Tides, Internal and Near‐Inertial Waves in the Yermak Pass at the Entrance of the Atlantic Water to the Arctic Ocean

In the crucial region of the Yermak Plateau where warm Atlantic water enters the Arctic ocean, we examined high frequency variations in the Yermak Pass Branch over a 34 months‐long mooring data set. The mooring was ice covered only half of the time with ice‐free periods both in summer and winter. We...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2022-12, Vol.127 (12), p.n/a
Main Authors: Artana, Camila, Provost, Christine, Ferrari, Ramiro, Bricaud, Clément, Poli, Léa, Park, Young‐Hyang
Format: Article
Language:English
Subjects:
Anticyclonic circulation
Arctic Ocean
Barotropic mode
Barotropic tides
Current rings
Diurnal
Diurnal tides
Eddies
Frequency variation
Geophysics
High frequencies
High frequency
Ice
Ice cover
Inertial waves
Inflow
Internal waves
Low frequencies
Low frequency
Mooring
mooring data
Mooring systems
Ocean, Atmosphere
Oceans
Penetration
Plateaus
Residual circulation
residual tidal currents
Sciences of the Universe
Shears
Standing waves
Tidal circulation
Tidal currents
Tides
Variation
Velocity
Wave propagation
Yermak Plateau
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Summary:In the crucial region of the Yermak Plateau where warm Atlantic water enters the Arctic ocean, we examined high frequency variations in the Yermak Pass Branch over a 34 months‐long mooring data set. The mooring was ice covered only half of the time with ice‐free periods both in summer and winter. We investigated the contribution of residual tidal currents to the low frequency flow of Atlantic Water (AW) and high frequency variations in velocity shears possibly associated with internal waves. High resolution model simulations including tides show that diurnal tide forced an anticyclonic circulation around the Yermak Plateau. This residual circulation helps the northward penetration of the AW into the Arctic. Tides should be taken into account when examining low frequency AW inflow. High frequency variations in velocity shears are mainly concentrated in a broad band around 12 hr in the Yermak Pass. Anticyclonic eddies, observed during ice‐free conditions, modulate the shear signal. Semi‐diurnal internal stationary waves dominate high frequency variations in velocity shears. The stationary waves could result from the interaction of freely propagating semi‐diurnal internal waves generated by diurnal barotropic tides on critical slopes around the plateau. The breaking of the stationary waves with short length scales possibly contribute to mixing of AW at the entrance to the Arctic. Plain Language Summary The Atlantic Water (AW) is the main source of heat and salt to the Arctic. The Yermak Plateau is a major obstacle to the flow. Tides are strong over the Yermak Plateau. Tides contribute to the mean flow helping the northward penetration of the AW around the Yermak Plateau. Tides play also key role in the generation of stationary waves likely important for mixing. Key Points An anticyclonic residual circulation around the Yermak Plateau forced by the diurnal tide helps Atlantic Water penetrate into the Arctic Semi‐diurnal stationary internal waves are observed in the Yermak Pass and could result from freely propagating semi‐diurnal internal waves Freely propagating semi‐diurnal internal waves are generated by diurnal barotropic tides on critical slopes around the plateau
ISSN:2169-9275
2169-9291
DOI:10.1029/2022JC019082