Comparison of sea-ice thickness measurements under summer and winter conditions in the Arctic using a small electromagnetic induction device.

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dc.contributor.authorHaas, Christian
dc.contributor.authorGerland, Sebastian
dc.contributor.authorEicken, Hajo
dc.contributor.authorMiller, Heinz
dc.coverage.spatialMEDIAN LATITUDE: 80.834819 * MEDIAN LONGITUDE: 127.219880 * SOUTH-BOUND LATITUDE: 77.250000 * WEST-BOUND LONGITUDE: 66.850000 * NORTH-BOUND LATITUDE: 86.410000 * EAST-BOUND LONGITUDE: 155.000000 * DATE/TIME START: 1993-09-03T00:00:00 * DATE/TIME END: 1996-09-05T00:00:00
dc.date.accessioned2019-11-26T04:00:29Z
dc.date.available2019-11-26T04:00:29Z
dc.date.issued1997-10-07
dc.description.abstractDrillhole-determined sea-ice thickness was compared with values derived remotely using a portable small-offset loop-loop steady state electromagnetic (EM) induction device during expeditions to Fram Strait and the Siberian Arctic, under typical winter and summer conditions. Simple empirical transformation equations are derived to convert measured apparent conductivity into ice thickness. Despite the extreme seasonal differences in sea-ice properties as revealed by ice core analysis, the transformation equations vary little for winter and summer. Thus, the EM induction technique operated on the ice surface in the horizontal dipole mode yields accurate results within 5 to 10% of the drillhole determined thickness over level ice in both seasons. The robustness of the induction method with respect to seasonal extremes is attributed to the low salinity of brine or meltwater filling the extensive pore space in summer. Thus, the average bulk ice conductivity for summer multiyear sea ice derived according to Archie's law amounts to 23 mS/m compared to 3 mS/m for winter conditions. These mean conductivities cause only minor differences in the EM response, as is shown by means of 1-D modeling. However, under summer conditions the range of ice conductivities is wider. Along with the widespread occurrence of surface melt ponds and freshwater lenses underneath the ice, this causes greater scatter in the apparent conductivity/ice thickness relation. This can result in higher deviations between EM-derived and drillhole determined thicknesses in summer than in winter.
dc.formatapplication/zip, 83 datasets
dc.identifierhttps://doi.pangaea.de/10.1594/PANGAEA.728415
dc.identifierhttps://doi.org/10.1594/PANGAEA.728415
dc.identifier.citationHaas, Christian; Gerland, Sebastian; Eicken, Hajo; Miller, Heinz (1997): Comparison of sea-ice thickness measurements under summer and winter conditions in the Arctic using a small electromagnetic induction device. Geophysics, 62(3), 749-757, https://doi.org/10.1190/1.1444184
dc.identifier.urihttps://repository.geologyscience.ru/handle/123456789/8093
dc.language.isoen
dc.publisherPANGAEA
dc.rightsCC-BY-3.0: Creative Commons Attribution 3.0 Unported
dc.rightsAccess constraints: unrestricted
dc.sourceSupplement to: Haas, Christian; Gerland, Sebastian; Eicken, Hajo; Miller, Heinz (1997): Comparison of sea-ice thickness measurements under summer and winter conditions in the Arctic using a small electromagnetic induction device. Geophysics, 62(3), 749-757, https://doi.org/10.1190/1.1444184
dc.subjectArctic Ocean
dc.subjectArk11_203p1
dc.subjectArk11_205p1
dc.subjectArk11_205p2
dc.subjectArk11_206p1
dc.subjectArk11_207p1
dc.subjectArk11_209p1
dc.subjectArk11_210p1
dc.subjectArk11_216p1
dc.subjectArk11_219p1
dc.subjectArk11_219p3
dc.subjectArk11_221p1
dc.subjectArk11_228p1
dc.subjectArk11_229p1
dc.subjectArk11_230p1
dc.subjectArk11_232p1
dc.subjectArk11_232p2
dc.subjectArk11_233p1
dc.subjectArk11_234p1
dc.subjectArk11_235p1
dc.subjectArk11_236p1
dc.subjectArk11_237p1
dc.subjectArk11_237p2
dc.subjectArk11_238p1
dc.subjectArk11_239p1
dc.subjectArk11_240p1
dc.subjectArk11_241p1
dc.subjectArk11_242p1
dc.subjectArk11_243p1
dc.subjectArk11_247p1
dc.subjectArk12_207p1
dc.subjectArk12_207p2
dc.subjectArk12_208p1
dc.subjectArk12_209p1
dc.subjectArk12_210p1
dc.subjectArk12_212p1
dc.subjectArk12_212p2
dc.subjectArk12_213p1
dc.subjectArk12_214p1
dc.subjectArk12_215p1
dc.subjectArk12_216p1
dc.subjectArk12_218p1
dc.subjectArk12_219p1
dc.subjectArk12_220p1
dc.subjectArk12_221p1
dc.subjectArk12_222p1
dc.subjectArk12_223p1
dc.subjectArk12_226p1
dc.subjectArk12_227p1
dc.subjectArk12_229p1
dc.subjectArk12_230p1
dc.subjectArk12_231p1
dc.subjectArk12_232p1
dc.subjectArk12_232p2
dc.subjectArk12_232p3
dc.subjectArk12_233p1
dc.subjectArk12_234p1
dc.subjectArk12_236p1
dc.subjectArk12_236p2
dc.subjectArk12_238p1
dc.subjectArk12_239p1
dc.subjectArk12_240p1
dc.subjectArk12_240p2
dc.subjectArk12_240p3
dc.subjectArk12_240p4
dc.subjectArk12_240p5
dc.subjectArk12_240p6
dc.subjectArk12_240p7
dc.subjectArk12_242p1
dc.subjectArk12_243p1
dc.subjectArk12_246p1
dc.subjectArk12_247p1
dc.subjectArk12_249p1
dc.subjectArk9_4_246p1
dc.subjectArk9_4_251p1
dc.subjectArk9_4_253p1
dc.subjectArk9_4_254p1
dc.subjectArk9_4_255p1
dc.subjectArk9_4_256p1
dc.subjectArk9_4_257p1
dc.subjectArk9_4_258p1
dc.subjectArk9_4_260p1
dc.subjectArk9_4_261p1
dc.subjectArk9_4_264p1
dc.subjectARK-IX/4
dc.subjectARK-XI/1
dc.subjectARK-XII
dc.subjectAWI_SeaIce
dc.subjectEast Siberian Sea
dc.subjectFEME
dc.subjectICEM
dc.subjectIce measurement
dc.subjectKara/Laptev Sea/Transpolar Drift
dc.subjectLaptev Sea
dc.subjectPolarstern
dc.subjectPS27
dc.subjectPS36
dc.subjectPS41
dc.subjectRemote Sensing of Sea Ice Properties
dc.subjectSea Ice Physics @ AWI
dc.titleComparison of sea-ice thickness measurements under summer and winter conditions in the Arctic using a small electromagnetic induction device.
dc.title.alternativeGround-based electromagnetic (EM) and drill-hole ice and snow thickness and melt pond depth measurements during Polarstern cruise ARK-IX/4, ARK-XI/1, and ARK-XII
dc.typeDataset

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