Editorial Type:
Article
Article Type:
Research Article

Seasonal and Interannual Variability of Atmospheric Heat Sources and Moisture Sinks as Determined from NCEP–NCAR Reanalysis

Michio Yanai Department of Atmospheric Sciences, University of California, Los Angeles, Los Angeles, California

Search for other papers by Michio Yanai in
Current site
Google Scholar
PubMed Close
and
Tomohiko Tomita Department of Atmospheric Sciences, University of California, Los Angeles, Los Angeles, California

Search for other papers by Tomohiko Tomita in
Current site
Google Scholar
PubMed Close
Print Publication:
01 Mar 1998
DOI:
https://doi.org/10.1175/1520-0442(1998)011<0463:SAIVOA>2.0.CO;2
Page(s):
463–482
Restricted access

Abstract

Using the National Centers for Environmental Predictions (NCEP)–National Center for Atmospheric Research (NCAR) reanalysis, distributions of the heat source Q1 and moisture sink Q2 between 50°N and 50°S are determined for a 15-yr period from 1980 to 1994. Heating mechanisms operating in various parts of the world are examined by comparing the horizontal distributions of the vertically integrated heat source 〈Q1〉 with those of the vertically integrated moisture sink 〈Q2〉 and outgoing longwave radiation (OLR) flux and by comparing the vertical distributions of Q1 with those of Q2.

In northern winter, the major heat sources are located (i) in a broad zone connecting the tropical Indian Ocean, Indonesia, and the South Pacific convergence zone (SPCZ); (ii) over the Congo and Amazon Basins; and (iii) off the east coasts of Asia and North America. In northern summer, the major heat sources are over (i) the Bay of Bengal coast, (ii) the western tropical Pacific, and (iii) Central America. Throughout the year, the South Indian Ocean, eastern parts of the North and South Pacific Oceans, and eastern parts of the North and South Atlantic Oceans remain to be heat sinks. The desert regions such as the Sahara are characterized by large sensible heating near the surface and intense radiative cooling aloft. Over the tropical oceans, heat released by condensation with deep cumulus convection provides the major heat source. The radiative cooling and moistening due to evaporation are dominant features over the subtropical oceans where subsidence prevails. Over the Tibetan Plateau, the profiles of Q1 and Q2 show the importance of sensible heating in spring and contributions from the release of latent heat of condensation in summer. Off the east coast of Japan, intense sensible and latent heat fluxes heat and moisten the lower troposphere during winter.

Heat sources in various regions exhibit strong interannual variability. A long (4–5 yr) periodicity corresponding to the variations in OLR and sea surface temperature (SST) is dominant in the equatorial eastern and central Pacific Ocean, while a shorter-period oscillation is superimposed upon the long-period variation over the equatorial Indian Ocean. The interannual variations of 〈Q1〉, OLR, and SST are strongly coupled in the eastern and central equatorial Pacific. However, the coupling between the interannual variations of 〈Q1〉 and OLR with those of SST is weak in the equatorial western Pacific and Indian Ocean, suggesting that factors other than the local SST are also at work in controlling the variations of atmospheric convection in these regions.

* Current affiliation: International Pacific Research Center, University of Hawaii at Manoa, Honolulu, Hawaii.

Corresponding author address: Dr. Michio Yanai, Department of Atmospheric Sciences, University of California, Los Angeles, 405 Hilgard Avenue, Los Angeles, CA, 90095-1565.

Abstract

Using the National Centers for Environmental Predictions (NCEP)–National Center for Atmospheric Research (NCAR) reanalysis, distributions of the heat source Q1 and moisture sink Q2 between 50°N and 50°S are determined for a 15-yr period from 1980 to 1994. Heating mechanisms operating in various parts of the world are examined by comparing the horizontal distributions of the vertically integrated heat source 〈Q1〉 with those of the vertically integrated moisture sink 〈Q2〉 and outgoing longwave radiation (OLR) flux and by comparing the vertical distributions of Q1 with those of Q2.

In northern winter, the major heat sources are located (i) in a broad zone connecting the tropical Indian Ocean, Indonesia, and the South Pacific convergence zone (SPCZ); (ii) over the Congo and Amazon Basins; and (iii) off the east coasts of Asia and North America. In northern summer, the major heat sources are over (i) the Bay of Bengal coast, (ii) the western tropical Pacific, and (iii) Central America. Throughout the year, the South Indian Ocean, eastern parts of the North and South Pacific Oceans, and eastern parts of the North and South Atlantic Oceans remain to be heat sinks. The desert regions such as the Sahara are characterized by large sensible heating near the surface and intense radiative cooling aloft. Over the tropical oceans, heat released by condensation with deep cumulus convection provides the major heat source. The radiative cooling and moistening due to evaporation are dominant features over the subtropical oceans where subsidence prevails. Over the Tibetan Plateau, the profiles of Q1 and Q2 show the importance of sensible heating in spring and contributions from the release of latent heat of condensation in summer. Off the east coast of Japan, intense sensible and latent heat fluxes heat and moisten the lower troposphere during winter.

Heat sources in various regions exhibit strong interannual variability. A long (4–5 yr) periodicity corresponding to the variations in OLR and sea surface temperature (SST) is dominant in the equatorial eastern and central Pacific Ocean, while a shorter-period oscillation is superimposed upon the long-period variation over the equatorial Indian Ocean. The interannual variations of 〈Q1〉, OLR, and SST are strongly coupled in the eastern and central equatorial Pacific. However, the coupling between the interannual variations of 〈Q1〉 and OLR with those of SST is weak in the equatorial western Pacific and Indian Ocean, suggesting that factors other than the local SST are also at work in controlling the variations of atmospheric convection in these regions.

* Current affiliation: International Pacific Research Center, University of Hawaii at Manoa, Honolulu, Hawaii.

Corresponding author address: Dr. Michio Yanai, Department of Atmospheric Sciences, University of California, Los Angeles, 405 Hilgard Avenue, Los Angeles, CA, 90095-1565.

Save
Cover Journal of Climate
Journal of Climate

  • Ackerman, S. A., and S. K. Cox, 1987: Radiative energy budget estimates for the 1979 southwest summer monsoon. J. Atmos. Sci.,44, 3052–3078.

  • Barnett, T. P., L. Dümenil, U. Schlese, E. Roeckner, and M. Latif, 1989: The effect of Eurasian snow cover on regional and global climate variations. J. Atmos. Sci.,46, 661–685.

  • Christy, J. R., 1991: Diabatic heating rate estimates from European Centre for Medium-Range Weather Forecasts analyses. J. Geophys. Res.,96, 5123–5135.

  • Dopplick, T. G., 1979: Radiative heating of the global atmosphere: Corrigendum. J. Atmos. Sci.,36, 1812–1817.

  • Douglas, M. W., R. A. Maddox, and K. Howard, 1993: The Mexican monsoon. J. Climate,6, 1665–1677.

  • Douville, D., and J.-F. Royer, 1996: Sensitivity of the Asian summer monsoon to an anomalous Eurasian snow cover within the Meteo-France GCM. Climate Dyn.,12, 449–466.

  • Hahn, D. G., and J. Shukla, 1976: An apparent relationship between Eurasian snow cover and Indian monsoon rainfall. J. Atmos. Sci.,33, 2461–2462.

  • He, H., J. W. McGinnis, Z. Song, and M. Yanai, 1987: Onset of the Asian monsoon in 1979 and the effect of the Tibetan Plateau. Mon. Wea. Rev.,115, 1966–1995.

  • Hoskins, B. J., H. H. Hsu, I. N. James, M. Masutani, P. D. Sardeshmukh, and G. H. White, 1989: Diagnostics of the global atmospheric circulation based on ECMWF analyses 1979–1989. World Climate Research Programme-27, WMO/TD-326, 217 pp.

  • Iwasaki, T., 1991: Year-to-year variation of snow cover area in the Northern Hemisphere. J. Meteor. Soc. Japan,69, 209–217.

  • Jiang, N., J. D. Neelin, and M. Ghil, 1995: Quasi-quadrennial and quasi-biennial variability in equatorial Pacific. Climate Dyn.,12, 101–112.

  • Johnson, D. R., M. Yanai, and T. K. Schaack, 1987: Global and regional distributions of atmospheric heat sources and sinks during the GWE. Monsoon Meteorology, C. P. Chang and T. N. Krishnamurti, Eds., Oxford University Press, 271–297.

  • Joseph, P. V., J. K. Eischeid, and R. J. Pyle, 1994: Interannual variability of the onset of the Indian summer monsoon and its association with atmospheric features, El Niño, and sea surface temperature anomalies. J. Climate,7, 81–105.

  • Kalnay, E., and Coauthors, 1996: The NCEP/NCAR 40-year reanalysis project. Bull. Amer. Meteor. Soc.,77, 437–471.

  • Krishnamurti, T. N., H. S. Bedi, and M. Subramaniam, 1989: The summer monsoon of 1987. J. Climate,2, 321–340.

  • ——, ——, and ——, 1990: The summer monsoon of 1988. Meteor. Atmos. Phys.,42, 19–37.

  • Lau, K. M., and P. J. Sheu, 1988: Annual cycle, quasi-biennial oscillation, and Southern Oscillation. J. Geophys. Res.,93, 10975–10988.

  • ——, H.-T. Wu, and S. Bony, 1997: The role of large-scale atmospheric circulation in the relationship between tropical convection and sea surface temperature. J. Climate,10, 381–392.

  • Li, C., and M. Yanai, 1996: The onset and interannual variability ofthe Asian summer monsoon in relation to land–sea thermal contrast. J. Climate,9, 358–375.

  • Luo, H., and M. Yanai, 1984: The large-scale circulation and heat sources over the Tibetan Plateau and surrounding areas during the early summer of 1979. Part II: Heat and moisture budgets. Mon. Wea. Rev.,112, 966–989.

  • Meehl, G. A., 1987: The annual cycle and interannual variability in the tropical Pacific and Indian Ocean regions. Mon. Wea. Rev.,115, 27–50.

  • Mohanty, U. C., S. K. Dube, and M. P. Singh, 1983: A study of heat and moisture budgets over the Arabian Sea and their role in the onset and maintenance of summer monsoons. J. Meteor. Soc. Japan,61, 208–221.

  • Nitta, T., 1977: Response of cumulus updraft and downdraft to GATE A/B-scale motion systems. J. Atmos. Sci.,34, 1163–1186.

  • ——, 1983: Observational study of heat sources over the eastern Tibetan Plateau during the summer monsoon. J. Meteor. Soc. Japan,61, 590–605.

  • Ose, T., 1996: The comparison of the simulated response to the regional snow mass anomalies over Tibet, Eastern Europe, and Siberia. J. Meteor. Soc. Japan,74, 845–866.

  • Philander, S. G., 1990: El Niño, La Niña, and the Southern Oscillation. Academic Press, 293 pp.

  • Ramanathan, V., and W. Collins, 1991: Thermodynamic regulation of ocean warming by cirrus clouds deduced from observations of the 1987 El Niño. Nature,351, 27–32.

  • Rao, G. V., W. R. Schaub Jr., and J. Puetz, 1981: Evaporation and precipitation over the Arabian Sea during several monsoon seasons. Mon. Wea. Rev.,109, 364–370.

  • Rasmusson, E. M., and T. H. Carpenter, 1982: Variations in tropical sea surface temperature and surface wind fields associated with the Southern Oscillation/El Niño. Mon. Wea. Rev.,110, 354–384.

  • ——, and ——, 1983: The relationship between the eastern equatorial Pacific sea surface temperatures and rainfall over India and Sri Lanka. Mon. Wea. Rev.,111, 517–528.

  • ——, X. Wang, and C. F. Ropelewski, 1990: The biennial component of ENSO variability. J. Mar. Syst.,1, 71–96.

  • Ropelewski, C. F., and M. S. Halpert, 1987: Global- and regional-scale precipitation patterns associated with the El Niño/Southern Oscillation. Mon. Wea. Rev.,115, 1606–1626.

  • ——, and ——, 1989: Precipitation patterns associated with the high index phase of the Southern Oscillation. J. Climate,2, 268–284.

  • Sankar-Rao, M., K. M. Lau, and S. Yang, 1996: On the relationship between Eurasian snow cover and the Asian summer monsoon. Int. J. Climatol.,16, 605–616.

  • Schaack, T. K., and D. R. Johnson, 1994: January and July global distributions of atmospheric heating for 1986, 1987, and 1988. J. Climate,7, 1270–1285.

  • ——, ——, and M.-Y. Wei, 1990: The three-dimensional distribution of atmospheric heating during the GWE. Tellus,42A, 305–327.

  • Shukla, J., 1987: Interannual variability of monsoons. Monsoons, J. S. Fein and P. L. Stephens, Eds., John Wiley and Sons, 399–463.

  • Thompson, R. M., Jr., S. W. Payne, E. E. Recker, and R. J. Reed, 1979: Structure and properties of synoptic-scale wave disturbances in the intertropical convergence zone of the eastern Atlantic. J. Atmos. Sci.,36, 53–72.

  • Tomita, T., and T. Yasunari, 1996: Role of the northeast winter monsoon on the biennial oscillation of the ENSO/monsoon system. J. Meteor. Soc. Japan,74, 399–413.

  • Trenberth, K. E., 1975: A quasi-biennial standing wave in the Southern Hemisphere and interrelations with sea surface temperature. Quart. J. Roy. Meteor. Soc.,101, 55–74.

  • ——, 1984: Signal versus noise in the Southern Oscillation. Mon. Wea. Rev.,112, 326–332.

  • ——, 1992: Global analyses from ECMWF and atlas of 1000 to 10 mb circulation statistics. NCAR Tech. Note NCAR/TN-373+STR, 191 pp.

  • ——, and D. J. Shea, 1987: On the evolution of the Southern Oscillation. Mon. Wea. Rev.,115, 3078–3096.

  • ——, and J. G. Olson, 1988: ECMWF global analyses 1976–86: Circulation statistics and data evaluation. NCAR Tech. Note NCAR/TN-300+STR, 94 pp. plus 12 fiche.

  • ——, and A. Solomon, 1994: The global heat balance: Heat transports in the atmosphere and ocean. Climate Dyn.,10, 107–134.

  • ——, and C. J. Guillemot, 1996: Evaluation of the atmospheric moisture and hydrological cycle in the NCEP reanalyse. NCAR Tech. Note TN-430+STR, 308 pp.

  • Vernekar, A. D., J. Zhou, and J. Shukla, 1995: The effect of Eurasian snow cover on the Indian monsoon. J. Climate,8, 248–266.

  • Waliser, D. E., and N. E. Graham, 1993: Convective cloud systems and warm-pool sea surface temperatures: Coupled interactions and self-regulation. J. Geophys. Res.,98, 12881–12893.

  • ——, ——, and C. Gautier, 1993: Comparison of the highly reflective cloud and outgoing longwave radiation datasets for use in estimating tropical deep convection. J. Climate,6, 331–353.

  • Webster, P. J., 1994: The role of hydrological processes in ocean–atmosphere interactions. Rev. Geophys.,32, 427–476.

  • ——, and S. Yang, 1992: Monsoon and ENSO: Selectively interactive systems. Quart. J. Roy. Meteor. Soc.,118, 877–926.

  • Wei, M.-Y., D. R. Johnson, and R. D. Townsend, 1983: Seasonal distributions of diabatic heating during the First GARP Global Experiment. Tellus,35A, 241–255.

  • Yanai, M., and R. H. Johnson, 1993: Impacts of cumulus convection on thermodynamic fields. Representation of Cumulus Convection in Numerical Models of the Atmosphere, Meteor. Monogr., No. 46, Amer. Meteor. Soc., 39–62.

  • ——, and C. Li, 1994a: Mechanism of heating and the boundary layer over the Tibetan Plateau. Mon. Wea. Rev.,122, 305–323.

  • ——, and ——, 1994b: Interannual variability of the Asian summer monsoon and its relationship with ENSO, Eurasian snow cover, and heating. Proc. Int. Conf. on Monsoon Variability and Prediction, Trieste, Italy, World Meteorological Organization, 27–34.

  • ——, and ——, 1996: Seasonal and interannual variability of atmospheric heating. Preprints, Eighth Conf. on AirSea Interaction and Symposium on GOALS, Atlanta, GA, Amer. Meteor. Soc., 102–106.

  • ——, S. Esbensen, and J.-H. Chu, 1973: Determination of bulk properties of tropical cloud clusters from large-scale heat and moisture budgets. J. Atmos. Sci.,30, 611–627.

  • ——, C. Li, and Z. Song, 1992: Seasonal heating of the Tibetan Plateau and its effects on the evolution of the Asian summer monsoon. J. Meteor. Soc. Japan,70, 319–351.

  • Yang, S., 1996: ENSO–snow–monsoon associations and seasonal–interannual predictions. Int. J. Climatol.,16, 125–134.

  • Yasunari, T., 1990: Impact of Indian monsoon on the coupled atmosphere/ocean system in the tropical Pacific. Meteor. Atmos. Phys.,44, 29–41.

  • ——, 1991: The monsoon year—A new concept of the climatic year in the Tropics. Bull. Amer. Meteor. Soc.,72, 1331–1338.

  • ——, A. Kitoh, and T. Tokioka, 1991: Local and remote responses to excessive snow mass over Eurasia appearing in the northern spring and summer climate—A study with the MRI-GCM. J. Meteor. Soc. Japan,69, 473–487.

All Time Past Year Past 30 Days
Abstract Views 0 0 0
Full Text Views 2232 896 89
PDF Downloads 1522 374 39