Interactions of the northern and southern branches of the thermohaline circulation

Coarse resolution models are used to investigate the influence of Southern Hemisphere processes on the northern branch of the thermohaline circulation. The link between the zonal wind stress at the latitude of Drake Passage and the production of deep water in the Northern Hemisphere is explored. A n...

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Bibliographic Details
Main Author: McDermott, D.A.
Language:unknown
Published: 2014
Subjects:
54 ENVIRONMENTAL SCIENCES
OCEANIC CIRCULATION
ATMOSPHERIC CIRCULATION
CONFIGURATION INTERACTION
WIND
WATER CURRENTS
GENERAL CIRCULATION MODELS
OSCILLATIONS
MIXING
BOX MODELS
ATLANTIC OCEAN
PACIFIC OCEAN
NUMERICAL DATA
Drake Passage
Pacific
Online Access:http://www.osti.gov/servlets/purl/527451
https://www.osti.gov/biblio/527451
https://doi.org/10.2172/527451
Description
Summary:Coarse resolution models are used to investigate the influence of Southern Hemisphere processes on the northern branch of the thermohaline circulation. The link between the zonal wind stress at the latitude of Drake Passage and the production of deep water in the Northern Hemisphere is explored. A nearly linear response to wind stress at the tip of South America is seen in northern deep water production rates in both one- and two-basin configurations. Transient studies are conducted that illustrate the transmission of the wind generated signal from the Southern Hemisphere to the northern sinking region. Mixed-boundary condition experiments are conducted in a number of model configurations. The results of the OGCM mixed boundary condition experiments are investigated using simple box models. Two scenarios are presented to produce oscillations that are similar to deep-decoupling oscillations in the presence of continued AABW production. First, the high northern latitudes are subjected to a melt pulse/retreat pattern of freshening. These perturbations can cause transitions from one stable mode to another, as well as overturning flushes that are followed by a return to the original stable overturning mode. Second, stochastic forcing is applied to the high northern latitude surface fresh water flux. The variations in surface forcing are capable of producing transitions between overturning states that are similar to deep-decoupling oscillations. The stochastic forcing acts to overcome the stabilizing effect of the AABW. In two-basin mixed boundary condition experiments, cooling the climate is seen to result in deep-decoupling type oscillations under stochastic forcing that produced no such variability in a warmer climate.

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