Physical and ecological processes at a moving ice edge in the Fram Strait as observed with an AUV

Wulff, Thorben; Bauerfeind, Eduard; Appen, Wilken-Jon von

doi:10.1016/j.dsr.2016.07.001

Cited by 23 publications

(26 citation statements)

References 40 publications

(51 reference statements)

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“…Patch formation (Prairie et al, ) is still an unsolved but important problem in marine biology. Fronts are known to relate to patches of phytoplankton (Wulff et al, ), zooplankton (Trudnowska et al, ), and marine birds and mammals (Joiris & Falck, ) in Fram Strait. The CTD casts suggest that the submesoscale filament may have a similar structuring ability on biomass and nutrient distributions as well as biological communities.…”

Section: Discussionmentioning

confidence: 99%

Observations of a Submesoscale Cyclonic Filament in the Marginal Ice Zone

Appen

Wekerle

Hehemann

et al. 2018

Geophysical Research Letters

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104

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Submesoscale flows are energetic motions on scales of several kilometers that may lead to substantial vertical motions. Here we present satellite and ship radar as well as underway conductivity-temperature-depth and Acoustic Doppler Current Profiler observations of a cyclonic submesoscale filament in the marginal ice zone of Fram Strait. The filament created a 500-m thin and 50-km long sea ice streak and extends to >250-m depth with a negative/positive density anomaly within/below the halocline. The frontal jets of 0.5 m/s are in turbulent thermal wind balance while the ageostrophic secondary circulation in places appears to subduct Atlantic Water at >50 m/day. Our study reveals the submesoscale dynamics related to sea ice shapes that can be sensed remotely and shows how submesoscale dynamics contribute to shaping the marginal ice zone. It also demonstrates the co-occurrence and mixing of water masses over short horizontal scales, which has implications for ocean and sea ice models and understanding of patch formation of planktonic organisms.Plain Language Summary A sea ice streak in the marginal ice zone was observed with radar measurements. Below this streak in situ shipboard measurements of the temperature, salinity, and velocity field revealed a cyclonic submesoscale filament. This is a line of denser water of a few kilometers width bounded by strong counteracting velocities. This denser water is also associated with a different water mass and thus a change in biological properties and communities. This provides in situ confirmation for previous theoretical conclusions of how oceanic flows on kilometer scales structure the sea ice and biology in the marginal ice zone. The understanding of such small-scale processes helps improve computer models of the ocean and sea ice dynamics. It also makes it possible to interpret oceanic flows from remote sensing of sea ice. Furthermore, it gives indication over which horizontal scales biological processes vary in the ocean.

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Section: Discussionmentioning

confidence: 99%

Observations of a Submesoscale Cyclonic Filament in the Marginal Ice Zone

Appen

Wekerle

Hehemann

et al. 2018

Geophysical Research Letters

Self Cite

104

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“…In the future, increasing data collection spatial resolution through deployments on other autonomous platforms such as surface wave gliders, autonomous underwater vehicles, and autonomous profiling floats will serve to further expand potential research capabilities. Both ISUS (Johnson and Needoba, 2008;Ryan et al, 2010;Harvey et al, 2012;Zhang et al, 2015;Fischer et al, 2017) and SUNA (Wulff, 2016;Karstensen et al, 2017) nitrate sensors have been successfully deployed on autonomous underwater vehicles. In the future, incorporation of UV optical nitrate sensors along with pH and pCO 2 sensors on surface wave gliders (Chavez et al, 2017b) will provide quantitative data on the coupling of the carbon and nutrient cycles.…”

Section: Future Visionmentioning

confidence: 99%

Hourly In Situ Nitrate on a Coastal Mooring: A 15-Year Record and Insights into New Production

Sakamoto¹,

Mbari²,

Johnson³

et al. 2017

Oceanog

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“…The miniaturization of biogeochemical sensors allow their implementation on autonomous underwater vehicles (AUVs, e.g., ice-tethered profilers, gliders and Argo floats). Successful deployments of AUVs in the pan-Arctic area provide new physical and biogeochemical insights, even in the presence of sea ice (e.g., Laney et al, 2014;Wulff et al, 2016). Nowadays, BGC-Argo floats are largely used to evaluate the NCP in different ocean basins (e.g., Bushinsky & Emerson, 2015;Hennon et al, 2016;Plant et al, 2016;Riser et al, 2018;Yang et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Assessing Phytoplankton Activities in the Seasonal Ice Zone of the Greenland Sea Over an Annual Cycle

et al. 2018

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In seasonal ice zones (SIZs), such as the one of the Greenland Sea, the sea ice growth in winter and subsequent melting in summer influence the phytoplankton activity. However, studies assessing phytoplankton activities over complete annual cycles and at a fine temporal resolution are lacking in this environment. Biogeochemical‐Argo floats, which are able to sample under the ice, were used to collect physical and biogeochemical data along vertical profiles and at 5‐day resolution during two complete annual cycles in the Greenland Sea SIZ. Three phytoplankton activity phases were distinct within an annual cycle: one under ice, a second at the ice edge, and a third one around an open‐water subsurface chlorophyll maximum. As expected, the light and nitrate availabilities controlled the phytoplankton activity and the establishment of these phases. On average, most of the annual net community production occurred equally under ice and at the ice edge. The open‐water subsurface chlorophyll maximum phase contribution, on the other hand, was much smaller. Phytoplankton biomass accumulation and production thus occur over a longer period than might be assumed if under ice blooms were neglected. This also means that satellite‐based estimates of phytoplankton biomass and production in this SIZ are likely underestimated. Simulations with the Arctic‐based physical‐biologically coupled SINMOD model suggest that most of the annual net community production in this SIZ results from local processes rather than due to advection of nitrate from the East Greenland and Jan Mayen Currents.

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Physical and ecological processes at a moving ice edge in the Fram Strait as observed with an AUV

Cited by 23 publications

References 40 publications

Observations of a Submesoscale Cyclonic Filament in the Marginal Ice Zone

Observations of a Submesoscale Cyclonic Filament in the Marginal Ice Zone

Hourly In Situ Nitrate on a Coastal Mooring: A 15-Year Record and Insights into New Production

Assessing Phytoplankton Activities in the Seasonal Ice Zone of the Greenland Sea Over an Annual Cycle

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