Your search keyword '"Hajo EICKEN"' showing total 4 results

1. Landfast sea ice breakouts: Stabilizing ice features, oceanic and atmospheric forcing at Barrow, Alaska

Author

J.C. 'Craig' George, M. V. Rohith, Chandra Kambhamettu, Yasushi Fukamachi, Andrew R. Mahoney, Joshua Jones, Hajo Eicken, and Kay I. Ohshima

Subjects

Drift ice, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 0211 other engineering and technologies, Geology, 02 engineering and technology, Antarctic sea ice, Aquatic Science, Pressure ridge, Oceanography, 01 natural sciences, Arctic ice pack, Ice shelf, Fast ice, Climatology, Sea ice thickness, Sea ice, 021101 geological & geomatics engineering, 0105 earth and related environmental sciences

Abstract

Landfast sea ice is an important seasonal feature along most Arctic coastlines, such as that of the Chukchi Sea near Barrow, Alaska. Its stability throughout the ice season is determined by many factors but grounded pressure ridges are the primary stabilizing component. Landfast ice breakouts occur when these grounded ridges fail or unground, and previously stationary ice detaches from the coast and drifts away. Using ground-based radar imagery from a coastal ice and ocean observatory at Barrow, we have developed a method to estimate the extent of grounded ridges by tracking ice motion and deformation over the course of winter and have derived ice keel depth and potential for grounding from cumulative convergent ice motion. Estimates of landfast ice grounding strength have been compared to the atmospheric and oceanic stresses acting on the landfast ice before and during breakout events to determine prevailing causes for the failure of stabilizing features. Applying this approach to two case studies in 2008 and 2010, we conclude that a combination of atmospheric and oceanic stresses may have caused the breakouts analyzed in this study, with the latter as the dominant force. Preconditioning (as weakening) of grounded ridges by sea level variations may facilitate failure of the ice sheet leading to breakout events.

Published

2016

2. Surface water mass composition changes captured by cores of Arctic land-fast sea ice

Author

Hajo Eicken, Joshua Jones, Andrew R. Mahoney, Yasushi Fukamachi, R. Van Hale, A. J. Gough, and Inga J. Smith

Subjects

Drift ice, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Geology, Antarctic sea ice, Aquatic Science, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Arctic ice pack, Fast ice, Sea ice thickness, Sea ice, Cryosphere, Sea ice concentration, 0105 earth and related environmental sciences

Abstract

In the Arctic, land-fast sea ice growth can be influenced by fresher water from rivers and residual summer melt. This paper examines a method to reconstruct changes in water masses using oxygen isotope measurements of sea ice cores. To determine changes in sea water isotope composition over the course of the ice growth period, the output of a sea ice thermodynamic model (driven with reanalysis data, observations of snow depth, and freeze-up dates) is used along with sea ice oxygen isotope measurements and an isotopic fractionation model. Direct measurements of sea ice growth rates are used to validate the output of the sea ice growth model. It is shown that for sea ice formed during the 2011/2012 ice growth season at Barrow, Alaska, large changes in isotopic composition of the ocean waters were captured by the sea ice isotopic composition. Salinity anomalies in the ocean were also tracked by moored instruments. These data indicate episodic advection of meteoric water, having both lower salinity and lower oxygen isotopic composition, during the winter sea ice growth season. Such advection of meteoric water during winter is surprising, as no surface meltwater and no local river discharge should be occurring at this time of year in that area. How accurately changes in water masses as indicated by oxygen isotope composition can be reconstructed using oxygen isotope analysis of sea ice cores is addressed, along with methods/strategies that could be used to further optimize the results. The method described will be useful for winter detection of meteoric water presence in Arctic fast ice regions, which is important for climate studies in a rapidly changing Arctic. Land-fast sea ice effective fractionation coefficients were derived, with a range of +1.82‰ to +2.52‰. Those derived effective fractionation coefficients will be useful for future water mass component proportion calculations. In particular, the equations given can be used to inform choices made when engaging in end member determination for working out the component proportions of water masses.

Published

2016

3. Rapid physically driven inversion of the air–sea ice CO2 flux in the seasonal landfast ice off Barrow, Alaska after onset of surface melt

Author

Kunio Shirasawa, Hajo Eicken, Daiki Nomura, and Rolf Gradinger

Subjects

0106 biological sciences, geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, 010604 marine biology & hydrobiology, Geology, Brine rejection, Aquatic Science, Oceanography, 01 natural sciences, Arctic ice pack, Salinity, Brinicle, Sea ice growth processes, 13. Climate action, Sea ice thickness, Melt pond, Sea ice, 0105 earth and related environmental sciences

Abstract

The air–sea ice CO 2 flux was measured over landfast sea ice in the Chukchi Sea, off Barrow, Alaska in late May 2008 with a chamber technique. The ice cover transitioned from a cold early spring to a warm late spring state, with an increase in air temperature and incipient surface melt. During melt, brine salinity and brine dissolved inorganic carbon concentration (DIC) decreased from 67.3 to 18.7 and 3977.6 to 1163.5 μmol kg −1 , respectively. In contrast, the salinity and DIC of under-ice water at depths of 3 and 5 m below the ice surface remained almost constant with average values of 32.4±0.3 (standard deviation) and 2163.1±16.8 μmol kg −1 , respectively. The air–sea ice CO 2 flux decreased from +0.7 to −1.0 mmol m −2 day −1 (where a positive value indicates CO 2 being released to the atmosphere from the ice surface). During this early to late spring transition, brought on by surface melt, sea ice shifted from a source to a sink for atmospheric CO 2 , with a rapid decrease of brine DIC likely associated with a decrease in the partial pressure of CO 2 of brine from a supersaturated to an undersaturated state compared to the atmosphere. Formation of superimposed ice coincident with melt was not sufficient to shut down ice–air gas exchange.

Published

2010

4. Sea-ice processes in the Laptev Sea and their importance for sediment export

Author

Hajo Eicken, V. Alexandrov, T. Viehoff, Heidemarie Kassens, Torge Martin, and Erk Reimnitz

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Anchor ice, Geology, Antarctic sea ice, Aquatic Science, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Arctic ice pack, 13. Climate action, Sea ice thickness, Sea ice, 14. Life underwater, Entrainment (chronobiology), Sedimentary budget, 0105 earth and related environmental sciences, Frazil ice

Abstract

Based on remote-sensing data and an expedition during August-September 1993, the importance of the Laptev Sea as a source area for sediment-laden sea ice was studied. Ice-core analysis demonstrated the importance of dynamic ice-growth mechanisms as compared to the multi-year cover of the Arctic Basin. Ice-rafted sediment (IRS) was mostly associated with congealed frazil ice, although evidence for other entrainment mechanisms (anchor ice, entrainment into freshwater ice) was also found. Concentrations of suspended particulate matter (SPM) in patches of dirty ice averaged at 156 g m(-3) (standard deviation sigma = 140 g m(-3)), with a background concentration of 5 g m(-3). The potential for sediment entrainment over the broad, shallow Laptev Sea shelf during fall freeze-up was studied through analysis of remote-sensing data and weather-station records for the period 1979-1994. Freeze-up commences on 26 September (sigma = 7 d) and is completed after 19 days (sigma = 6 d). Meteorological conditions as well as ice extent prior to and during freeze-up vary considerably, the open-water area ranging between 107 x 10(3) and 447 x 10(3) km(2). Ice motion and transport of IRS were derived from satellite imagery and drifting buoys for the period during and after the expedition (mean ice velocities of 0.04 and 0.05 m s(-1), respectively). With a best-estimate sediment load of 16 t km(-2) (ranging between 9 and 46 t km(-2)), sediment export from the eastern Laptev Sea amounts to 4 x 10(6) t yr(-1), with extremes of 2 x 10(6) and 11 x 10(6) t yr(-1). Implications for the sediment budget of the Laptev shelf, in particular with respect to riverine input of SPM, which may be of the same order of magnitude, are discussed.

Published

1997