Background stratification impacts on internal tide  generation and abyssal propagation in the western  equatorial Atlantic and the Bay of Biscay

Barbot, Simon; Lyard, Florent; Tchilibou, Michel; Carrère, Loren

doi:10.5194/os-17-1563-2021

Cited by 10 publications

(29 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Larger conversion rate might be due to the stratification modulation from MAMJJ (shallower and slightly stronger stratification) compared to ASOND. This is in good agreement with idealized simulations of Barbot et al (2021), that show that shallower stratification enhanced the conversion rate in this area.…”

supporting

confidence: 90%

“…For all sites except F, P 2 ratio is stronger in MAMJJ than ASOND, meaning that MAMJJ is more favorable to local dissipation. In the 8 boxes, the generation of mode 2 and 3 is larger in MAMJJ compared to ASOND (see CVR for mode 2 and 3 columns of Table 3), as expected for a season with shallower pycnocline Barbot et al (2021). Once higher modes are generated, instabilities are more probable, and thus local dissipation is higher.…”

Section: M2 Coherent Internal Tide For Mamjj and Asond: Energy Budgetmentioning

confidence: 53%

“…In ASOND, the pycnocline deepens by more than 50 m and reaches 170 to 190 m in the area delimited by the NBC and its retroflection (Figure 5d). The internal tides generated in ASOND are expected to have less higher modes and a larger wavelength of the mode 1 (Barbot et al, 2021) . Also, the steep pycnocline slope established along the NBCR / NECC (front) in ASOND, might act as a kind of barrier to the free propagation of the internal tide.…”

Section: Mamjj and Asond Stratificationsmentioning

confidence: 99%

“…The distance (90 km) smaller than a mode 1 baroclinic wavelength (120 km) suggest that the dissipation would occurs in the model in the water column between 100 and 500m. It is also possible that the 90 km distance is a consequence of a change in stratification and particularly in the depth of the pycnocline as discussed by Barbot et al (2021).…”

mentioning

confidence: 99%

“…The seasonality of the stratification induces a seasonality of the internal tides. Seasons with a shallow pycnocline coincide with the generation of high vertical modes, while a deeper pycnocline leads mostly to mode 1 internal tide generation (Tchilibou et al, 2020;Barbot et al, 2021). Idealized and, less often, realistic studies have looked at internal tides and current interactions.…”

mentioning

confidence: 99%

See 4 more Smart Citations

Internal tides off the Amazon shelf during two contrasted seasons: Interactions with background circulation and SSH imprints

Tchilibou

Koch-Larrouy

Barbot

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

Abstract. The Amazon shelf break is a key region for internal tides (IT) generation. The region also shows a large seasonal variation of circulation and associated stratification. The objective of this study is to document how these variations will impact IT generation and propagation properties. A high-resolution regional model (1/36° horizontal resolution), explicitly resolving IT is analyzed to investigate their interactions with the background circulation and stratification, over two seasons: first MAMJJ (March to July), with weaker mesoscale currents, shallower and stronger pycnocline, and second ASOND (August to December) with stronger mesoscale currents, deeper and weaker pycnocline. IT are generated on the shelf break between the 100 and 1800 m isobaths, with a maximum on average at about 10 km offshore. South of 2° N, the conversion from barotropic to baroclinic tide is more efficient in MAMJJ than in ASOND. At the eight main IT generations sites, the local dissipation is higher in MAMJJ (30 %) than in ASOND (22 %). The remaining fraction propagates away from the generation sites and mainly dissipates locally every 90–120 km. The remote dissipation increases slightly during ASOND and the coherent M2 fluxes seem blocked between 4°–6° N west of 47° W. Further analysis of 25 hours mean snapshots of the baroclinic flux shows deviation and branching of the IT when interacting with strong mesoscale and stratification. We evaluated sea surface height (SSH) frequency and wavenumber spectra for subtidal (f < 1/28h−1), tidal (1/28h−1 < f < 1/11h−1) and super tidal (f > 1/11h−1) frequencies. Tidal frequencies explain most of the SSH variability for wavelengths between 300 km and 70 km. Below 70 km, the SSH is mainly incoherent and supertidal. The length scale at which the SSH becomes dominated by unbalanced IT was estimated to be around 250 km. Our results highlight the complexity of correctly predicting IT SSH in order to better observe mesoscale and submesoscale from existing and upcoming altmetrics missions, notably the Surface Water Ocean Topography (SWOT) mission.

show abstract

supporting

confidence: 90%

Section: M2 Coherent Internal Tide For Mamjj and Asond: Energy Budgetmentioning

confidence: 53%

Section: Mamjj and Asond Stratificationsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Internal tides off the Amazon shelf during two contrasted seasons: Interactions with background circulation and SSH imprints

Tchilibou

Koch-Larrouy

Barbot

et al. 2022

Preprint

Self Cite

View full text Add to dashboard Cite

show abstract

A likely role for stratification in long-term changes of the global ocean tides

Opel,

Schindelegger,

Ray

2024

Commun Earth Environ

View full text Add to dashboard Cite

Stratification—that is, the vertical change in seawater density—exerts a subtle control on the energetics and thus the surface elevation of barotropic (depth independent) flows in the ocean. Changes in stratification therefore provide a plausible pathway to explain some of the puzzling trends in ocean tides evident in tide gauge and, more recently, satellite altimetry data. Using a three-dimensional global ocean model, we estimate that strengthening of stratification between 1993 and 2020 caused open-ocean trends of order 0.1 mm yr−1 in the barotropic M2 tide, similar in structure and magnitude to long-term M2 changes deduced from satellite altimetry. Amplitude trends are predominantly negative, implying enhanced energy transfer to internal tides since the 1990s. Effects of stratification are also a relevant forcing of contemporary M2 trends at the coast, where they may modulate or even overprint the tidal response to sea level rise. Salient examples for such significant near-shore influence of stratification (≥ 95% confidence) include the Northwest Australian Shelf ( − 0.5 mm yr−1) and the coasts of western North America ( − 0.1 mm yr−1), commensurate with observed M2 amplitude trends at tide gauges.

show abstract

Characterization of internal solitary waves in the Andaman Sea and Arabian Sea using EOS-04 and sentinel observations

Mandal,

Seemanth,

Ratheesh

2024

International Journal of Remote Sensing

View full text Add to dashboard Cite

Background stratification impacts on internal tide generation and abyssal propagation in the western equatorial Atlantic and the Bay of Biscay

Cited by 10 publications

References 33 publications

Internal tides off the Amazon shelf during two contrasted seasons: Interactions with background circulation and SSH imprints

Internal tides off the Amazon shelf during two contrasted seasons: Interactions with background circulation and SSH imprints

A likely role for stratification in long-term changes of the global ocean tides

Characterization of internal solitary waves in the Andaman Sea and Arabian Sea using EOS-04 and sentinel observations

Contact Info

Product

Resources

About