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Sea ice dynamics influence halogen deposition to Svalbard

Cryosphere (2013) 7(5) 1645-1658
DOI: 10.5194/tc-7-1645-2013
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Abstract

Sea ice is an important parameter in the climate system and its changes impact upon the polar albedo and atmospheric and oceanic circulation. Iodine (I) and bromine (Br) have been measured in a shallow firn core drilled at the summit of the Holtedahlfonna glacier (Northwest Spitsbergen, Svalbard). Changing I concentrations can be linked to the March-May maximum sea ice extension. Bromine enrichment, indexed to the Br / Na sea water mass ratio, appears to be influenced by changes in the seasonal sea ice area. I is emitted from marine biota and so the retreat of March-May sea ice coincides with enlargement of the open-ocean surface which enhances marine primary production and consequent I emission. The observed Br enrichment could be explained by greater Br emissions during the Br explosions that have been observed to occur mainly above first year sea ice during the early springtime. In this work we present the first comparison between halogens in surface snow and Arctic sea ice extension. Although further investigation is required to characterize potential depositional and post-depositional processes, these preliminary findings suggest that I and Br can be linked to variability in the spring maximum sea ice extension and seasonal sea ice surface area.

Figures

  • Fig. 1. (a) Map of the drilling site (79◦09′ N, 13◦23′ E; 1150 m a.s.l.) at Holtedahlfonna glacier at Spitsbergen, Svalbard (courtesy of Norwegian Polar Institute). (b) Descriptive map of the Arctic sea ice regions (from NSIDC) and a red dot indicate the Spitzbergen firn core location.
  • Fig. 2. 18O isotopic ratios (b) and density profiles (a) in the Holtedahlfonna firn core. Vertical black bars (c) indicate mass balance measurements carried out at 1150 m a.s.l. in the Holtedahlfonna glacier summit, 40 m west of the drilling site. Diamonds (c) indicate the presence of ice lenses in the core; the increasing size of the diamond represents increasing thickness of the lenses. These are characterized as thin (< 20 mm), medium (20–100 mm) and large (> 100 mm). These data have been used to construct the core chronology, which covers 10 yr of deposition. Statistical assessment of the smoothed (smth) 18O profile turnpoints (d). Solid red triangles indicate assigned summer peaks and solid blue triangles indicate assigned winter troughs. Empty red and blue triangles indicate spurious assignments of summer peaks and winter troughs. The grey bars indicate summer periods as inferred from the data set.
  • Fig. 3. Iodine concentrations in pg g−1 (black circles) compared with spring sea ice extent in km2 (blue circles, reverse scale). Increased I concentrations in the firn core can be linked to decreased spring sea ice extension. The 18O (‰) profile is shown in red. The grey bars indicate spring-summer periods. The dotted line indicates the iodine detection limit (5 pg g−1). Sea ice data from NSIDC.
  • Fig. 4. March–May back trajectory (BT) calculations using HYSPLIT during the period 2003–2011. Average 3 and 6 day back trajectories are shown in the first top chart. Three-day back trajectory calculations for each year are also shown.
  • Fig. 5. Comparison of Iodine trend in the firn core recovered with changes in March–May sea ice from single sectors. Panel (g) shows the sum of the Greenland sea, Barents sea and Baffin bay regions.
  • Fig. 6. Bromine enrichment (%Brenr, black circles) is compared to seasonal sea ice area (blue circles). Seasonal sea ice area was calculated as the difference between the March maxima of sea ice and the September sea ice minima of the previous year. Seasonal variability of %Brenr is present in the upper part of the core. Bromine is enriched relative to seawater Na during the springtime, when the seasonal sea ice-produced Bromine explosion is most active. The grey bars indicate summer periods. Sea ice data from NSIDC.
  • Fig. 7. Comparison of %Brenr trend in the firn core recovered with changes in seasonal sea ice from single Arctic sectors.

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CITATION STYLE

APA

Spolaor, A., Gabrieli, J., Martma, T., Kohler, J., Björkman, M. B., Isaksson, E., … Barbante, C. (2013). Sea ice dynamics influence halogen deposition to Svalbard. Cryosphere, 7(5), 1645–1658. https://doi.org/10.5194/tc-7-1645-2013

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