Physical processes contributing to the water mass transformation of the Indonesian Throughflow
Physical processes contributing to the water mass transformation of the Indonesian Throughflow
The properties of the waters that move from the Pacific to the Indian Ocean via passages in the Indonesian archipelago are observed to vary with along-flow-path distance. We study an ocean model of the Indonesian Seas with reference to the observed water property distributions and diagnose the mechanisms and magnitude of the water mass transformations using a thermodynamical methodology. This model includes a key parameterization of mixing due to baroclinic tidal dissipation and simulates realistic water property distributions in all of the seas within the archipelago. A combination of air–sea forcing and mixing is found to significantly change the character of the Indonesian Throughflow (ITF). Around 6 Sv (approximately 1/3 the model net ITF transport) of the flow leaves the Indonesian Seas with reduced density. Mixing transforms both the intermediate depth waters (transforming 4.3 Sv to lighter density) and the surface waters (made denser despite the buoyancy input by air–sea exchange, net transformation?=?2 Sv). The intermediate transformation to lighter waters suggests that the Indonesian transformation contributes significantly to the upwelling of cold water in the global conveyor belt. The mixing induced by the wind is not driving the transformation. In contrast, the baroclinic tides have a major role in this transformation. In particular, they are the only source of energy acting on the thermocline and are responsible for creating the homostad thermocline water, a characteristic of the Indonesian outflow water. Furthermore, they cool the sea surface temperature by between 0.6 and 1.5°C, and thus allow the ocean to absorb more heat from the atmosphere. The additional heat imprints its characteristics into the thermocline. The Indonesian Seas cannot only be seen as a region of water mass transformation (in the sense of only transforming water masses in its interior) but also as a region of water mass formation (as it modifies the heat flux and induced more buoyancy flux). This analysis is complemented with a series of companion numerical experiments using different representations of the mixing and advection schemes. All the different schemes diagnose a lack of significant lateral mixing in the transformation.
Indonesian Throughflow, Water mass transformation, Neutral density framework, Thermodynamic, Tidal mixing processes
275-288
Koch-Larrouy, Ariane
c53ebc39-93b2-49c4-9389-241f9d491c8a
Madec, Gurvan
ffb28deb-4bbd-4a4c-914f-492f813e4864
Iudicone, Daniele
e126ed06-8bab-4971-abf1-98a0d5f9dc7f
Atmadipoera, Agus
62a3362f-3177-47c3-9ba8-f8a8c0c41619
Molcard, Robert
f81d0579-da1b-42ed-8d70-21078f63ad10
November 2008
Koch-Larrouy, Ariane
c53ebc39-93b2-49c4-9389-241f9d491c8a
Madec, Gurvan
ffb28deb-4bbd-4a4c-914f-492f813e4864
Iudicone, Daniele
e126ed06-8bab-4971-abf1-98a0d5f9dc7f
Atmadipoera, Agus
62a3362f-3177-47c3-9ba8-f8a8c0c41619
Molcard, Robert
f81d0579-da1b-42ed-8d70-21078f63ad10
Koch-Larrouy, Ariane, Madec, Gurvan, Iudicone, Daniele, Atmadipoera, Agus and Molcard, Robert
(2008)
Physical processes contributing to the water mass transformation of the Indonesian Throughflow.
Ocean Dynamics, 58 (3-4), .
(doi:10.1007/s10236-008-0154-5).
Abstract
The properties of the waters that move from the Pacific to the Indian Ocean via passages in the Indonesian archipelago are observed to vary with along-flow-path distance. We study an ocean model of the Indonesian Seas with reference to the observed water property distributions and diagnose the mechanisms and magnitude of the water mass transformations using a thermodynamical methodology. This model includes a key parameterization of mixing due to baroclinic tidal dissipation and simulates realistic water property distributions in all of the seas within the archipelago. A combination of air–sea forcing and mixing is found to significantly change the character of the Indonesian Throughflow (ITF). Around 6 Sv (approximately 1/3 the model net ITF transport) of the flow leaves the Indonesian Seas with reduced density. Mixing transforms both the intermediate depth waters (transforming 4.3 Sv to lighter density) and the surface waters (made denser despite the buoyancy input by air–sea exchange, net transformation?=?2 Sv). The intermediate transformation to lighter waters suggests that the Indonesian transformation contributes significantly to the upwelling of cold water in the global conveyor belt. The mixing induced by the wind is not driving the transformation. In contrast, the baroclinic tides have a major role in this transformation. In particular, they are the only source of energy acting on the thermocline and are responsible for creating the homostad thermocline water, a characteristic of the Indonesian outflow water. Furthermore, they cool the sea surface temperature by between 0.6 and 1.5°C, and thus allow the ocean to absorb more heat from the atmosphere. The additional heat imprints its characteristics into the thermocline. The Indonesian Seas cannot only be seen as a region of water mass transformation (in the sense of only transforming water masses in its interior) but also as a region of water mass formation (as it modifies the heat flux and induced more buoyancy flux). This analysis is complemented with a series of companion numerical experiments using different representations of the mixing and advection schemes. All the different schemes diagnose a lack of significant lateral mixing in the transformation.
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More information
Published date: November 2008
Keywords:
Indonesian Throughflow, Water mass transformation, Neutral density framework, Thermodynamic, Tidal mixing processes
Identifiers
Local EPrints ID: 65646
URI: http://eprints.soton.ac.uk/id/eprint/65646
ISSN: 1616-7341
PURE UUID: 74b688b2-252e-46f6-8b14-ff26c778fdb7
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Date deposited: 03 Mar 2009
Last modified: 13 Mar 2024 17:47
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Contributors
Author:
Ariane Koch-Larrouy
Author:
Gurvan Madec
Author:
Daniele Iudicone
Author:
Agus Atmadipoera
Author:
Robert Molcard
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