Surface Connectivity and Interocean Exchanges From Drifter-Based Transition Matrices

Global surface transport in the ocean can be represented by using the observed trajectories of drifters to calculate probability distribution functions. The oceanographic applications of the Markov Chain approach to modeling include tracking of floating debris and water masses, globally and on yearl...

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Bibliographic Details
Main Authors: McAdam, Ronan, van Sebille, Erik
Other Authors: Sub Physical Oceanography, Dep Natuurkunde, Marine and Atmospheric Research
Format: Article in Journal/Newspaper
Language:English
Published: 2018
Subjects:
Interocean exchange
Surface transport
Transition matrix
Transport barriers
Geophysics
Oceanography
Forestry
Aquatic Science
Ecology
Condensed Matter Physics
Water Science and Technology
Soil Science
Geochemistry and Petrology
Earth-Surface Processes
Physical and Theoretical Chemistry
Polymers and Plastics
Atmospheric Science
Earth and Planetary Sciences (miscellaneous)
Space and Planetary Science
Materials Chemistry
Palaeontology
North Atlantic
Online Access:https://dspace.library.uu.nl/handle/1874/362629
Description
Summary:Global surface transport in the ocean can be represented by using the observed trajectories of drifters to calculate probability distribution functions. The oceanographic applications of the Markov Chain approach to modeling include tracking of floating debris and water masses, globally and on yearly-to-centennial time scales. Here we analyze the error inherent with mapping trajectories onto a grid and the consequences for ocean transport modeling and detection of accumulation structures. A sensitivity analysis of Markov Chain parameters is performed in an idealized Stommel gyre and western boundary current as well as with observed ocean drifters, complementing previous studies on widespread floating debris accumulation. Focusing on two key areas of interocean exchange-the Agulhas system and the North Atlantic intergyre transport barrier-we assess the capacity of the Markov Chain methodology to detect surface connectivity and dynamic transport barriers. Finally, we extend the methodology's functionality to separate the geostrophic and nongeostrophic contributions to interocean exchange in these key regions.

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