Tracing the Three Atlantic Branches Entering the Arctic Ocean With <sup>129</sup>I and <sup>236</sup>U

Casacuberta, Núria; Christl, Marcus; Vockenhuber, Christof; Wefing, Anne-Marie; Wacker, Lukas; Masqué, Pere; Synal, Hans-Arno; Loeff, Michiel Rutgers v. d.

doi:10.1029/2018jc014168

Cited by 44 publications

(92 citation statements)

References 43 publications

(67 reference statements)

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“…The residence time of deep water in the Makarov Basin was determined to be 400–650 years based on the 226 Ra profile at station 30 (Figure S10) and the range in the 226 Ra flux from sediments in the Makarov Basin. This value is similar to previous estimates of ~300–600 years (Jones et al, ; Schlosser et al, ; Tanhua et al, ; Casacuberta et al, ; Rutgers van der Loeff et al, ). The deep waters at stations 48, 52, and 57 in the deep Canada Basin (Figure S10) were determined to have residence times of 130–270 years based on the range of 226 Ra fluxes estimated for sediments in both the Makarov and Canada Basins.…”

Section: Discussionsupporting

confidence: 91%

“…Intermediate waters move cyclonically around the Arctic; one pathway follows the Eurasian side of the Lomonosov Ridge and another crosses the Lomonosov to enter the Makarov and Canada Basins (Rudels et al, ; Schauer et al, ; Smethie et al, ). Anthropogenically sourced tracers such as 3 H, SF 6 , 129 I, and 236 U have been used to denote recent ventilation of intermediate water in the Amundsen, Canada, and Makarov Basins and indicate that the residence time of this water mass is on the order of decades (Casacuberta et al, ; Ekwurzel et al, ; Rutgers van der Loeff et al, ; Schlosser et al, ; Smethie et al, ; Smith et al, ; Smethie & Swift, ; Tanhua et al, ).…”

Section: Discussionmentioning

confidence: 99%

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Shelf‐Basin Interactions and Water Mass Residence Times in the Western Arctic Ocean: Insights Provided by Radium Isotopes

et al. 2019

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Radium isotopes are produced through the decay of thorium in sediments and are soluble in seawater; thus, they are useful for tracing ocean boundary‐derived inputs to the ocean. Here we apply radium isotopes to study continental inputs and water residence times in the Arctic Ocean, where land‐ocean interactions are currently changing in response to rising air and sea temperatures. We present the distributions of radium isotopes measured on the 2015 U.S. GEOTRACES transect in the Western Arctic Ocean and combine this data set with historical radium observations in the Chukchi Sea and Canada Basin. The highest activities of radium‐228 were observed in the Transpolar Drift and the Chukchi shelfbreak jet, signaling that these currents are heavily influenced by interactions with shelf sediments. The ventilation of the halocline with respect to inputs from the Chukchi shelf occurs on time scales of ≤19–23 years. Intermediate water ventilation time scales for the Makarov and Canada Basins were determined to be ~20 and >30 years, respectively, while deep water residence times in these basins were on the order of centuries. The radium distributions and residence times described in this study serve as a baseline for future studies investigating the impacts of climate change on the Arctic Ocean.

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Section: Discussionsupporting

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Shelf‐Basin Interactions and Water Mass Residence Times in the Western Arctic Ocean: Insights Provided by Radium Isotopes

et al. 2019

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“…Yet a recent study (Casacuberta et al, ) found that the 129 I and 236 U signals from LH and SF do not completely mix in the North Sea, suggesting three different input functions for Atlantic waters entering the Arctic Ocean (two branches entering via Barents Sea, green and purple in Figure a and one via Fram Strait, orange in Figure a). The high 129 I/ 236 U ratio released from LH largely remains within the NCC, which enters the Barents Sea very close to the Norwegian coast.…”

Section: Discussionmentioning

confidence: 91%

“…Apart from the temporal variation of 129 I/ 236 U from RP, the combination of 129 I and 236 U allows distinguishing between the two main anthropogenic sources (i.e., RP and GF), as they are characterized by very different 129 I and 236 U concentrations as well as 129 I/ 236 U atom ratios (Casacuberta et al, , ). To this purpose, the dual‐tracer approach of using the 236 U/ 238 U ratio together with the 129 I/ 236 U ratio has been suggested and used to constrain sources of water masses (Christl, Casacuberta, Vockenhuber, et al, ; Casacuberta et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…129 I and 236 U concentrations obtained for the outflowing waters in the Fram Strait indicate a large influence of NCC waters in the surface. Finally, we make use of the split input functions for 129 I defined recently (Casacuberta et al, ) to calculate transit times of waters transported from the Barents Sea through the Arctic Ocean to the Fram Strait by the different Atlantic branches.…”

Section: Introductionmentioning

confidence: 99%

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Tracing Atlantic Waters Using ¹²⁹I and ²³⁶U in the Fram Strait in 2016

et al. 2019

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In this study 129I and 236U concentrations in seawater samples collected onboard R/V Polarstern during the PS100 expedition in the Fram Strait in 2016 are presented. The overall aim of the study was to investigate the distribution of these long‐lived radionuclides along the transect located at 79°N. The combination of both radionuclides was used for the first time in the Fram Strait to trace ocean circulation pathways of Atlantic waters. Results show that both 129I and 236U concentrations as well as 236U/238U ratios are about two times higher (> 600 × 107 at kg(−1), > 20 × 106 at kg(−1), and 2.8 × 10−9, respectively) in the cold and fresh outflowing surface waters from the Arctic Ocean (Polar Surface Water, PSW) compared to inflowing Atlantic origin waters (300 × 107 at kg(−1) 129I, 12 × 106 at kg(−1) 236U, and 1.4 × 10−9 236U/238U). A comparison with the different 129I and 236U input functions for the Atlantic branches entering the Arctic Ocean reveals that the middepth Atlantic origin waters outflowing the Arctic Ocean show more influence of the Barents Sea Branch Water than the Fram Strait Branch Water. The high radionuclide concentrations observed in the PSW indicate substantial influence of the Norwegian Coastal Current. This current carries a significantly larger proportion of 129I and 236U releases from European reprocessing plants than the aforementioned Atlantic branches. We estimate surface water transit times from the northern Norwegian Coast through the Arctic to the PSW of 12–19 years, less than for the middepth Barents Sea Branch Water (16–23 years).

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Radionuclides as Ocean Tracers

Rodellas

Roca‐Martí

Puigcorbé

et al. 2022

Marine Analytical Chemistry

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Tracing the Three Atlantic Branches Entering the Arctic Ocean With ¹²⁹I and ²³⁶U

Cited by 44 publications

References 43 publications

Shelf‐Basin Interactions and Water Mass Residence Times in the Western Arctic Ocean: Insights Provided by Radium Isotopes

Shelf‐Basin Interactions and Water Mass Residence Times in the Western Arctic Ocean: Insights Provided by Radium Isotopes

Tracing Atlantic Waters Using ¹²⁹I and ²³⁶U in the Fram Strait in 2016

Radionuclides as Ocean Tracers

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Tracing the Three Atlantic Branches Entering the Arctic Ocean With 129I and 236U

Cited by 44 publications

References 43 publications

Shelf‐Basin Interactions and Water Mass Residence Times in the Western Arctic Ocean: Insights Provided by Radium Isotopes

Shelf‐Basin Interactions and Water Mass Residence Times in the Western Arctic Ocean: Insights Provided by Radium Isotopes

Tracing Atlantic Waters Using 129I and 236U in the Fram Strait in 2016

Radionuclides as Ocean Tracers

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Tracing the Three Atlantic Branches Entering the Arctic Ocean With ¹²⁹I and ²³⁶U

Tracing Atlantic Waters Using ¹²⁹I and ²³⁶U in the Fram Strait in 2016