Your search keyword '"Bjørk, Anders A."' showing total 8 results

1. Cosmogenic nuclide inheritance in Little Ice Age moraines - A case study from Greenland

Author

Larsen, Nicolaj K., Søndergaard, Anne Sofie, Levy, Laura B., Laursen, Charlotte H., Bjørk, Anders A., Kjeldsen, Kristian K., Funder, Svend, Strunk, Astrid, Olsen, Jesper, and Kjær, Kurt H.

Published

2021

2. Rapidly changing glaciers, ocean and coastal environments, and their impact on human society in the Qaanaaq region, northwestern Greenland

Author

Sugiyama, Shin, Kanna, Naoya, Sakakibara, Daiki, Ando, Takuto, Asaji, Izumi, Kondo, Ken, Wang, Yefan, Fujishi, Yoshiki, Fukumoto, Shungo, Podolskiy, Evgeniy, Fukamachi, Yasushi, Takahashi, Minori, Matoba, Sumito, Iizuka, Yoshinori, Greve, Ralf, Furuya, Masato, Tateyama, Kazutaka, Watanabe, Tatsuya, Yamasaki, Shintaro, Yamaguchi, Atsushi, Nishizawa, Bungo, Matsuno, Kohei, Nomura, Daiki, Sakuragi, Yuta, Matsumura, Yoshimasa, Ohashi, Yoshihiko, Aoki, Teruo, Niwano, Masashi, Hayashi, Naotaka, Minowa, Masahiro, Jouvet, Guillaume, van Dongen, Eef, Bauder, Andreas, Funk, Martin, Bjørk, Anders Anker, and Oshima, Toku

Published

2021

3. Glacier response to the Little Ice Age during the Neoglacial cooling in Greenland.

Author

Kjær, Kurt H., Bjørk, Anders A., Kjeldsen, Kristian K., Hansen, Eric S., Andresen, Camilla S., Siggaard-Andersen, Marie-Louise, Khan, Shfaqat A., Søndergaard, Anne Sofie, Colgan, William, Schomacker, Anders, Woodroffe, Sarah, Funder, Svend, Rouillard, Alexandra, Jensen, Jens Fog, and Larsen, Nicolaj K.

Subjects

*MELTWATER, *LITTLE Ice Age, *GLACIERS, *GREENLAND ice, *ICE sheets, *ICE cores, *ICE caps, *COOLING

Abstract

In the Northern Hemisphere, an insolation driven Early to Middle Holocene Thermal Maximum was followed by a Neoglacial cooling that culminated during the Little Ice Age (LIA). Here, we review the glacier response to this Neoglacial cooling in Greenland. Changes in the ice margins of outlet glaciers from the Greenland Ice Sheet as well as local glaciers and ice caps are synthesized Greenland-wide. In addition, we compare temperature reconstructions from ice cores, elevation changes of the ice sheet across Greenland and oceanographic reconstructions from marine sediment cores over the past 5,000 years. The data are derived from a comprehensive review of the literature supplemented with unpublished reports. Our review provides a synthesis of the sensitivity of the Greenland ice margins and their variability, which is critical to understanding how Neoglacial glacier activity was interrupted by the current anthropogenic warming. We have reconstructed three distinct periods of glacier expansion from our compilation: two older Neoglacial advances at 2,500 – 1,700 yrs. BP (Before Present = 1950 CE, Common Era) and 1,250 – 950 yrs. BP; followed by a general advance during the younger Neoglacial between 700-50 yrs. BP, which represents the LIA. There is still insufficient data to outline the detailed spatio-temporal relationships between these periods of glacier expansion. Many glaciers advanced early in the Neoglacial and persisted in close proximity to their present-day position until the end of the LIA. Thus, the LIA response to Northern Hemisphere cooling must be seen within the wider context of the entire Neoglacial period of the past 5,000 years. Ice expansion appears to be closely linked to changes in ice sheet elevation, accumulation, and temperature as well as surface-water cooling in the surrounding oceans. At least for the two youngest Neoglacial advances, volcanic forcing triggering a sea-ice /ocean feedback, could explain their initiation. There are probably several LIA glacier fluctuations since the first culmination close to 1250 CE (Common Era) and available data suggests ice culminations in the 1400s, early to mid-1700s and early to mid-1800s CE. The last LIA maxima lasted until the present deglaciation commenced around 50 yrs. BP (1900 CE). The constraints provided here on the timing and magnitude of LIA glacier fluctuations delivers a more realistic background validation for modelling future ice sheet stability. [ABSTRACT FROM AUTHOR]

Published

2022

4. Holocene ice margin variations of the Greenland Ice Sheet and local glaciers around Sermilik Fjord, southeast Greenland.

Author

Larsen, Nicolaj K., Siggaard-Andersen, Marie-Louise, Bjørk, Anders A., Kjeldsen, Kristian K., Ruter, Anthony, Korsgaard, Niels J., and Kjær, Kurt H.

Subjects

*GREENLAND ice, *ICE sheets, *HOLOCENE Epoch, *ICE caps, *FJORDS, *GLACIERS, *ALPINE glaciers, *MELTWATER

Abstract

Understanding the long-term difference in the response times of ice sheets, peripheral ice caps and glaciers may provide information about their respective sensitivities to climate change. However, there are only a few places where the history of local glaciers, ice caps (GICs) and the Greenland Ice Sheet (GrIS) have been recorded in the same area. In this study, we use proglacial threshold lake records from four sites around Sermilik Fjord, in southeast Greenland to determine the Holocene ice marginal variations. Combined with other published records from the area, we find that the GrIS margin receded to within its present extent in the Early Holocene ~9.6 cal ka BP, probably reaching its minimum extent by ~7.3 to 6.3 cal ka BP before readvancing to its maximum Late Holocene position between ~2.6 and 0.3 cal ka BP. The GICs began to retreat ~9.5 cal ka BP and completely melted away for an extended period between ~8 and 4 ka during the Middle Holocene. Regrowth of the GICs began during the early- and late Neoglacial and they reached their maximum extent between ~1.2 and 0.7 cal ka BP. In general, we find a coherent pattern of ice marginal variations between the GrIS and GICs, which coincides with the major Holocene climate changes. However, our results also demonstrate that there are differences in the synchronicity between individual records, which largely are dictated by the local topography that determines when ice marginal changes were recorded in proglacial lakes. Accordingly, this study illustrates both the advantages and limitations of the method and highlight the need for multiple proglacial lake records to constrain past glacier variations in a region. [ABSTRACT FROM AUTHOR]

Published

2022

5. Local glaciers record delayed peak Holocene warmth in south Greenland.

Author

Larocca, Laura J., Axford, Yarrow, Bjørk, Anders A., Lasher, G. Everett, and Brooks, Jeremy P.

Subjects

*HOLOCENE Epoch, *GLACIERS, *LAKE sediments, *LITTLE Ice Age, *GLACIOLOGY, *CLIMATE change, *GLACIAL landforms, *ATMOSPHERIC temperature

Abstract

Local glaciers and ice caps (GICs) respond sensitively and quickly, on the scale of decades to centuries, to climate variations. Continuous records of past fluctuations in GIC size provide information on the timing and magnitude of Holocene climate shifts, and a longer-term perspective on 21st century glacier retreat. Although there is broad-scale agreement on millennial-scale trends in Holocene climate variability and fluctuations in local GICs in Greenland, regional variations are only loosely constrained. Here we present three Holocene proglacial lake sediment records from South Greenland, an area with abundant local glaciers but few Holocene-length paleoclimate records. In addition, we use geospatial analysis to model past equilibrium-line altitudes (ELAs) and thereby constrain the magnitude of ablation-season temperature change during the warmest and coolest periods of the Holocene. Physical and geochemical sedimentary characteristics show that two of the proglacial lakes continued to receive glacial meltwater input until ∼7.3 and ∼7.1 ka BP. The survival of local glaciers implies that South Greenland remained relatively cool, and that summer temperatures gradually warmed, but did not warm well beyond 1.2 °C above present in the early Holocene. In the mid-Holocene, from ∼7.1 to 5.5 ka BP, organic sedimentation at these two sites indicates that local glaciers became very small, or more likely melted away completely. The glaciers within the third lake's catchment melted away prior to ∼5.2 ka BP, as sediments deposited earlier in the Holocene could not be dated at this site. We estimate that summer temperatures increased by at least 1.2–1.8 °C above present by ∼7.3–7.1 ka BP. Our results are consistent with other observations that suggest a north-to-south gradient in the timing of Holocene thermal maximum conditions, with southern Greenland experiencing a delayed warming relative to other regions in Greenland. As summer temperatures cooled in the Neoglacial, our records show that sustained glacier regrowth began ∼3.1 ka BP with glaciers in the southernmost catchment, which at present, receive the most precipitation. In the other two catchments, which host smaller glaciers in a drier environment, regrowth began at ∼1.3 and ∼1.2 ka BP, the timing of which is in agreement with other glacial records from the Arctic Atlantic region. Local glaciers reached their maximum late Holocene extents during a cooler, second phase of the Little Ice Age (LIA) ∼0.2-0.1 ka BP, that we estimate was at least 0.4–0.9 °C cooler than present. Overall, these findings improve understanding of the spatio-temporal dynamics of Holocene glacier and climate change in Greenland, potentially yielding valuable information about their future response. • Early Holocene summer temperatures in South Greenland were relatively cool and did not warm well beyond 1.2 °C above present. • Peak warmth occurred in the mid-Holocene, between ∼7.1-5.5 ka BP, with summer temperatures at least 1.2–1.8 °C above present. • Regrowth of local glaciers at ∼3.1, ∼1.3, and ∼1.2 ka BP reflect a broad, gradual pattern of cooling summer air temperatures. • LIA historical moraines suggest summer air temperatures at least 0.4–0.9 °C cooler than present. • Greenlandic records show GICs in the north became smaller or disappeared earlier in the Holocene than those in the south. [ABSTRACT FROM AUTHOR]

Published

2020

6. Geodetic and model data reveal different spatio-temporal patterns of transient mass changes over Greenland from 2007 to 2017.

Author

Zhang, Bao, Liu, Lin, Khan, Shfaqat Abbas, van Dam, Tonie, Bjørk, Anders Anker, Peings, Yannick, Zhang, Enze, Bevis, Michael, Yao, Yibin, and Noël, Brice

Subjects

*MASS budget (Geophysics), *GREENLAND ice, *GLOBAL Positioning System, *PRECIPITATION anomalies, *GEODETIC observations, *ATMOSPHERIC circulation

Abstract

• Geodetic data and model reveal transient mass changes in Greenland. • NW Greenland exhibited different change patterns than the rest subregions. • Precipitation anomalies were opposite in signs in east & west Greenland. • Atmospheric circulation anomalies may cause most of the transient mass changes. Much of the research to understand the ice mass changes of Greenland ice sheet (GrIS) has focused on detecting linear rates and accelerations at decadal or longer periods. The transient (short-term, non-secular) mass changes show large variability, and if not properly accounted for, can introduce significant biases into estimates of long-term ice mass loss rates and accelerations. Despite the growing number of geodetic observations, in terms of spatial coverage, types of observables, and the extent of the time series, studies of the transient mass changes over GrIS are lacking. To address this limitation, we apply multi-channel singular spectral analysis to the Gravity Recovery and Climate Experiment (GRACE) mass concentrations (mascon), surface mass balance (SMB) model output, and ice discharge data, to determine the transient mass changes over Greenland over the decade (2007 to 2017). The goal of this analysis is to elucidate the spatio-temporal variability of the ice mass change. For the entire GrIS, both the mascon and SMB transient mass changes are characterized by a sustained mass gain from late 2007 to early 2010, a sustained mass loss from early 2010 to early 2013, and a mass gain from early 2013 to mid-2015. Global Positioning System sites deployed along the coast of Greenland showed uplift from early 2010 to early 2013 and subsidence from early 2013 to 2015, consistent with the corresponding ice mass loss and gain of the entire GrIS. The peak-to-peak amplitude of the transient mass change was estimated to be −294 ± 27 Gt from GRACE mascons and -252 ± 16 Gt from the SMB where the latter value includes the effect of ice discharge. The transient mass change due to ice discharge accounted for less than 10% of the total transient mass change. Our regional assessment reveals that the central-west, southwest, northeast, and southeast regions display similar time-varying patterns as we found for the entire GrIS, but the north and northwest regions show different patterns. Atmospheric circulation anomalies as measured by the Greenland Blocking Index (GBI) are able to explain most of these transient anomalies. More specifically, high-GBI-associated high temperature was one of the main reasons for the transient mass loss of the entire GrIS during 2010-2012 while low GBI can explain the transient mass gain during 2013-2015. Contrasting behaviors of precipitation anomalies in east and west Greenland under abnormally high or low GBI conditions may explain the different patterns of the transient mass change in the northwest and the rest of Greenland. [ABSTRACT FROM AUTHOR]

Published

2019

7. Strong altitudinal control on the response of local glaciers to Holocene climate change in southwest Greenland.

Author

Larsen, Nicolaj K., Strunk, Astrid, Levy, Laura B., Olsen, Jesper, Bjørk, Anders, Lauridsen, Torben L., Jeppesen, Erik, and Davidson, Thomas A.

Subjects

*CLIMATE change, *HOLOCENE Epoch, *QUATERNARY Period, *ICE sheets, *GLACIERS

Abstract

Accelerating ice loss during recent years has made the Greenland Ice Sheet one of the largest single contributors to global sea level rise, accounting for 0.5 of the total 3.2 mm yr −1 . This loss is predicted to continue and will most likely increase in the future as a consequence of global warming. However, the sensitivity of glaciers and ice caps (GICs) in Greenland to prolonged warm periods is less well constrained and geological records documenting the long-term glacial history are needed to put recent observations into a broader perspective. Here we report the results from three proglacial lakes where fluctuations in local glaciers located at different altitudes in Kobbefjord, southwest Greenland have been recorded. Our results show that the lakes received meltwater from the initial deglaciation of the area ∼9.2 cal. ka BP until ∼8.7–7.9 cal. ka BP when the meltwater input ceased as the glaciers most likely disappeared. Regrowth of glaciers began again at ∼5.5 cal. ka BP at ∼1370 m a.s.l., ∼3.6 cal. ka at ∼1170 m a.s.l., and ∼1.6 cal. ka BP at ∼1000 m a.s.l., clearly reflecting strong altitudinal control of the GIC response to Neoglacial cooling. Our results highlight that GICs in Kobbefjord, southwest Greenland are primarily influenced by changes in summer air temperatures and winter precipitation and that they are facing a rapid decay that most likely will result in their disappearance within the next centuries as a consequence of global warming. If current 21st Century retreat rates continue, the GICs in the study area will be completely gone in ∼30–90 years, with the smallest GICs disappearing first. [ABSTRACT FROM AUTHOR]

Published

2017

8. Multi-phased deglaciation of south and southeast Greenland controlled by climate and topographic setting.

Author

Levy, Laura B., Larsen, Nicolaj K., Knudsen, Mads F., Egholm, David L., Bjørk, Anders A., Kjeldsen, Kristian K., Kelly, Meredith A., Howley, Jennifer A., Olsen, Jesper, Tikhomirov, Dmitry, Zimmerman, Susan R.H., and Kjær, Kurt H.

Subjects

*ENVIRONMENTAL engineering, *GLACIAL melting, *CLIMATE change, *GREENLAND ice, *YOUNGER Dryas, *ICE sheets

Abstract

To put recent Greenland Ice Sheet (GrIS) ice loss into a longer-term context, we must understand its behavior during late-glacial and Early Holocene warming. Previous results seem to suggest that there is a large contrast in the timing of deglaciation between South and Southeast Greenland. However, because of lack of available data, in particular in Southeast Greenland, it is difficult to assess how the ice sheet responded to major late-glacial and Early Holocene climate changes. In this study, we use 41 new 10Be ages to constrain the deglaciation chronology in 12 new locations from the coast to the present ice margin in South and Southeast Greenland. We find that South Greenland (south of 61.5°N) deglaciated between ∼14.8 and 11.9 ka, whereas Southeast Greenland (61.5°N to 68.2°N) deglaciated between ∼11.4 and 11.3 ka. The deglaciation of the coastal, low-intermediate topography in South Greenland coincides with increased air surface temperatures during the Bølling-Allerød with fjords continuing to deglaciate into the Early Holocene. In contrast, the ice sheet persisted at the coast until the late-glacial and Early Holocene in Southeast Greenland, likely because of increased precipitation in the high alpine topography and fjord geometry and bathymetry (e.g. width of fjords and presence of sills). This multi-phased deglaciation demonstrates a contrasting response of the southern GrIS to changes in climate and variations in topographic setting, and that the spatial deglaciation of the GrIS was complex and likely did not respond to a single external climate forcing. • Deglaciation began in South Greenland by 14.8 ka coeval with rising air temperature. • Warm Atlantic water likely drove deglaciation during the Younger Dryas. • Ice retreated from Southeast Greenland coast by 11.3 ka when air temperatures rose. • Evidence of a Neoglacial advance occurs in Southeast Greenland by ∼1.9 ka. • Local climate, topography and fjord geometry/bathymetry likely mediated ice retreat. [ABSTRACT FROM AUTHOR]

Published

2020