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1

Book

Physical oceanography of the Indian ocean : from WOCE to CLIVAR (2003)

Schott, Friedrich A.

Oxford [u.a.] : Pergamon

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Type of Medium: Book

Pages: IV, S. 1889 - 2347 , graph. Darst., Kt

Series Statement: Deep sea research 50.2003,12/13

Language: English

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2

Book

Physical oceanography of the Indian Ocean during WOCE (2002)

Schott, Friedrich A.

Oxford [u.a.] : Pergamon

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Keywords: Aufsatzsammlung

Type of Medium: Book

Pages: IV S., S. 1171-1596 , graph. Darst., Kt

Series Statement: Deep sea research 49,7/8

Language: English

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3

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Variability of the Great Whirl from Observations and Models (2002)

Wirth, A. ; Willebrand, Jürgen ; Schott, Friedrich

Pergamon Press

In: Deep Sea Research Part II: Topical Studies in Oceanography, 49 (7). pp. 1279-1295.

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Publication Date: 2020-08-05

Description: Observations from cruises in the Arabian Sea and data from satellites are interpreted using different realizations of a multi-level primitive equation model and an eddy-permitting reduced-gravity shallow water model of the Indian Ocean. The focus is on the interannual circulation variability of the Arabian Sea, and especially of the meridional location of the Great Whirl (GW). The results suggest that the variability in the western Arabian Sea is not only due to the interannual variability in the wind field, but that a substantial part is caused by the chaotic nature of the ocean dynamics. Decreasing the friction coefficient from 1000 to 500m2s-1 in a 19o numerical reduced-gravity model, the variance of the GW location increases dramatically, and the mean position moves southward by one degree. In the eddy-permitting experiments analyzed, both mechanisms appear to determine the GW location at the onset of the GW dynamics in late summer.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/S0967-0645(01)00165-5

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4

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Winter and summer monsoon water mass, heat and freshwater transport changes in the Arabian Sea near 8°N (2002)

Stramma, Lothar ; Brandt, Peter ; Schott, Friedrich ; [et al.]

Pergamon Press

In: Deep Sea Research Part II: Topical Studies in Oceanography, 49 . pp. 1173-1195.

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Publication Date: 2020-08-05

Description: The differences in the water mass distributions and transports in the Arabian Sea between the summer monsoon of August 1993 and the winter monsoon of January 1998 are investigated, based on two hydrographic sections along approximately 8°N. At the western end the sections were closed by a northward leg towards the African continent at about 55°E. In the central basin along 8°N the monsoon anomalies of the temperature and density below the surface-mixed layer were dominated by annual Rossby waves propagating westward across the Arabian Sea. In the northwestern part of the basin the annual Rossby waves have much smaller impact, and the density anomalies observed there were mostly associated with the Socotra Gyre. Salinity and oxygen differences along the section reflect local processes such as the spreading of water masses originating in the Bay of Bengal, northward transport of Indian Central Water, or slightly stronger southward spreading of Red Sea Water in August than in January. The anomalous wind conditions of 1997/98 influenced only the upper 50–100 m with warmer surface waters in January 1998, and Bay of Bengal Water covered the surface layer of the section in the eastern Arabian Sea. Estimates of the overturning circulation of the Arabian Sea were carried out despite the fact that many uncertainties are involved. For both cruises a vertical overturning cell of about 4–6 Sv was determined, with inflow below 2500 m and outflow between about 300 and 2500 m. In the upper 300–450 m a seasonally reversing shallow meridional overturning cell appears to exist in which the Ekman transport is balanced by a geostrophic transport. The heat flux across 8°N is dominated by the Ekman transport, yielding about –0.6 PW for August 1993, and 0.24 PW for January 1998. These values are comparable to climatological and model derived heat flux estimates. Freshwater fluxes across 8°N also were computed, yielding northward freshwater fluxes of 0.07 Sv in January 1998 and 0.43 Sv in August 1993. From climatological salinities the stronger freshwater flux in August was found to be caused by the seasonal change of salinity storage in the Arabian Sea north of 8°N. The near-surface circulation follows complex pathways, with generally cyclonic-circulation in January 1998 affected at the eastern side by the Laccadive High, and anticyclonic circulation in August 1993.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/S0967-0645(01)00169-2

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The mean flow field of the tropical Atlantic Ocean (1999)

Stramma, Lothar ; Schott, Friedrich

Pergamon Press

In: Deep Sea Research Part II: Topical Studies in Oceanography, 46 (1-2). pp. 279-304.

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Publication Date: 2020-08-05

Description: The mean horizontal ßow Þeld of the tropical Atlantic Ocean is described between 20¡N and 20¡S from observations and literature results for three layers of the upper ocean, Tropical Surface Water, Central Water, and Antarctic Intermediate Water. Compared to the subtropical gyres the tropical circulation shows several zonal current and countercurrent bands of smaller meridional and vertical extent. The wind-driven Ekman layer in the upper tens of meters of the ocean masks at some places the ßow structure of the Tropical Surface Water layer as is the case for the Angola Gyre in the eastern tropical South Atlantic. Although there are regions with a strong seasonal cycle of the Tropical Surface Water circulation, such as the North Equatorial Countercurrent, large regions of the tropics do not show a signiÞcant seasonal cycle. In the Central Water layer below, the eastward North and South Equatorial undercurrents appear imbedded in the westward-ßowing South Equatorial Current. The Antarcic Intermediate Water layer contains several zonal current bands south of 3¡N, but only weak ßow exists north of 3¡N. The sparse available data suggest that the Equatorial Intermediate Current as well as the Southern and Northern Intermediate Countercurrents extend zonally across the entire equatorial basin. Due to the convergence of northern and southern water masses, the western tropical Atlantic north of the equator is an important site for the mixture of water masses, but more work is needed to better understand the role of the various zonal under- and countercurrents in cross-equatorial water mass transfer. ( 1999 Elsevier Science Ltd. All rights reserved

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/S0967-0645(98)00109-X

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Annual Rossby waves in the Arabian Sea from TOPEX/POSEIDON altimeter and in-situ data (2002)

Brandt, Peter ; Stramma, Lothar ; Schott, Friedrich ; [et al.]

Pergamon Press

In: Deep Sea Research Part II: Topical Studies in Oceanography, 49 (7). pp. 1197-1210.

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Publication Date: 2020-08-05

Description: Sea-surface height data acquired by the TOPEX/POSEIDON satellite over the Arabian Sea from October 1992 to October 1998 are analyzed. Strong seasonal fluctuations are found between 61 and 101N, which are mainly associated with westward propagating annual Rossby waves radiated from the western side of the Indian subcontinent and that are continuously forced by the action of the wind-stress curl over the central Arabian Sea. An analysis of hydrographic data acquired during August 1993 and during January 1998 at 81N in the Arabian Sea reveals the existence of first- and second-mode annual Rossby waves. These waves, which can be traced as perturbations in the density fields, have wavelengths of 12�103 and 4.4�103km as well as phase velocities of 0.38 and 0.14 m/s, respectively. The waves are associated with a time-dependent meridional overturning cell that sloshes water northward and southward. Between 581 and 681E in the central Arabian Sea, we found a Rossby-wave induced transport in the upper 500m of about 10 Sv southward in August 1993 and northward in January 1998. Below 2000 m, there was still a northward transport of 3.2 Sv in August 1993 and a southward transport of 4.8 Sv in January 1998. A comparison of steric height differences between August 1993 and January 1998 calculated from the observed density fields as well as calculated from the reconstructed density fields using first- and second-mode annual Rossby waves agree quite well with the corresponding sea-surface height differences. Implications resulting from the reflection of annual Rossby waves, like fluctuations of the western boundary currents, are discussed.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/S0967-0645(01)00166-7

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Abyssal Circulation in the Somali Basin (2002)

Dengler, Marcus ; Quadfasel, Detlef ; Schott, Friedrich ; [et al.]

Pergamon Press

In: Deep Sea Research Part II: Topical Studies in Oceanography, 49 (7-8). pp. 1297-1322.

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Publication Date: 2020-08-05

Description: The bottom and deep circulation in the Somali Basin are investigated on the basis of hydrographic and direct velocity profiles from three shipboard surveys carried out during the southwest monsoon in 1995 and of velocity time series from the WOCE mooring array ICM7. The inflow of bottom water into the Somali Basin through the Amirante Passage drives a thermohaline circulation, which may be modulated by the monsoon wind forcing. Details of the abyssal circulation have been discussed controversially. Deep velocity records from the mooring array in the northern Somali Basin are dominated by fluctuations with periods of 30–50 days and amplitudes above Full-size image (〈1 K). Despite this strong variability annual record averages indicate the existence of a deep western boundary current (DWBC) below Full-size image (〈1 K) at the base of the continental slope south of Socotra Island as part of a cyclonic bottom circulation. The southwestward DWBC transport off Socotra Island is estimated to Full-size image (〈1 K). The bottom and deep water exchange between the Somali and Arabian Basin north of 7°N is estimated from two cross-basin geostrophic velocity sections referenced by vertically averaged LADCP currents. For the bottom water, an eastward transport into the Arabian Basin of Full-size image (〈1 K) and Full-size image (〈1 K) was determined in June and August, respectively, while for the deep-water layer above Full-size image (〈1 K) eastward transports of Full-size image (〈1 K) in June and Full-size image (〈1 K) in August were obtained.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/S0967-0645(01)00167-9

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