Abstract
By using a new heat budget equation that is closely related to the sea surface temperature (SST) and a dataset from an ocean general circulation model (MOM2) with 10-a integration (1987–1996), the relative importance of various processes determining SST variations in two regions of the Indian Ocean is compared. These regions are defined by the Indian Ocean Dipole Index and will be referred to hereafter as the eastern (0°–10°S, 90°–110°E) and western regions (10°S–10°N, 50°–70°E), respectively. It is shown that in each region there is a falling of SST in boreal summer and a rising in most months of other seasons, but the phases are quite different. In the eastern region, maximum cooling rate occurs in July, whereas in the western region it occurs in June with much larger magnitude. Maximum heating rate occurs in November in the eastern region, but in March in the western one. The western region exhibits another peak of increasing rate of SST in October, indicating a typical half-year period. Net surface heat flux and entrainment show roughly the same phases as the time-varying term, but the former has much larger contribution in most of a year, whereas the latter is important in the boreal summer. Horizontal advection, however, shows completely different seasonal variations as compared with any other terms in the heat budget equation. In the eastern region, it has a maximum in June/November and a minimum in March/September, manifesting a half-year period; in the western region, it reaches the maximum in August and the minimum in November. Further investigation of the horizontal advection indicates that the zonal advection has almost the opposite sign to the meridional advection. In the eastern region, the zonal advection is negative with a peak in August, whereas the meridional one is positive with two peaks in June and October. In the western region, the zonal advection is negative from March to November with two peaks in June and November, whereas the meridional one is positive with one peak in July. Different phases can be clearly seen between the two regions for each component of the horizontal advection. A detailed analysis of the data of 1994, a year identified when the Indian Ocean dipole event happened, indicates that the horizontal advection plays a dominant role in the remarkable cooling of the eastern region, in which zonal and meridional advections have the same sign of anomaly. However, in the western region in 1994 no any specialty was shown as compared with other years, for the SST anomaly is not positive in large part of this region. All these imply that the eastern and western regions may be related in a quite complex way and have many differences in dynamics. Further study is needed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Behera, S. K., P. S. Salvekar, and T. Yamagata, 2000. Simulation of interannual SST variability in the tropical Indian Ocean. J. Clim., 13: 3487–3499.
Carton, J.A., G. Chepurin, and X. Cao, 2000. A simple ocean data assimilation analysis of the global upper ocean 1950-1995, Part II: Results. J. Phys. Oceanogr., 30: 311–326.
Chen, L.T., 1991. Effect on zonal difference of sea surf ace temperature anomalies in the Arabian Sea and the South China Sea on summer rainfall over the Yangtze River. Scientia Atmospheric Sinica, 15(1): 33–42 (in Chinese).
Feng, M., P. Hacker, and R. Lukas, 1998. Upper ocean heat and salt balances in response to a westerly wind burst in the western equatorial Pacific during TOGA COARE. J. Geophys. Res., 103: 10289–10311.
Godfrey, J.S., 1996. The effect of the Indonesian Through-flow on ocean circulation and heat exchange with the atmosphere: A review. J. Geophys. Res., 101, C5: 12217–12237.
Hu, R.J., 2003. Study on the heat budget and the meridional circulation of the tropical Indian Ocean. Ph. D. Dissertation. Ocean University of China, Qingdao (in Chinese).
Hu, R.J., Q.Y., Liu, Q. Wang, J.S. Godfrey, and X. F. Meng, 2005a. The shallow meridional overturning circulation in the northern Indian Ocean and its interannual variability. Adv. Atmos. Sci., 22(2): 220–229.
Hu, R.J., Q. Y. Liu, X. F. Meng, and J. S. Godfrey, 2005b. On the mechanism of the seasonal variability of SST in the tropical Indian Ocean. Adv. Atmos. Sci., 22 (3): 451–462.
Hu, R.J., Q. Y. Liu, and X. F. Meng, 2005c. The seasonal and interannual variabilities in the meridional heat transport and heat budget in the northern Indian Ocean. J. Ocean Univ. Chin., 35(3): 363–369 (in Chinese).
Li, C.Y., and M.Q. Mu, 2001. The dipole in the equatorial Indian Ocean and its impacts on climate. Chin. J. Atmos. Sci., 25(4): 433–443 (in Chinese).
Liu, H.L., X.H. Zhang, and W. Li, 2001. The heat balance in the western equatorial Pacific warm pool during the westerly wind bursts: A case study. Adv. Atmos. Sci., 18(5): 882–896 (in Chinese).
Masumoto, Y., and T. Yamagata, 1996. Seasonal variations of the Indonesian Throughflow in a general circulation model. J. Geophys. Res., 101: 12287–12293.
McPhaden, M. J., 1982. Variability in the central Indian Ocean, II, Oceanic heat and turbulent energy balances. J. Mar. Res., 40: 403–419.
McPhaden, M. J., and S. P. Hayes, 1991. On the variability of winds, sea surface temperature, and surface layer heat content in the western equatorial Pacific. J. Geophys. Res., 96(suppl.): 3331–3342.
Murtugudde, R., and A. J. Busalacchi, 1999. Interannual variability of the dynamics and thermodynamics of the tropical Indian Ocean. J. Clint., 12: 2300–2326.
Nicholls, N, 1985. Sea surface temperature and Australia winter rainfall. J. Clim., 2: 965–973.
Pacanowski, R. C, 1995. MOM2 Documentation User’s Guide and Reference Manual, Version 2.0. GFDL Ocean Technical Report No.3, Princeton, 329 pp.
Qiu, B., 2000. Interannual variability of the Kuroshio Extension system and its impact on the wintertime SST field. J. Phys. Oceanogr., 30: 1486–1502.
Qu, T., G. Meyers, and J.S. Godfrey, 1994. Ocean dynamics in the region between Australia and Indonesian and its influence on the variation of sea surface temperature in a global general circulation model. J. Geophys. Res., 99: 18433–18445.
Rao, R. R., and R. Sivakumar, 1999. On the possible mechanisms of the evolution of a mini-warm pool during the presummer monsoon season and the genesis of onset vortex in the southeastern Arabian Sea. Quart. J. Roy. Meteor. Soc, 125: 787–809.
Rao, R. R., and R. Sivakumar, 2000. Seasonal variability of near-surface thermal structure and heat budget of the mixed layer of the tropical Indian Ocean from a new global ocean temperature climatology. J. Geophys. Res., 105: 995–1015.
Saji, N. H., B. N. Goswami, P. N. Vinayachandran, and T. Yamagata, 1999. A dipole in the tropical Indian Ocean. Nature, 401: 360–363.
Schiller, A., J. S. Godfrey, P. C. Mclntosh, G. Meyers, and S. E. Wijffels, 1998. Seasonal near-surface dynamics and thermodynamics of the Indian Ocean and the Indonesian Throughflow in a global ocean general circulation model. J. Phys. Oceanogr., 28: 2288–2312.
Schott, F. A., and P.M. Jr. McCreary, 2001. The monsoon circulation of the Indian Ocean. Prog. Oceanogr., 51: 1–123.
Shetye, S., 1986. A model study of the Arabian Sea temperature. J. Mar. Res., 44: 521–542.
Shukla, J., and D.A. Mooley, 1987. Empirical prediction of the summer monsoon rainfall over India. Mon. Wea. Rev., 115: 695–703.
Stevenson, J.W., and P. P. Niiler, 1983. Upper ocean heat budget during the Hawaii-to-Tahiti shuttle experiment. J. Phys. Oceanogr., 13: 1894–1907.
Webster, P.J., A.M. Moore, J.P. Loschnigg, and R. R. Leben, 1999. Coupled ocean-atmosphere dynamics in the Indian Ocean during 1997–1998. Nature, 401: 356–359.
Wu, G. X., P. Liu, Y. M. Liu, and J. P. Li, 2000. Impacts of the sea surface temperature anomaly in the Indian Ocean on the subtropical anticyclone over the western Pacific-two-stage thermal adaptation in the atmosphere. Acta Meteorologica Sinica, 58(5): 513–522 (in Chinese).
Wyrtki, K., 1973. An equatorial jet in the Indian Ocean. Science, 181: 262–264.
Xiao, Z.N., and H.M. Yan, 2001. A numerical simulation of the Indian Ocean SSTa influence on the early summer precipitation of the South China during an El Niño year. Chin. J. Atmos. Sci., 25(2): 173–183 (in Chinese).
Xie, S.-P., H. Annamalai, F. Schott, and J.P. Jr. McCreary, 2001. Structure and mechanisms of south Indian Ocean climate variability. J. Clim., 15: 864–878.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Hu, R., Liu, Q. & Li, C. A heat budget study on the mechanism of SST variations in the Indian ocean dipole regions. J Ocean Univ. China 4, 334–342 (2005). https://doi.org/10.1007/s11802-005-0054-y
Issue Date:
DOI: https://doi.org/10.1007/s11802-005-0054-y