrievals of ice velocity and deformation parameters from satellite images and buoy arrays," Cryosphere, 14, 2999-3016, doi:10.5194/tc-14-2999-2020, 2020. |
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15 Sep 2020 |
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The objective of this note is to provide the background and basic tools to estimate the statistical error of deformation parameters that are calculated from displacement fields retrieved from synthetic aperture radar (SAR) imagery or from location changes of position sensors in an array. We focus here specifically on sea ice drift and deformation. In the most general case, the uncertainties of divergence/convergence, shear, vorticity, and total deformation are dependent on errors in coordinate measurements, the size of the area and the time interval over which these parameters are determined, as well as the velocity gradients within the boundary of the area. If displacements are calculated from sequences of SAR images, a tracking error also has to be considered. Timing errors in position readings are usually very small and can be neglected. We give examples for magnitudes of position and timing errors typical for buoys and SAR sensors, in the latter case supplemented by magnitudes of the tracking error, and apply the derived equations on geometric shapes frequently used for deriving deformation from SAR images and buoy arrays. Our case studies show that the size of the area and the time interval for calculating deformation parameters have to be chosen within certain limits to make sure that the uncertainties are smaller than the magnitude of deformation parameters. |
Interrelated ecological impacts of climate change on an apex predator Laidre, K.L., S. Atkinson, E.V. Regehr, H.L. Stern, E.W. Born, Ø. Wiig, N.J. Lunn, and M. Dyck, "Interrelated ecological impacts of climate change on an apex predator," Ecol. Appl., 30, e02071, doi:10.1002/eap.2071, 2020. |
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1 Jun 2020 |
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Climate change has broad ecological implications for species that rely on sensitive habitats. For some top predators, loss of habitat is expected to lead to cascading behavioral, nutritional, and reproductive changes that ultimately accelerate population declines. In the case of the polar bear (Ursus maritimus), declining Arctic sea ice reduces access to prey and lengthens seasonal fasting periods. We used a novel combination of physical capture, biopsy darting, and visual aerial observation data to project reproductive performance for polar bears by linking sea ice loss to changes in habitat use, body condition (i.e., fatness), and cub production. Satellite telemetry data from 43 (19911997) and 38 (20092015) adult female polar bears in the Baffin Bay subpopulation showed that bears now spend an additional 30 d on land (90 d in total) in the 2000s compared to the 1990s, a change closely correlated with changes in spring sea ice breakup and fall sea ice formation. Body condition declined for all sex, age, and reproductive classes and was positively correlated with sea ice availability in the current and previous year. Furthermore, cub litter size was positively correlated with maternal condition and spring breakup date (i.e., later breakup leading to larger litters), and negatively correlated with the duration of the ice‐free period (i.e., longer ice‐free periods leading to smaller litters). Based on these relationships, we projected reproductive performance three polar bear generations into the future (approximately 35 yr). Results indicate that two‐cub litters, previously the norm, could largely disappear from Baffin Bay as sea ice loss continues. Our findings demonstrate how concurrent analysis of multiple data types collected over long periods from polar bears can provide a mechanistic understanding of the ecological implications of climate change. This information is needed for long‐term conservation planning, which includes quantitative harvest risk assessments that incorporate estimated or assumed trends in future environmental carrying capacity. |
Vulnerability of arctic marine mammals to vessel traffic in the increasingly ice-free Northwest Passage and Northern Sea Route Hauser, D.D.W., K.L. Laidre, and H.L. Stern, "Vulnerability of arctic marine mammals to vessel traffic in the increasingly ice-free Northwest Passage and Northern Sea Route," Proc. Nat. Acad. Sci. USA, 115, 7617-7622, doi:10.1073/pnas.1803543115, 2018 |
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2 Jul 2018 |
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The fabled Northwest Passage and Northern Sea Route that were once the quests of early Western explorers are now increasingly sea ice–free, with routine vessel transits expected by midcentury. The potential impacts of this novel vessel traffic on endemic Arctic marine mammal (AMM) species are unknown despite their critical social and ecological roles in the ecosystem and widely recognized susceptibility to ice loss. We developed a vulnerability assessment of 80 subpopulations of seven AMM species to vessel traffic during the ice-free season. Vulnerability scores were based on the combined influence of spatially explicit exposure to the sea routes and a suite of sensitivity variables. More than half of AMM subpopulations (42/80) are exposed to open-water vessel transits in the Arctic sea routes. Narwhals (Monodon monoceros) were estimated to be most vulnerable to vessel impacts, given their high exposure and sensitivity, and polar bears (Ursus maritimus) were estimated to be the least vulnerable because of their low exposure and sensitivity. Regions with geographic bottlenecks, such as the Bering Strait and eastern Canadian Arctic, were characterized by two to three times higher vulnerability than more remote regions. These pinch points are obligatory pathways for both vessels and migratory AMMs, and so represent potentially high conflict areas but also opportunities for conservation-informed planning. Some of the species and regions identified as least vulnerable were also characterized by high uncertainty, highlighting additional data and monitoring needs. Our quantification of the heterogeneity of risk across AMM species provides a necessary first step toward developing best practices for maritime industries poised to advance into this rapidly changing seascape. |
Indirect effects of sea ice loss on summerfall habitat and behaviour for sympatric populations of an Arctic marine predator Hauser, D.D.W., K.L. Laidre, H.L. Stern, R.S. Suydam, and P.R. Richard, "Indirect effects of sea ice loss on summerfall habitat and behaviour for sympatric populations of an Arctic marine predator," Divers. Distrib., 24, 791-799, doi:10.1111/ddi.12722, 2018. |
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1 Jun 2018 |
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Climate change is fundamentally altering habitats, with complex consequences for species across the globe. The Arctic has warmed 23 times faster than the global average, and unprecedented sea ice loss can have multiple outcomes for ice‐associated marine predators. Our goal was to assess impacts of sea ice loss on population‐specific habitat and behaviour of a migratory Arctic cetacean. |
Reconstructing variability in West Greenland ocean biogeochemistry and bowhead whale (Balaena mysticetus) food web structure using amino acid isotope ratios Pomerleau, C., M.P. Heide-Jørgensen, S.H. Ferguson, H.L. Stern, J.L. Høyer, and G.A. Stern, "Reconstructing variability in West Greenland ocean biogeochemistry and bowhead whale (Balaena mysticetus) food web structure using amino acid isotope ratios," Polar Biol., 40, 2225-2238, doi:10.1007/s00300-017-2136-x, 2017. |
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1 Nov 2017 |
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Climate change is causing physical and biological changes in the polar marine environment, which may impact higher trophic level predators such as the bowhead whale (Balaena mysticetus) and the structure of their food webs. We used bulk stable isotope analysis and compound-specific isotope analysis (CSIA) of individual amino acids (AA) to examine bowhead whale trophic position and the biogeochemistry of one of their feeding grounds, Disko Bay, West Greenland, over a period of 7 years (20072013). We also examined whether environmental conditions such as sea ice concentration and sea surface temperature were causing any interannual variation in isotope data. Bulk δ15N values were consistent across the 7 years of sampling and were similar between sex classes. Bulk δ13C and essential-AAs δ13C values displayed an overall temporal decline of 1.0 and 1.4%, respectively. A significant positive linear relationship was found between δ13C of bulk skin and essential-AAs suggesting that some of the observed isotopic variation in bowhead whales between years reflect changes in the carbon at the base of the food web. There were no correlations between the δ13C and δ15N values of isotopic tracers with sea ice concentrations or sea surface temperatures. The trophic level of bowhead whales remained stable over time despite large interannual variability in ice and temperature regimes. Our results indicate that the recent environmental changes in West Greenland resulted in no trophic perturbation being transferred to bowhead whales during that time period. Our study shows that the novel approach of CSIA-AA can be used effectively to study the combined temporal variation of bowhead whale food web structure and ecosystem isotopic baseline values and detect changes at the species and ecosystem levels. |
Decadal shifts in autumn migration timing by Pacific Arctic beluga whales are related to delayed annual sea ice formation Hauser, D.D.W., K.L. Laidre, K.M. Stafford, H.L. Stern, R.S. Suydam, and P.R. Richard, "Decadal shifts in autumn migration timing by Pacific Arctic beluga whales are related to delayed annual sea ice formation," Global Clim. Change, 23, 2206-2217, doi:10.111/gcb.13564, 2017. |
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1 Jun 2017 |
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Migrations are often influenced by seasonal environmental gradients that are increasingly being altered by climate change. The consequences of rapid changes in Arctic sea ice have the potential to affect migrations of a number of marine species whose timing is temporally matched to seasonal sea ice cover. This topic has not been investigated for Pacific Arctic beluga whales (Delphinapterus leucas) that follow matrilineally maintained autumn migrations in the waters around Alaska and Russia. For the sympatric Eastern Chukchi Sea ('Chukchi') and Eastern Beaufort Sea ('Beaufort') beluga populations, we examined changes in autumn migration timing as related to delayed regional sea ice freeze-up since the 1990s, using two independent data sources (satellite telemetry data and passive acoustics) for both populations. We compared dates of migration between 'early' (19932002) and 'late' (20042012) tagging periods. During the late tagging period, Chukchi belugas had significantly delayed migrations (by 2 to >4 weeks, depending on location) from the Beaufort and Chukchi seas. Spatial analyses also revealed that departure from Beaufort Sea foraging regions by Chukchi whales was postponed in the late period. Chukchi beluga autumn migration timing occurred significantly later as regional sea ice freeze-up timing became later in the Beaufort, Chukchi, and Bering seas. In contrast, Beaufort belugas did not shift migration timing between periods, nor was migration timing related to freeze-up timing, other than for southward migration at the Bering Strait. Passive acoustic data from 2008 to 2014 provided independent and supplementary support for delayed migration from the Beaufort Sea (4 day yr |
Rebuilding beluga stocks in West Greenland Heide-Jørgensen, M.P., R.G. Hansen, S. Fossette, N.H. Nielsen, D.L. Borchers, H. Stern, and L. Witting, "Rebuilding beluga stocks in West Greenland," Anim. Conserv., 20, 282-293, doi:10.1111/acv.12315, 2017. |
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1 Jun 2017 |
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Decisions about sustainable exploitation levels of marine resources are often based on inadequate data, but are nevertheless required for practical purposes. We describe one exception where abundance estimates spanning 30 years and catch data spanning more than 40 years were used in a Bayesian assessment model of belugas Delphinapterus leucas off West Greenland. The model was updated with data from a visual aerial survey on the wintering ground in 2012. Methods that take account of stochastic animal availability by using independent estimates of forward and perpendicular sighting distances were used to estimate beluga abundance. A model that appears to be robust to the presence of a few large groups yielded an estimate of 7456 belugas (cv = 0.44), similar to a conventional distance-sampling estimate. A mark–recapture distance analysis that corrects for perception and availability bias estimated the abundance to be 9072 whales (cv = 0.32). Increasing distance of beluga sightings from shore was correlated with decreasing sea ice cover, suggesting that belugas expand their distribution offshore (i.e. westward in this context) with the reduction of coastal sea ice. A model with high (0.98) adult survival estimated a decline from 18 600 (90% CI: 13 400, 26 000) whales in 1970 to 8000 (90% CI: 5830, 11 200) in 2004. The decline was probably a result of a period with exceptionally large catches. Following the introduction of catch limits in 2004, the model projects an increase to 11 600 (90% CI: 6760, 17 600) individuals in 2020 (assuming annual removals of 294 belugas after 2014). If the annual removal level is fixed at 300 individuals, a low-survival (0.97) model predicts a 75% probability of an increasing population during 20152020. Reduced removal rates due to catch limits and the more offshore, less accessible distribution of the whales are believed to be responsible for the initial signs of population recovery. |
Habitat selection by two beluga whale populations in the Chukchi and Beaufort seas Hauser, D.D.W., K.L. Laidre, H.L. Stern, S.E. Moore, R.S. Suydam, and P.R. Richard, "Habitat selection by two beluga whale populations in the Chukchi and Beaufort seas," Plos One, 12, doi:10.1371/journal.pone.0172755, 2017. |
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24 Feb 2017 |
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There has been extensive sea ice loss in the Chukchi and Beaufort seas where two beluga whale (Delphinapterus leucas) populations occur between JulyNovember. Our goal was to develop population-specific beluga habitat selection models that quantify relative use of sea ice and bathymetric features related to oceanographic processes, which can provide context to the importance of changing sea ice conditions. We established habitat selection models that incorporated daily sea ice measures (sea ice concentration, proximity to ice edge and dense ice) and bathymetric features (slope, depth, proximity to the continental slope, Barrow Canyon, and shore) to establish quantitative estimates of habitat use for the Eastern Chukchi Sea ('Chukchi') and Eastern Beaufort Sea ('Beaufort') populations. We applied 'used v. available' resource selection functions to locations of 65 whales tagged from 19932012, revealing large variations in seasonal habitat selection that were distinct between sex and population groups. Chukchi whales of both sexes were predicted to use areas in close proximity to Barrow Canyon (typically <200 km) as well as the continental slope in summer, although deeper water and denser ice were stronger predictors for males than females. Habitat selection differed more between sexes for Beaufort belugas. Beaufort males selected higher ice concentrations (≥40%) than females (040%) in JulyAugust. Proximity to shore (<200 km) strongly predicted summer habitat of Beaufort females, while distance to the ice edge was important for male habitat selection, especially during westward migration in September. Overall, our results indicate that sea ice variables were rarely the primary drivers of beluga summer-fall habitat selection. While diminished sea ice may indirectly affect belugas through changes in the ecosystem, associations with bathymetric features that affect prey availability seemed key to habitat selection during summer and fall. These results provide a benchmark by which to assess future changes in beluga habitat use of the Pacific Arctic. |
Polar maps: Captain Cook and the earliest historical charts of the ice edge in the Chukchi Sea Stern, H.L., "Polar maps: Captain Cook and the earliest historical charts of the ice edge in the Chukchi Sea," Polar Geogr., 39, 220-227, 2016. |
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3 Nov 2016 |
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On 11 August 1778, Captain James Cook, the pre-eminent explorer of his age, sailed north through Bering Strait with two ships, Resolution and Discovery, in search of the Northwest Passage. Working his way along the coast of Alaska, his progress was halted a week later by 'ice which was as compact as a Wall and seemed to be ten or twelve feet high at least'. In this text, all quotations from original journals and manuscripts are taken from Beaglehole (1967). This marked Cook’s farthest north, at 70°44N, about 30 km north of Icy Cape. Turning southwest and then west, Cook sailed close to the ice edge for the next 11 days, trying to find an opening to the north. On 29 August, having reached the coast of Siberia at 69°N without finding a break in the ice, he abandoned the search, since 'so little was the prospect of succeeding', but he resolved 'to return to the North in further search of a Passage the ensuing summer'.He sailed south through Bering Strait on 2 September. |
Sea-ice indicators of polar bear habitat Stern, H.L., and K.L. Laidre, "Sea-ice indicators of polar bear habitat," Cyrosphere, 10, 2027-2041, doi:10.5194/tc-10-2027-2016, 2016. |
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14 Sep 2016 |
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Nineteen subpopulations of polar bears (Ursus maritimus) are found throughout the circumpolar Arctic, and in all regions they depend on sea ice as a platform for traveling, hunting, and breeding. Therefore polar bear phenology the cycle of biological events is linked to the timing of sea-ice retreat in spring and advance in fall. We analyzed the dates of sea-ice retreat and advance in all 19 polar bear subpopulation regions from 1979 to 2014, using daily sea-ice concentration data from satellite passive microwave instruments. We define the dates of sea-ice retreat and advance in a region as the dates when the area of sea ice drops below a certain threshold (retreat) on its way to the summer minimum or rises above the threshold (advance) on its way to the winter maximum. The threshold is chosen to be halfway between the historical (19792014) mean September and mean March sea-ice areas. |
Modeling the seasonal evolution of the Arctic sea ice floe size distribution Zhang, J., H. Stern, B. Hwang, A. Schweiger, M. Steele, M. Stark, and H.C. Graber, "Modeling the seasonal evolution of the Arctic sea ice floe size distribution," Elem. Sci. Anth., 4, doi:10.12952/journal.elementa.000126, 2016 |
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13 Sep 2016 |
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To better simulate the seasonal evolution of sea ice in the Arctic, with particular attention to the marginal ice zone, a sea ice model of the distribution of ice thickness, floe size, and enthalpy was implemented into the Pan-arctic IceOcean Modeling and Assimilation System (PIOMAS). Theories on floe size distribution (FSD) and ice thickness distribution (ITD) were coupled in order to explicitly simulate multicategory FSD and ITD distributions simultaneously. The expanded PIOMAS was then used to estimate the seasonal evolution of the Arctic FSD in 2014 when FSD observations are available for model calibration and validation. |
Sea ice floe size distribution in the marginal ice zone: Theory and numerical experiments Zhang, J., A. Schweiger, M. Steele, and H. Stern, "Sea ice floe size distribution in the marginal ice zone: Theory and numerical experiments," J. Geophys. Res., 120, 3484-3498, do:10.1002/2015JC010770, 2015. |
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12 May 2015 |
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To better describe the state of sea ice in the marginal ice zone (MIZ) with floes of varying thicknesses and sizes, both an ice thickness distribution (ITD) and a floe size distribution (FSD) are needed. In this work, we have developed a FSD theory that is coupled to the ITD theory of Thorndike et al. (1975) in order to explicitly simulate the evolution of FSD and ITD jointly. The FSD theory includes a FSD function and a FSD conservation equation in parallel with the ITD equation. The FSD equation takes into account changes in FSD due to ice advection, thermodynamic growth, and lateral melting. It also includes changes in FSD because of mechanical redistribution of floe size due to ice ridging and, particularly, ice fragmentation induced by stochastic ocean surface waves. The floe size redistribution due to ice fragmentation is based on the assumption that wave-induced breakup is a random process such that when an ice floe is broken, floes of any smaller sizes have an equal opportunity to form, without being either favored or excluded. To focus only on the properties of mechanical floe size redistribution, the FSD theory is implemented in a simplified ITD and FSD sea ice model for idealized numerical experiments. Model results show that the simulated cumulative floe number distribution (CFND) follows a power law as observed by satellites and airborne surveys. The simulated values of the exponent of the power law, with varying levels of ice breakups, are also in the range of the observations. It is found that floe size redistribution and the resulting FSD and mean floe size do not depend on how floe size categories are partitioned over a given floe size range. The ability to explicitly simulate multicategory FSD and ITD together may help to incorporate additional model physics, such as FSD-dependent ice mechanics, surface exchange of heat, mass, and momentum, and wave-ice interactions. |
Arctic marine mammal population status, sea ice habitat loss, and conservation recommendations for the 21st century Laidre, K.L., H. Stern, K.M. Kovacs, L. Lowry, S.E. Moore, E.V. Regehr, S.H. Ferguson, Ø. Wiig, P. Boveng, R.P. Angliss, E.W Born, D. Litovka, L. Quakenbush, C. Lydersen, D. Vongraven, and F. Ugarte, "Arctic marine mammal population status, sea ice habitat loss, and conservation recommendations for the 21st century," Conserv. Biol., 29, 724-737, doi:10.1111/cobi.12474, 2015. |
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17 Mar 2015 |
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Arctic marine mammals (AMMs) are icons of climate change, largely because of their close association with sea ice. However, neither a circumpolar assessment of AMM status nor a standardized metric of sea ice habitat change is available. We summarized available data on abundance and trend for each AMM species and recognized subpopulation. We also examined species diversity, the extent of human use, and temporal trends in sea ice habitat for 12 regions of the Arctic by calculating the dates of spring sea ice retreat and fall sea ice advance from satellite data (19792013). Estimates of AMM abundance varied greatly in quality, and few studies were long enough for trend analysis. Of the AMM subpopulations, 78% (61 of 78) are legally harvested for subsistence purposes. Changes in sea ice phenology have been profound. In all regions except the Bering Sea, the duration of the summer (i.e., reduced ice) period increased by 510 weeks and by >20 weeks in the Barents Sea between 1979 and 2013. In light of generally poor data, the importance of human use, and forecasted environmental changes in the 21st century, we recommend the following for effective AMM conservation: maintain and improve comanagement by local, federal, and international partners; recognize spatial and temporal variability in AMM subpopulation response to climate change; implement monitoring programs with clear goals; mitigate cumulative impacts of increased human activity; and recognize the limits of current protected species legislation. |
Shifts in female polar bear (Ursus maritimus) habitat use in East Greenland Laidre, K.L., E.W. Born, P. Heagerty, Ø. Wiig, H. Stern, R. Dietz, J. Aars, and M. Andersen, "Shifts in female polar bear (Ursus maritimus) habitat use in East Greenland," Polar Biol., 38, 879-893, doi:10.1007/s00300-015-1648-5, 2015. |
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6 Feb 2015 |
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Few studies have investigated the impacts of climate change on polar bears (Ursus maritimus) in East Greenland (EG), where some of the largest rates of sea ice loss have occurred. We used remotely sensed sea ice data to quantify changes in timing of sea ice freeze-up and breakup in EG polar bear habitat between 1979 and 2012. We then quantified movement rates, area use, habitat selection, and distribution and phenology of maternity denning using data from adult female polar bears tracked with satellite transmitters between 2007 and 2010 (n = 7). We compared results to historical data collected from adult females in the 1990s (n = 4). Adult females in the 2000s used areas with significantly lower sea ice concentrations (1015% lower) than bears in the 1990s during winter, a pattern influenced by delayed freeze-up in OctoberDecember. Adult females in the 2000s were located significantly closer (100150 km) to open water in all seasons and spent approximately 2 months longer in areas with <60% sea ice concentration than bears in the 1990s. Multivariate resource selection models contrasting preference between decades showed that there was a statistically significant and stronger winter preference in the 2000s for adult females to select for higher sea ice concentrations. Timing of maternity denning did not significantly differ between decades. Results indicate that multi-decadal loss of sea ice has resulted in shifts in polar bear habitat use in EG. |
Two-dimensional wavelet variance estimation with application to sea ice SAR images Geilhufe, M., D.B. Percival, and H.L. Stern, "Two-dimensional wavelet variance estimation with application to sea ice SAR images," Comput. Geosci., 54, 351-360, doi:10.1016/j.cageo.2012.11.020, 2013. |
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1 Apr 2013 |
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The surface of Arctic sea ice presents complex patterns of cracks and ridges that change with the seasons according to the external forces acting on the ice and the internal stresses within the ice. We propose a new statistical tool for analysis of these patterns based on a two-dimensional Maximal Overlap Discrete Wavelet Transform (MODWT) of Synthetic Aperture Radar (SAR) images, which can be used to track how ice conditions change over the course of the year. Here we give details on an extended pyramid algorithm that efficiently computes the MODWT coefficients for all combinations of vertical and horizontal scales. We show how to use these coefficients to form mean- and median-based wavelet variance estimates along with confidence intervals for the true unknown variances. We demonstrate the usefulness of the statistical tool on images acquired by the SAR sensor onboard RADARSAT, but the tool is of potential use in other geoscience applications and in other areas (e.g. medical imaging). We provide a Matlab implementation of this tool but also give sufficient details so that it can be encoded in other languages. |
Females roam while males patrol: Comparing movements of adult male and adult female polar bears during the springtime breeding season Laidre, K.L., E.W. Born, E. Gurarie, Ø. Wiig, R. Dietz, and H. Stern, "Females roam while males patrol: Comparing movements of adult male and adult female polar bears during the springtime breeding season," Proc. R. Soc. B, 280, doi:10.1098/rspb.2012.2371, 2013. |
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1 Feb 2013 |
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Intraspecific differences in movement behaviour reflect different tactics used by individuals or sexes to favour strategies that maximize fitness. We report movement data collected from n = 23 adult male polar bears with novel ear-attached transmitters in two separate pack ice subpopulations over five breeding seasons. We compared movements with n = 26 concurrently tagged adult females, and analysed velocities, movement tortuosity, range sizes and habitat selection with respect to sex, reproductive status and body mass. There were no differences in 4-day displacements or sea ice habitat selection for sex or population. By contrast, adult females in all years and both populations had significantly more linear movements and significantly larger breeding range sizes than males. We hypothesized that differences were related to encounter rates, and used observed movement metrics to parametrize a simulation model of malemale and malefemale encounter. The simulation showed that the more tortuous movement of males leads to significantly longer times to malemale encounter, while having little impact on malefemale encounter. By contrast, linear movements of females are consistent with a prioritized search for sparsely distributed prey. These results suggest a possible mechanism for explaining the smaller breeding range sizes of some solitary male carnivores compared to females. |
Unusual narwhal sea ice entrapments and delayed autumn freeze-up trends Laidre, K.L., M.P. Heide-Jørgensen, H. Stern, and P. Richard, "Unusual narwhal sea ice entrapments and delayed autumn freeze-up trends," Polar Biol., 35, 149-154, doi:10.1007/s00300-011-1036-8, 2012. |
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1 Jan 2012 |
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Sea ice entrapments of narwhals (Monodon monoceros) occur when rapid changes in weather and wind conditions create a formation of fast ice in bays or passages used by whales. Between 2008 and 2010, four entrapments of narwhals were reported in Canada and Greenland. In each case, large groups (40600 individuals) succumbed in the sea ice at three separate summering localities, two of these where entrapments had never before been reported. We examined long-term trends in autumn freeze-up timing (date when sea ice concentration rises above some threshold) on the 6 largest narwhal summering areas using sea ice concentration from satellite passive microwave data (19792009). We found strongly positive and significant trends (P < 0.001) in progressively later dates of autumn freeze-up in all summering areas. Autumn freeze-up occurs between 0.5 and 1 day later per year, or roughly 24 weeks later, over the 31-year time series. This indicates that sea ice conditions on narwhal summering areas are changing rapidly. The question remains whether entrapment events on summering areas are random or whether narwhals are adapting to changes in sea ice freeze-up by prolonging their summer residence time. |
Harbour porpoises respond to climate change Heide-Jorgensen, M.P., M. Iversen, N.H. Nielsen, C. Lockyer, H. Stern, and M.H. Ribergaard, "Harbour porpoises respond to climate change," Ecol. Evol., 1, 579-585, doi:10.1002/ece3.51, 2011. |
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1 Dec 2011 |
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The effects of climate change on marine ecosystems and in particular on marine top predators are difficult to assess due to, among other things, spatial variability, and lack of clear delineation of marine habitats. The banks of West Greenland are located in a climate sensitive area and are likely to elicit pronounced responses to oceanographic changes in the North Atlantic. The recent increase in sea temperatures on the banks of West Greenland has had cascading effects on sea ice coverage, residency of top predators, and abundance of important prey species like Atlantic cod (Gadus morhua). Here, we report on the response of one of the top predators in West Greenland; the harbour porpoise (Phocoena phocoena). The porpoises depend on locating high densities of prey species with high nutritive value and they have apparently responded to the general warming on the banks of West Greenland by longer residence times, increased consumption of Atlantic cod resulting in improved body condition in the form of larger fat deposits in blubber, compared to the situation during a cold period in the 1990s. This is one of the few examples of a measurable effect of climate change on a marine mammal population. |
Uncertainty in modeled Arctic sea ice volume Schweiger, A., R. Lindsay, J. Zhang, M. Steele, H. Stern, and R. Kwok, "Uncertainty in modeled Arctic sea ice volume," J. Geophys. Res., 116, doi:10.1029/2011JC007084, 2011. |
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1 Sep 2011 |
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Uncertainty in the Pan-Arctic Ice-Ocean Modeling and Assimilation System (PIOMAS) Arctic sea ice volume record is characterized. A range of observations and approaches, including in situ ice thickness measurements, ICESat retrieved ice thickness, and model sensitivity studies, yields a conservative estimate for October Arctic ice volume uncertainty of 1.35 x 10^3 km^3 and an uncertainty of the ice volume trend over the 1979-2010 period of 1.0 x 10^3 km^3 decade^-1. A conservative estimate of the trend over this period is ~2.8 x 10^3 km^3 decade^-1. PIOMAS ice thickness estimates agree well with ICESat ice thickness retrievals (<0.1 m mean difference) for the area for which submarine data are available, while difference outside this area are larger. PIOMAS spatial thickness patterns agree well with ICESat thickness estimates with pattern correlations of above 0.8. PIOMAS appears to overestimate thin ice thickness and underestimate thick ice, yielding a smaller downward trend than apparent in reconstructions from observations. PIOMAS ice volume uncertainties and trends are examined in the context of climate change attribution and the declaration of record minima. The distribution of 32 year trends in a preindustrial coupled model simulation shows no trends comparable to those seen in the PIOMAS retrospective, even when the trend uncertainty is accounted for. Attempts to label September minima as new record lows are sensitive to modeling error. However, the September 2010 ice volume anomaly did in fact exceed the previous 2007 minimum by a large enough margin to establish a statistically significant new record. |
The effect of sea-ice loss on beluga whales (Delphinapterus leucas) in West Greenland Heide-Jorgensen, M.P., K.L. Laidre, D. Borchers, T.A. Marques, H. Stern, and M. Simon, "The effect of sea-ice loss on beluga whales (Delphinapterus leucas) in West Greenland," Polar Res., 29, 198-208, 2010. |
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14 Jan 2010 |
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An aerial survey was conducted to estimate the abundance of belugas (Delphinapterus leucas) on their wintering ground in West Greenland in MarchApril 2006 and 2008. The survey was conducted as a double platform aerial line transect survey, and sampled approximately 17% of the total survey area of ca. 125 000 km2. The abundance of belugas was 10 595 (95% confidence interval 490424 650). The largest abundance was found at the northern part of Store Hellefiske Bank, at the eastern edge of the Baffin Bay pack ice, a pattern similar to that found in eight systematic surveys conducted since 1981. |
Spatial scaling of Arctic sea ice deformation Stern, H.L., and R.W. Lindsay, "Spatial scaling of Arctic sea ice deformation," J. Geophys. Res., 114, doi:10.1029/2009JC005380, 2009. |
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21 Oct 2009 |
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Arctic sea ice deformation arises from spatial gradients in the ice velocity field. This deformation occurs across a wide range of spatial scales, from meters to thousands of kilometers. We analyze 7 years of sea ice deformation data from the RADARSAT Geophysical Processor System (RGPS) covering the western Arctic Ocean. We find that the mean deformation rate is related to the spatial scale over which it is measured according to a power law with exponent ~ 0.2, over a scale range from 10 to 1000 km (e.g., deformation rate doubles for a 30-fold reduction in scale). Both the exponent and the deformation rate have distinct annual cycles. The exponent becomes more negative in summer as the ice pack weakens and internal stresses are not as readily transmitted over long distances. The deformation rate reaches a minimum in late winter when the ice pack is strongest. The deformation also exhibits considerable localization, in which the largest deformation rates are confined to smaller and smaller areas as the scale of measurement decreases. |
Arctic sea ice retreat in 2007 follows thinning trend Lindsay, R.W., J. Zhang, A. Schweiger, M. Steele, and H. Stern, "Arctic sea ice retreat in 2007 follows thinning trend," J. Climate, 22, 165-176, 2009. |
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1 Jan 2009 |
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The minimum of Arctic sea ice extent in the summer of 2007 was unprecedented in the historical record. A coupled iceocean model is used to determine the state of the ice and ocean over the past 29 yr to investigate the causes of this ice extent minimum within a historical perspective. It is found that even though the 2007 ice extent was strongly anomalous, the loss in total ice mass was not. Rather, the 2007 ice mass loss is largely consistent with a steady decrease in ice thickness that began in 1987. Since then, the simulated mean September ice thickness within the Arctic Ocean has declined from 3.7 to 2.6 m at a rate of 0.57 m decade-1. Both the area coverage of thin ice at the beginning of the melt season and the total volume of ice lost in the summer have been steadily increasing. The combined impact of these two trends caused a large reduction in the September mean ice concentration in the Arctic Ocean. This created conditions during the summer of 2007 that allowed persistent winds to push the remaining ice from the Pacific side to the Atlantic side of the basin and more than usual into the Greenland Sea. This exposed large areas of open water, resulting in the record ice extent anomaly. |
Continued evolution of Jakobshavn Isbrae following its rapid speedup Joughin, I., I. Howat, M. Fahnestock, B. Smith, W. Krabill, R. Alley, H. Stern, and M. Truffer, "Continued evolution of Jakobshavn Isbrae following its rapid speedup," J. Geophys. Res., 113, doi:10.1029/2008JF001023, 2008. |
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28 Oct 2008 |
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Several new data sets reveal that thinning and speedup of Jakobshavn Isbrae continue, following its recent rapid increase in speed as its floating ice tongue disintegrated. The present speedup rate of 5% a-1 over much of the fast-moving region appears to be a diffusive response to the initial much larger speedup near the front. There is strong seasonality in speed over much of the fast-flowing main trunk that shows a good inverse correlation with the seasonally varying length of a short (typically ~6 km) floating ice tongue. This modulation of speed with ice front position supports the hypothesis that the major speedup was caused by loss of the larger floating ice tongue from 1998 to 2003. Analysis of image time series suggests that the transient winter ice tongue is formed when sea ice bonds glacier ice in the fjord to produce a nearly rigid mass that almost entirely suppresses calving. Major calving only resumes in late winter when much of this ice clears from the fjord. The collapse of the ice tongue in the late 1990s followed almost immediately after a sharp decline in winter sea-ice concentration in Disko Bay. This decline may have extended the length of the calving season for several consecutive years, leading to the ice tongue's collapse. |
Scaling properties of sea ice deformation from buoy dispersion analysis Rampal, R., J. Weiss, D. Marsan, R. Lindsay, and H. Stern, "Scaling properties of sea ice deformation from buoy dispersion analysis," J. Geophys. Res., 113, doi:10.1029/2007JC004143, 2008. |
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4 Mar 2008 |
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A temporal and spatial scaling analysis of Arctic sea ice deformation is performed over timescales from 3 h to 3 months and over spatial scales from 300 m to 300 km. The deformation is derived from the dispersion of pairs of drifting buoys, using the IABP (International Arctic Buoy Program) buoy data sets. This study characterizes the deformation of a very large solid plate (the Arctic sea ice cover) stressed by heterogeneous forcing terms like winds and ocean currents. It shows that the sea ice deformation rate depends on the scales of observation following specific space and time scaling laws. These scaling properties share similarities with those observed for turbulent fluids, especially for the ocean and the atmosphere. However, in our case, the time scaling exponent depends on the spatial scale, and the spatial exponent on the temporal scale, which implies a time/space coupling. An analysis of the exponent values shows that Arctic sea ice deformation is very heterogeneous and intermittent whatever the scales, i.e., it cannot be considered as viscous-like, even at very large time and/or spatial scales. Instead, it suggests a deformation accommodated by a multiscale fracturing/faulting processes. |
Polar Science Weekend: A university/science center collaboration Stern, H.L., R.E. Moritz, E. Lettvin, D. Schatz, and L. Russell, "Polar Science Weekend: A university/science center collaboration," Eos Trans. AGU, 89, Fall Meet. Suppl., abstract #ED33A-0620, 2008. |
26 Feb 2008 |
What is the trajectory of arctic sea ice? Stern, H., R. Lindsay, C. Bitz, and P. Hezel, "What is the trajectory of arctic sea ice?" in Arctic Sea Ice Decline: Observations, Projections, Mechanisms, and Implications, edited by E.T. DeWeaver, C.M. Bitz, and B.-L. Tremblay, 175-185 (American Geophysical Union, 2008). |
1 Jan 2008 |
Dynamics of the sea ice edge in Davis Strait Heide-Jørgensen, M.P., H. Stern, and K.L. Laidre, "Dynamics of the sea ice edge in Davis Strait," J. Mar. Syst., 67, 170-178, doi:10.1016/j.jmarsys.2006.10.011, 2007. |
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1 Aug 2007 |
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Sea ice concentration derived from satellite data were used to quantify sea ice characteristics in the Baffin BayDavis StraitLabrador Sea area. The ice edge in Davis Strait extends from Disko Bay in West Greenland 2500 km south to Newfoundland. The mean intercept at the West Greenland coast between 1979 and 2002 was located at 66.9°N, assuming the ice edge was 85% ice concentration. The shallow banks of West Greenland (> 200 m) had, on average, an ice extent covering 30 to 100% of the bank area during March for the 24 year time series. This extent varied in concentration between 39 and 100%. However, intermediate ice concentrations (3985% ice concentration) covered on average 25% of the banks. The Davis Strait ice edge showed considerable interannual variation correlated with the winter index of the North Atlantic Oscillation and the Arctic Oscillation. No temporal trend in ice extent could be detected over the 24 years. In addition to the ice production on the banks of West Greenland, sea ice produced further north in Baffin Bay was advected to the banks as shown by satellite tracked drifting buoys. Both the local sea ice production and the advected sea ice contributed significantly to sea temperatures and salinities measured during summer on the banks. No correlation between sea ice concentration and plankton abundance could be detected but the recruitment of the offshore cod (Gadus morhua) component in South Greenland was negatively correlated to the amount of sea ice in Baffin Bay. |
Increasing abundance of bowhead whales in West Greenland Heide-Jørgensen, M.P., K.L. Laidre, D. Borchers, F. Samara, and H. Stern, "Increasing abundance of bowhead whales in West Greenland," Biol. Lett., 3, 577-580, 2007. |
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1 Aug 2007 |
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In April 2006, a dedicated survey of bowhead whales (Balaena mysticetus) was conducted on the former whaling ground in West Greenland to determine the current wintering population abundance. This effort included a double platform aerial survey design, satellite tracking of the movements of nine whales, and estimation of high-resolution surface time from 14 whales instrumented with timedepth recorders. Bowhead whales were estimated to spend an average of 24% (cv=0.03) of the time at or above 2 m depth, the maximum depth at which they can be seen on the trackline. This resulted in a fully corrected abundance estimate of 1229 (95% CI: 4952939) bowhead whales when the availability factor was applied and sightings missed by observers were corrected. This surprisingly large population estimate is puzzling given that the change in abundance cannot be explained by a recent or rapid growth in population size. One possible explanation is that the population, which demonstrates high age and sex segregation, has recently attained a certain threshold size elsewhere, and a higher abundance of mature females appears on the winter and spring feeding ground in West Greenland. This in combination with the latest severe reduction in sea ice facilitating access to coastal areas might explain the surprising increase in bowhead whale abundance in West Greenland. |
Sea ice rheology from in-situ satellite and laboratory observations: Fracture and friction Weiss, J., E.M. Schulson, and H. Stern, "Sea ice rheology from in-situ satellite and laboratory observations: Fracture and friction," Earth Planet. Sci. Lett., 255, 1-8, doi:10.1016/j.epsl.2006.11.033, 2007. |
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15 Mar 2007 |
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On the basis of an analysis of in-situ ice stresses and of satellite-derived ice strain rates, as well as of a comparison between field and laboratory behaviour, we describe an alternative viewpoint for modelling sea ice deformation during winter. We propose that fracture and frictional sliding govern inelastic deformation over all spatial and temporal scales, even under small stresses. Consequently, winter and/or perennial sea ice does not behave as a viscous material, even at large scales, the normal flow rule is not obeyed (as observed during laboratory tests on sea ice samples harvested from the field), and stresses are highly intermittent and poorly correlated spatially. |
Scale dependence and localization of the deformation of arctic sea ice Marsan, D., H. Stern, R. Lindsay, and J. Weiss, "Scale dependence and localization of the deformation of arctic sea ice," Phys. Rev. Lett., 93, 17, doi:10.1103/PhysRevLett.93.178501, 2004. |
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20 Oct 2004 |
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A scaling analysis of the deformation of Arctic sea ice over a 3-day time period is performed for scales of 10 to 1000 km. The deformation field is derived from satellite radar data; it allows us to study how a very large solid body the Arctic sea-ice cover deforms under the action of heterogeneous forcing winds and ocean currents. The deformation is strongly localized at small scales, and can be characterized as multifractal. This behavior is well known for turbulent flows, and is here also observed for a deforming solid. A multiscaling extrapolation to the meter scale (laboratory scale) shows that, at the 3-day time scale, about 15% of the deformation is larger than 10-4 s-1, implying brittle failure, over 0.2% of the total area. |
The RADARSAT geophysical processor system: Quality of sea ice trajectory and deformation estimates Lindsay, R.W., and H.L. Stern, "The RADARSAT geophysical processor system: Quality of sea ice trajectory and deformation estimates," J. Atmos. Ocean. Technol., 20, 1333-1347, DOI: 10.1175/1520-0426(2003)020<1333:TRGPSQ>2.0.CO;2, 2003. |
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1 Sep 2003 |
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NASA's RADARSAT Geophysical Processor System (RGPS) uses sequential synthetic aperture radar (SAR) images to track the trajectories of some 30 000 points on the Arctic sea ice for periods of up to 6 months. Much of the Arctic basin is imaged and tracked every 3 days. The result is a highly detailed picture of how the sea ice moves and deforms. The points are initially spaced 10 km apart and are organized into four-cornered cells. The area and the strain rates are calculated for each cell for each new observation of its corners. The accuracy of the RGPS ice tracking, area changes, and deformation estimates is needed to make the dataset useful for analysis, model validation, and data assimilation. Two comparisons are made to assess the accuracy. The first compares the tracking performed at two different facilities (the Jet Propulsion Laboratory in Pasadena, California, and the Alaska SAR Facility in Fairbanks, Alaska), between which the primary difference is the operator intervention. The error standard deviation of the tracking, not including geolocation errors, is 100 m, which is the pixel size of the SAR images. The second comparison is made with buoy trajectories from the International Arctic Buoy Program. The squared correlation coefficient for RGPS and buoy displacements is 0.996. The median magnitude of the displacement differences is 323 m. The tracking errors give rise to error standard deviations of 0.5% day-1 in the divergence, shear, and vorticity. The uncertainty in the area change of a cell is 1.4% due to tracking errors and 3.2% due to resolving the cell boundary with only four points. The uncertainties in the area change and deformation invariants can be reduced substantially by averaging over a number of cells, at the expense of spatial resolution. |
Trends and variability of sea ice in Baffin Bay and Davis Strait Stern, H.L. and M.P. Heide-Jørgensen, "Trends and variability of sea ice in Baffin Bay and Davis Strait," Polar Res., 22, 11-18, doi:10.1111/j.1751-8369.2003.tb00090.x, 2003. |
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1 Jun 2003 |
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The extent and duration of sea ice in Baffin Bay and Davis Strait has a major impact on the timing and strength of the marine production along West Greenland. The advance and retreat of the sea ice follows a predictable pattern, with maximum extent typically in March. We examine the area of sea ice in March in three overlapping study regions centred on Disko Bay on the west coast of Greenland. Sea ice concentration estimates derived from satellite passive microwave data are available for the years 1979-2001. We extend the record back in time by digitizing ice charts from the Danish Meteorological Institute, 1953-1981. There is reasonable agreement between the chart data and the satellite data during the three years of overlap: 1979-1981. We find a significant increasing trend in sea ice for the 49-year period (1953-2001) for the study regions that extend into Davis Strait and Baffin Bay. The cyclical nature of the wintertime ice area is also evident, with a period of about 8 to 9 years. Correlation of the winter sea ice concentration with the winter North Atlantic Oscillation (NAO) index shows moderately high values in Baffin Bay. The correlation of ice concentration with the previous winter's NAO is high in Davis Strait and suggests that next winter's ice conditions can be predicted to some extent by this winter's NAO index. |
Sea ice kinematics and surface properties from RADARSAT synthetic aperture radar during the SHEBA drift Stern, H.L., and R.E. Moritz, "Sea ice kinematics and surface properties from RADARSAT synthetic aperture radar during the SHEBA drift," J. Geophys. Res., 107, doi:10.1029/2000JC000472, 2002. |
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18 Sep 2002 |
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Satellite data are important for providing the large-scale context of the Surface Heat Budget of the Arctic Ocean (SHEBA) station and for characterizing the spatial variability of the sea ice in its vicinity. The Canadian RADARSAT satellite collected 195 synthetic aperture radar (SAR) images of the SHEBA site over the course of the 1 year drift. The RADARSAT Geophysical Processor System (RGPS) used these images to compute the spatial pattern of ice motion within 100 km of the SHEBA station by tracking features in sequential images. From the ice motion data the divergence and shear of the pack ice are estimated. The divergence is large from November to January, followed by a gradual convergence from February through July. The character of the ice motion changes at the end of July, from piecewise rigid motion to free drift. The ice motion reverts to its winterlike character in late September. Thus the "kinematic" summer runs from late July to late September. The radar backscatter also goes through seasonal transitions, capturing the abrupt onset of melt (29 May) and freeze-up (15 August). The concentration of multiyear ice is about 94% in the fall, and its backscatter signature remains stable through spring. Multiyear and first-year ice cannot be distinguished during the summer melt season, when the mean backscatter is negatively correlated with the surface air temperature. The "thermodynamic" summer runs from late May to mid-August. |
Surface heat budget of the Arctic Ocean Uttal, T., and 27 others including R.E. Moritz, H.L. Stern, A. Heiberg, J.H. Morison, and R.W. Lindsay, "Surface heat budget of the Arctic Ocean," Bull. Amer. Meteor. Soc., 83, 255-275, 2002. |
More Info |
1 Feb 2002 |
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A summary is presented of the Surface Heat Budget of the Arctic Ocean (SHEBA) project, with a focus on the field experiment that was conducted from October 1997 to October 1998. The primary objective of the field work was to collect ocean, ice, and atmospheric datasets over a full annual cycle that could be used to understand the processes controlling surface heat exchangesin particular, the ice-albedo feedback and cloud-radiation feedback. This information is being used to improve formulations of arctic ice-ocean-atmosphere processes in climate models and thereby improve simulations of present and future arctic climate. The experiment was deployed from an ice breaker that was frozen into the ice pack and allowed to drift for the duration of the experiment. This research platform allowed the use of an extensive suite of instruments that directly measured ocean, atmosphere, and ice properties from both the ship and the ice pack in the immediate vicinity of the ship. This summary describes the project goals, experimental design, instrumentation, and the resulting datasets. Examples of various data products available from the SHEBA project are presented. |
Relationships between geostrophic winds, ice strain rates and the piecewise rigid motions of pack ice Moritz, R.E., and H.L. Stern, "Relationships between geostrophic winds, ice strain rates and the piecewise rigid motions of pack ice," in IUTAM Symposium on Scaling Laws in Ice Mechanics and Ice Dynamics, J.P. Dempsey and H.H. Shen, eds., 335-348 (Kluwer Academic Publishers, Dordrecht, The Netherlands, 2001). |
15 Jan 2001 |
In The News
Polar bears of the past survived warm periods. What does that mean for the future? Anchorage Daily News, Ned Rozell A small population of polar bears living off Greenland and Arctic Canada increased by 1.6 times when comparing numbers from the 1990s to 2013 and 2014. Lighter sea ice might have benefited the animals because sunshine penetrates thinner ice better, which stimulates small living things. That means more food for seals, the main food of polar bears. |
3 Jun 2023
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Arctic ice has seen an 'irreversible' thinning since 2007, study says Washington Post, Scott Dance New research suggests the decline was a fundamental change unlikely to be reversed this century perhaps proof that the planet has passed an alarming climactic tipping point. Mathematician Harry Stern offers a counterpoint. |
15 Mar 2023
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'Wholly unexpected': These polar bears can survive with less sea ice The New York Times, Henry Fountain The overall threat to the animals from climate change remains, but a new finding suggests that small numbers might survive for longer as the Arctic warms. See related articles on the UW News pinboard. |
16 Jun 2022
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Newly documented population of polar bears in Southeast Greenland sheds light on the species' future in a warming Arctic UW News, Hannah Hickey Scientists have documented a previously unknown subpopulation of polar bears living in Southeast Greenland. The polar bears survive with limited access to sea ice by hunting from freshwater ice that pours into the ocean from Greenland’s glaciers. |
16 Jun 2022
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Some polar bears in far north are getting short-term benefit from thinning ice UW News, Hannah Hickey A small subpopulation of polar bears lives on what used to be thick, multiyear sea ice far above the Arctic Circle. They are healthier as conditions are warming because thinning and shrinking multiyear sea ice is allowing more sunlight to reach the ocean surface, which makes the ecosystem more productive. photo: Carsten Egevang |
23 Sep 2020
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Polar bears are getting thinner and having fewer cubs CNN, Scottie Andrew The impact of the climate crisis is becoming more and more obvious to humans and their animal neighbors. But among all species, polar bears might be some of the hardest hit. |
14 Feb 2020
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Polar bears in Baffin Bay skinnier, having fewer cubs due to less sea ice UW News, Hannah Hickey Polar bears are spending more time on land than they did in the 1990s due to reduced sea ice, new University of Washington-led research shows. Bears in Baffin Bay are getting thinner and adult females are having fewer cubs than when sea ice was more available. |
12 Feb 2020
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Polar bears struggle as sea ice declines NASA Earth Observatory, Kasha Patel A new study shows that polar bears are spending less time on sea ice, leading them to fast longer, become thinner and have fewer cubs. |
4 Feb 2020
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As Arctic ship traffic increases, narwhals and other unique animals are at risk The Conversation, Donna Hauser, Harry Stern, and Kristin Laidre In a recent study, the authors assessed the vulnerability of 80 populations of Arctic marine mammals during the "open-water" period of September, when sea ice is at its minimum extent. They report that more than half (53 percent) of these populations including walruses and several types of whales would be exposed to vessels in Arctic sea routes. This could lead to collisions, noise disturbance, or changes in the animals' behavior. |
9 Nov 2018
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Ships Threaten Arctic Marine Mammals Scientific American, Adam Aton New research suggests that marine mammals in the Arctic could be threatened by increasing ship traffic as the region’s ice melts. Narwhals and beluga whales could be especially vulnerable because of their exposure to ships and their sensitivity to disturbances, according to a study published yesterday in the Proceedings of the National Academy of Sciences. |
3 Jul 2018
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Study identifies which marine mammals are most at risk from increased Arctic ship traffic UW News, Hannah Hickey In recent decades parts of the Arctic seas have become increasingly ice-free in late summer and early fall. As sea ice is expected to continue to recede due to climate change, seasonal ship traffic from tourism and freight is projected to rise. A study from the University of Washington and the University of Alaska Fairbanks is the first to consider potential impacts on the marine mammals that use this region during fall and identify which will be most vulnerable. |
2 Jul 2018
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How to conserve polar bears and maintain subsistence harvest under climate change UW News and Information, Hannah Hickey Polar bears are listed as a threatened species as the ice-covered ocean they depend on for hunting and transportation becomes scarce. |
15 Mar 2017
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Polar Science Weekend attractions range from old-fashioned ice sled to future NASA satellite UW News and Information, Hannah Hickey University of Washington polar scientists are holding the 12th annual Polar Science Weekend, Friday through Sunday, March 3-5, at Pacific Science Center in Seattle. |
1 Mar 2017
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Seattle climate scientists spread word on warming, skip politics The Seattle Times, Jerry Large Climate scientists at the University of Washington want to talk more about their work because it and public policy are intertwined. They stick to the science side of the equation, which they want the rest of us to understand better so that we can make informed decisions about climate change. |
12 Jan 2017
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Arctic sea ice loss impacts beluga whale migration UW News and Information, Michelle Ma The annual migration of some beluga whales in Alaska is altered by sea ice changes in the Arctic, while other belugas do not appear to be affected. |
5 Jan 2017
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Captain Cook's notes describe now-vanishing Arctic ice wall Live Science, Mindy Weisberger The meticulous records of Capt. James Cook have found a new and modern-day value: Helping climate change scientists understand the extent of sea ice loss in the icy Canadian Arctic, according to a new study. |
30 Nov 2016
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Q&A: Harry Stern discusses historical maps, the Northwest Passage and the future of Arctic Ocean Shipping UW News and Information, Hannah Hickey Harry Stern, a polar scientist at the University of Washington’s Applied Physics Laboratory, has been studying the Arctic Ocean for decades, and sailed part of the Northwest Passage in 2009. Stern’s latest work uses the earliest explorers’ experiences to better understand a maritime environment that still contains many unknowns. |
18 Nov 2016
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How Capt. James Cook's intricate 1778 records reveal global warming today in Arctic The Seattle Times, Sandi Doughton Working with maps and logs from Cook’s voyage, along with other historical records and satellite imagery, University of Washington mathematician Harry Stern has tracked changes in ice cover in the Chukchi Sea, between Alaska and Russia, over nearly 240 years. |
16 Nov 2016
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A new look at Captain Cook shows just how much the Arctic has melted Popular Science, Eleanor Cummins Mathematician Harry Stern has used Cook’s records and those left behind by other early Arctic explorers to create a detailed history of ice cover in the region extending all the way back to 1778. |
4 Nov 2016
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All polar bears across the Arctic face shorter sea ice season UW News and Information, Michelle Ma A new University of Washington study reports a trend toward earlier sea ice melt in the spring and later ice growth in the fall across all polar bear populations, which can negatively impact the feeding and breeding capabilities of the bears. |
14 Sep 2016
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Every single part of the Arctic is becoming worse for polar bears Washington Post, Chelsea Harvey As climate change continues to heat up the Arctic, there’s rarely good news these days for the polar bears who call it home. And now, a broad new study charting nearly four decades of changes in Arctic sea ice has again underscored the animal’s plight. |
14 Sep 2016
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More bad news for polar bears: UW scientists find dire ice conditions Seattle Times, Sandi Doughton Scientists at the University of Washington have completed the first, Arctic-wide analysis of the changes in sea ice that have the greatest impact on the bears particularly the shift toward an earlier melt and a later freeze. |
14 Sep 2016
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UW polar scientist part of new book, museum exhibit on Northwest Passage UW News and Information, Hannah Hickey A University of Washington expert on sea ice is part of a new book and museum exhibit focused on an idea that has captured many imaginations: a Northwest Passage that would allow ship traffic between the Atlantic and Pacific oceans. |
14 Oct 2015
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First global review of Arctic marine mammals reveals uncertain future National Geographic, Emily Shenk Despite Arctic marine mammals being icons of climate change, little is known about their populations across the Arctic. |
24 Mar 2015
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Huge data gaps cloud fate of Arctic mammals Science Insider, Virginia Gewin A first-ever effort to gauge the ecological status of all 11 species of marine mammals living in the Arctic reveals a mixed picture. Researchers found that although some populations appear to be coping with climate change, others are in decline. |
17 Mar 2015
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Explore the polar ice caps at the Pacific Science Center The Seattle Times/KING 5 News, Christine Johnson University of Washington's Applied Physics Laboratory has teamed up with the Pacific Science Center for four days of demonstrations, exhibits and talks aimed at school children, families, and people interested in learning more about the poles. Polar Science Weekend will feature over ninety scientists that work in some of the most remote and challenging places on earth. |
2 Mar 2012
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Extent of Arctic summer sea ice at record low level Christian Science Monitor, Pete Spotts Researchers at the University of Washington's Polar Science Center note that in 2010 the volume of summer sea ice fell to a record low. Volume takes into account ice thickness, as well as extent. |
10 Sep 2011
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Go to the poles in your imagination at annual Polar Science Weekend University Week Hands-on exhibits, UW polar experts and a bit of imagination will transport you and your family to the extreme environments of the Arctic and Antarctica later this month during Polar Science Weekend at Pacific Science Center. |
11 Feb 2010
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UW becomes member of University of the Arctic University Week, Catherine O'Donnell Growing international interest in the Arctic led the UW in June to become a member of the University of the Arctic. Polar Science Center researchers Harry Stern and Kristin Laidre are charter participants. |
24 Jul 2008
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