Variability of upper ocean thermohaline structure during a MJO event from DYNAMO aircraft observations

This paper reports upper ocean thermohaline structure and variability observed during the life cycle of an intense Madden Julian Oscillation (MJO) event occurred in the southern tropical Indian Ocean (14°S–Eq, 70°E–81°E). Water column measurements for this study were collected using airborne expenda...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2017-02, Vol.122 (2), p.1122-1140
Main Authors: Alappattu, Denny P., Wang, Qing, Kalogiros, John, Guy, Nick, Jorgensen, David P.
Format: Article
Language:English
Subjects:
Airborne sensing
Aircraft
Aircraft components
Aircraft observations
Barrier layers
Columns (structural)
Distribution
Dynamics
DYNAMO
Equator
Geophysics
Heterogeneity
Indian Ocean
Indonesian Throughflow
Intrusion
Isothermal layers
Life cycle
Life cycle engineering
Life cycles
Madden Julian Oscillation
Marine
Meteorological aircraft
Mixed layer
Mixed layer depth
Modes
Ocean circulation
Ocean currents
Oceanography
Oceans
Patchiness
Perturbation methods
Phases
Probes
Saline water
Sensors
Spatial distribution
Spatial heterogeneity
Statistical analysis
Statistical methods
Thermocline
Thermoclines
Thermohaline structure
Thermohalines
Tropical climate
Upper ocean
Variability
Water column
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Summary:This paper reports upper ocean thermohaline structure and variability observed during the life cycle of an intense Madden Julian Oscillation (MJO) event occurred in the southern tropical Indian Ocean (14°S–Eq, 70°E–81°E). Water column measurements for this study were collected using airborne expendable probes deployed from NOAA's WP‐3D Orion aircraft operated as a part of Dynamics of MJO field experiment conducted during November–December 2011. Purpose of the study is twofold; (1) to provide a statistical analysis of the upper ocean properties observed during different phases of MJO and, (2) to investigate how the upper ocean thermohaline structure evolved in the study region in response to the MJO induced perturbation. During the active phase of MJO, mixed layer depth (MLD) had a characteristic bimodal distribution. Primary and secondary modes were at ∼34 m and ∼65 m, respectively. Spatial heterogeneity of the upper ocean response to the MJO forcing was the plausible reason for bimodal distribution. Thermocline and isothermal layer depth deepened, respectively, by 13 and 19 m from the suppressed through the restoring phase of MJO. Thicker (>30 m) barrier layers were found to occur more frequently in the active phase of MJO, associated with convective rainfalls. Additionally, the water mass analysis indicated that, in the active phase of this MJO event the subsurface was dominated by Indonesian throughflow, nonetheless intrusion of Arabian Sea high saline water was also noted near the equator. Key Points In situ observations are made from the tropical Indian Ocean using airborne expendable probes deployed from P‐3 Orion aircraft Response of mixed layer, isothermal layer, and thermocline is analyzed with respect to the different phases of MJO in the Indian Ocean In the active phase of MJO, the mixed layer depth showed a bimodal distribution
ISSN:2169-9275
2169-9291
DOI:10.1002/2016JC012137