Detection of rapid deposition of sea ice-rafted material to the Arctic Ocean benthos using the cosmogenic tracer Be-7

During three icebreaker cruises in the Arctic Ocean under different sea-ice conditions in 2002, undisturbed benthic surface sediments were collected and assayed for the presence of a short-lived (t(1/2) = 53 d), particle-reactive cosmogenic radionuclide, Be-7, that is solely derived from atmospheric deposition. Under largely ice-covered conditions in May-June 2002, we did not detect this radionuclide in benthic surface sediments, despite significant inventories present in ice-rafted snow on the overlying sea ice (mean = 86.8 Bq m(-2) +/- 32.0 SD; n = 9). During the July-August 2002 Shelf-Basin Interactions (SBI) cruise aboard the USCGC Healy and during a simultaneous cruise of the CCGS Sir Wilfrid Laurier on the Bering and Chukchi Shelf, which occupied the same general region following retreat and dissolution of Arctic ice cover, the 7 Be present in this snow as well as surface deposition on to the sea ice-free water surface was detected in many benthic surface sediments, including some as deep as 945 in in Barrow Canyon. Inventories of Be-7 in sediments were as high (similar to 60 Bq m(-2)) as the entire decay-corrected inventory present earlier in some snow samples collected on the sea-ice cover. Other deposition indicators such as the inventories of sediment chlorophyll, sediment oxygen respiration rates and Th-234-derived export fluxes also showed post-ice melt particle deposition and vertical transport, but in most cases the Be-7 deposition was not tightly correlated with these other indicators, suggesting that Be-7 sedimentation may not be controlled by the same processes. Our observations indicate that materials in sea ice, including contaminants, particulate organic, and mineral matter originating from atmospheric deposition or entrained in continental shelf sediments and rafted onto sea ice, can be rapidly transported to depth. The re-distribution of these materials as sea-ice drifts and eventually melts has the potential for impacting Arctic Ocean biogeochemical cycles and contaminant concentrations in areas of the Arctic remote from the original point of deposition. (c) 2005 Elsevier Ltd. All rights reserved.