Saved in:
Bibliographic Details
Main Authors: Rutgers van der Loeff, Michiel M, Cai, Pinghe, Stimac, Ingrid, Bauch, Dorothea, Hanfland, Claudia, Roeske, Tobias, Moran, S Bradley
Format: Dataset Open Access
Language:en
Published: PANGAEA 2012
Subjects:
Online Access:https://doi.org/10.1594/PANGAEA.772682
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1867167666663325696
author Rutgers van der Loeff, Michiel M
Cai, Pinghe
Stimac, Ingrid
Bauch, Dorothea
Hanfland, Claudia
Roeske, Tobias
Moran, S Bradley
author_facet Rutgers van der Loeff, Michiel M
Cai, Pinghe
Stimac, Ingrid
Bauch, Dorothea
Hanfland, Claudia
Roeske, Tobias
Moran, S Bradley
collection Datos científicos de ciencias marinas y ambientales
contents The transpolar drift is strongly enriched in 228Ra accumulated on the wide Arctic shelves with subsequent rapid offshore transport. We present new data of Polarstern expeditions to the central Arctic and to the Kara and Laptev seas. Because 226Ra activities in Pacific waters are 30% higher than in Atlantic waters, we correct 226Ra for the Pacific admixture when normalizing 228Ra with 226Ra. The use of 228Ra decay as age marker critically depends on the constancy in space and time of the source activity, a condition that has not yet adequately been tested. While 228Ra decays during transit over the central basin, ingrowth of 228Th could provide an alternative age marker. The high 228Th/228Ra activity ratio (AR = 0.8-1.0) in the central basins is incompatible with a mixing model based on horizontal eddy diffusion. An advective model predicts that 228Th grows to an equilibrium AR, the value of which depends on the scavenging regime. The low AR over the Lomonosov Ridge (AR = 0.5) can be due to either rapid transport (minimum age without scavenging 1.1 year) or enhanced scavenging. Suspended particulate matter load (derived from beam transmission and particulate 234Th) and total 234Th depletion data show that scavenging, although extremely low in the central Arctic, is enhanced over the Lomonosov Ridge, making an age of 3 years more likely. The combined data of 228Ra decay and 228Th ingrowth confirm the existence of a recirculating gyre in the surface water of the eastern Eurasian Basin with a river water residence time of at least 3 years.
format Dataset Open Access
id pangaea_https___doi_org_10_1594_PANGAEA_772682
institution PANGAEA
language en
publishDate 2012
publisher PANGAEA
record_format pangaea
spellingShingle Radium in Arctic surface water
Rutgers van der Loeff, Michiel M
Cai, Pinghe
Stimac, Ingrid
Bauch, Dorothea
Hanfland, Claudia
Roeske, Tobias
Moran, S Bradley
Arctic Ocean; ARK-XI/1; ARK-XXII/2; AWI_MarGeoChem; Barents Sea; CTD/Rosette; CTD-RO; East Siberian Sea; Expendable CTD; In situ pump; ISP; Kara Sea; Laptev Sea; Marine Geochemistry @ AWI; Polarstern; PS36; PS36/002-1; PS36/003-1; PS36/004-1; PS36/006-1; PS36/007-2; PS36/009-1; PS36/010-1; PS36/012-1; PS36/016-1; PS36/018-1; PS36/019-2; PS36/021-1; PS36/023-2; PS36/024A-2; PS36/025-2; PS36/029-2; PS36/031-3; PS36/033-2; PS36/040-2; PS36/042-2; PS36/044-2; PS36/045-2; PS36/047-2; PS36/049-2; PS36/051-1; PS36/052-1; PS36/056-2; PS36/060-1; PS36/062-1; PS36/065-1; PS36/071-1; PS36/073-1; PS36/080-2; PS36/084-1; PS36/089-2; PS36/091-2; PS36/094-1; PS70/237-4; PS70/239-2; PS70/257-6; PS70/261-3; PS70/263-3; PS70/264-6; PS70/266-3; PS70/268-6; PS70/271-6; PS70/272-2; PS70/274-5; PS70/276-4; PS70/277-4; PS70/279-4; PS70/284-2; PS70/285-9; PS70/290-5; PS70/294-6; PS70/299-3; PS70/301-4; PS70/303-2; PS70/309-6; PS70/312-6; PS70/322-5; PS70/326-4; PS70/328-14; PS70/333-6; PS70/335-2; PS70/338-4; PS70/342-12; PS70/346-2; PS70/349-3; PS70/352-7; PS70/358-2; PS70/363-9; PS70/371-7; PS70/377-3; PS70/382-2; PS70/385-7; PS70/389-4; PS70/400-3; PS70/407-3; PS70/409-2; PS70/411-4; PS70/XCTD58-1; PS70 SPACE DAMOCLES; XCTD
The transpolar drift is strongly enriched in 228Ra accumulated on the wide Arctic shelves with subsequent rapid offshore transport. We present new data of Polarstern expeditions to the central Arctic and to the Kara and Laptev seas. Because 226Ra activities in Pacific waters are 30% higher than in Atlantic waters, we correct 226Ra for the Pacific admixture when normalizing 228Ra with 226Ra. The use of 228Ra decay as age marker critically depends on the constancy in space and time of the source activity, a condition that has not yet adequately been tested. While 228Ra decays during transit over the central basin, ingrowth of 228Th could provide an alternative age marker. The high 228Th/228Ra activity ratio (AR = 0.8-1.0) in the central basins is incompatible with a mixing model based on horizontal eddy diffusion. An advective model predicts that 228Th grows to an equilibrium AR, the value of which depends on the scavenging regime. The low AR over the Lomonosov Ridge (AR = 0.5) can be due to either rapid transport (minimum age without scavenging 1.1 year) or enhanced scavenging. Suspended particulate matter load (derived from beam transmission and particulate 234Th) and total 234Th depletion data show that scavenging, although extremely low in the central Arctic, is enhanced over the Lomonosov Ridge, making an age of 3 years more likely. The combined data of 228Ra decay and 228Th ingrowth confirm the existence of a recirculating gyre in the surface water of the eastern Eurasian Basin with a river water residence time of at least 3 years.
title Radium in Arctic surface water
topic Arctic Ocean; ARK-XI/1; ARK-XXII/2; AWI_MarGeoChem; Barents Sea; CTD/Rosette; CTD-RO; East Siberian Sea; Expendable CTD; In situ pump; ISP; Kara Sea; Laptev Sea; Marine Geochemistry @ AWI; Polarstern; PS36; PS36/002-1; PS36/003-1; PS36/004-1; PS36/006-1; PS36/007-2; PS36/009-1; PS36/010-1; PS36/012-1; PS36/016-1; PS36/018-1; PS36/019-2; PS36/021-1; PS36/023-2; PS36/024A-2; PS36/025-2; PS36/029-2; PS36/031-3; PS36/033-2; PS36/040-2; PS36/042-2; PS36/044-2; PS36/045-2; PS36/047-2; PS36/049-2; PS36/051-1; PS36/052-1; PS36/056-2; PS36/060-1; PS36/062-1; PS36/065-1; PS36/071-1; PS36/073-1; PS36/080-2; PS36/084-1; PS36/089-2; PS36/091-2; PS36/094-1; PS70/237-4; PS70/239-2; PS70/257-6; PS70/261-3; PS70/263-3; PS70/264-6; PS70/266-3; PS70/268-6; PS70/271-6; PS70/272-2; PS70/274-5; PS70/276-4; PS70/277-4; PS70/279-4; PS70/284-2; PS70/285-9; PS70/290-5; PS70/294-6; PS70/299-3; PS70/301-4; PS70/303-2; PS70/309-6; PS70/312-6; PS70/322-5; PS70/326-4; PS70/328-14; PS70/333-6; PS70/335-2; PS70/338-4; PS70/342-12; PS70/346-2; PS70/349-3; PS70/352-7; PS70/358-2; PS70/363-9; PS70/371-7; PS70/377-3; PS70/382-2; PS70/385-7; PS70/389-4; PS70/400-3; PS70/407-3; PS70/409-2; PS70/411-4; PS70/XCTD58-1; PS70 SPACE DAMOCLES; XCTD
url https://doi.org/10.1594/PANGAEA.772682