Over a range of 132.5m, 54 temperature sensors (1 mK relative accuracy) were moored yearlong while sampling at 1Hz around 1455m in the open Canary Basin. Coherence between individual records shows a weak but significant peak above the local buoyancy frequency N for all vertical separations z < 100 m, including at sensor interval z = 2.5 m. Instead of a dominant zero-phase difference over the range of sensors, as observed for internal waves at frequencies f < < N, with f denoting the inertial frequency, this superbuoyant coherence shows -phase difference. The transition from zero-phase difference, for internal waves, to -phase difference is abrupt and increases in frequency for decreasing z < 10 m. For z > 10 m, the transition is fixed at Nt 1.6N, which is also the maximum value of the small-scale buoyancy frequency, and limits the internal wave band on its high-frequency side. In the time domain it is observed that this high-frequency coherence mainly occurs when nonlinearities in the temperature gradient, such as steps in the temperature profile, are advected past the sensors. A simple kinematic model of fine-structure contamination is proposed to reproduce this observation. The canonical -2 slope of the temperature spectrum above N is not observed in the in situ data, which rather slope as -8/3. The -8/3 slope can, however, be reproduced in our model, provided the jumps in the temperature profile are not infinitely thin. © 2012. American Geophysical Union. All Rights Reserved.
CITATION STYLE
Gostiaux, L., & Van Haren, H. (2012). Fine-structure contamination by internal waves in the Canary Basin. Journal of Geophysical Research: Oceans, 117(11). https://doi.org/10.1029/2012JC008064
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