Raj, Roshin P (2016): Mean dynamic topography of the North Indian Ocean [dataset]. PANGAEA, https://doi.org/10.1594/PANGAEA.861422, Supplement to: Raj, RP (2016): Surface velocity estimates of the North Indian Ocean from satellite gravity and altimeter missions. International Journal of Remote Sensing, 38(1), 296-313, https://doi.org/10.1080/01431161.2016.1266106
Always quote citation above when using data! You can download the citation in several formats below.
Abstract:
The circulation in the North Indian Ocean (NIO) is one of the most complex systems compared with other regions of global oceans, mostly due to its interactions with the monsoon winds. In recent years, our ability to measure the ocean's mean dynamic topography (MDT) from space has improved immensely with the availability of satellite gravity measurements from Gravity Recovery and Climate Experiment (GRACE) and Gravity Field and Steady-State Ocean Circulation Explorer (GOCE) missions. The present study uses data from GOCE and GRACE satellite gravity missions together with altimeter data in retrieving the geoid, satellite-only MDT, and surface velocities in the NIO. The study estimates geoid heights of the NIO from all five releases of the direct approach and the time-wise GOCE gravity data. The formal error associated with geoid heights at different resolutions is found to be the lowest for the latest release of direct approach GOCE data. In addition, a new satellite-only MDT is estimated from the direct approach GOCE geoid and the CNES_CLS11 mean sea surface. This MDT corrected to a 20-year time reference is used together with the newly reprocessed sea level anomaly data to estimate absolute dynamic topography and surface geostrophic velocities in the NIO. The total surface velocities computed from the Ekman and geostrophic velocity fields reproduce all major surface currents in the NIO, along with their seasonality. Furthermore, total surface velocity estimates computed here are validated using surface drifters and are found to be highly comparable (difference within ± 10 cm s–1) with more than 170,000 individual surface drifter observations. Finally, the total velocities estimated here are used to examine the variability of the East India Coastal Current.
Related to:
Johannessen, Johnny Andre; Balmino, Georges; Le Provost, Christian; Rummel, R; Sabadini, R; Sünkel, H; Tscherning, C C; Visser, P; Woodworth, Philip L; Hughes, Chris W; Legrande, P; Sneeuw, N; Perosanz, F; Aguirre-Martinez, M; Rebhan, H; Drinkwater, Mark R (2003): The European Gravity Field and Steady-State Ocean Circulation Explorer Satellite Mission: Its Impact on Geophysics. Surveys in Geophysics, 24(4), 339-386, https://doi.org/10.1023/B:GEOP.0000004264.04667.5e
Raj, Roshin P (2014): The circulation of the Norwegian Sea- An investigation from space and ocean. PhD Thesis, University of Bergen, 50 pp, hdl:1956/7877
Schaeffer, P; Faugére, Y; Legeais, Jean-François; Ollivier, A; Guinle, T; Picot, N (2012): The CNES_CLS11 Global Mean Sea Surface Computed from 16 Years of Satellite Altimeter Data. Marine Geodesy, 35(1), 3-19, https://doi.org/10.1080/01490419.2012.718231
Coverage:
Latitude: 15.000000 * Longitude: 81.000000
Comment:
North Indian Ocean: 40E to 120E and 0N to 30 N.
A satellite-only Mean Dynamic Topography (MDT) of the North Indian Ocean is estimated from the DIRR5 geoid and CNES_CLS11 mean sea surface (Schaffer et al. 2012). DIRR5 geoid is estimated from the latest release (Release 5) of GOCE gravity data according to previous studies (e.g., Johannessen et al. 2003; Raj, 2014). Note that this MDT estimated is referenced to a time period of 7 years (1993-1999). A correction data obtained from AVISO is later used to convert the MDT to a time reference of 20 years (1993-2012).
More details are given in Raj (2016).
License:
Creative Commons Attribution 3.0 Unported (CC-BY-3.0)
Size:
7.9 MBytes