Abstract
The heat budget has been computed locally over the entire globe for each month of 1988 using compatible top-of-the-atmosphere radiation from the Earth Radiation Budget Experiment combined with European Centre for Medium Range Weather Forecasts atmospheric data. The effective heat sources and sinks (diabatic heating) and effective moisture sources and sinks for the atmosphere are computed and combined to produce overall estimates of the atmospheric energy divergence and the net flux through the Earth's surface. On an annual mean basis, this is directly related to the divergence of the ocean heat transport, and new computations of the ocean heat transport are made for the ocean basins. Results are presented for January and July, and the annual mean for 1988, along with a comprehensive discussion of errors. While the current results are believed to be the best available at present, there are substantial shortcomings remaining in the estimates of the atmospheric heat and moisture budgets. The issues, which are also present in all previous studies, arise from the diurnal cycle, problems with atmospheric divergence, vertical resolution, spurious mass imbalances, initialized versus uninitialized atmospheric analyses, and postprocessing to produce the atmospheric archive on pressure surfaces. Over land, additional problems arise from the complex surface topography, so that computed surface fluxes are more reliable over the oceans. The use of zonal means to compute ocean transports is shown to produce misleading results because a considerable part of the implied ocean transports is through the land. The need to compute the heat budget locally is demonstrated and results indicate lower ocean transports than in previous residual calculations which are therefore more compatible with direct ocean estimates. A Poisson equation is solved with appropriate boundary conditions of zero normal heat flux through the continental boundaries to obtain the ocean heat transport. Because of the poor observational data base, adjustments to the surface fluxes are necessary over the southern oceans. Error bars are estimated based on the large-scale spurious residuals over land of 30 W m−2 over 1000 km scales (1012 m2). In the Atlantic Ocean, a northward transport emerges at all latitudes with peak values of 1.1±0.2 PW (1 standard error) at 20 to 30°N. Comparable values are achieved in the Pacific at 20°N, so that the total is 2.1±0.3 PW. The peak southward transport is at 15 to 20°S of 1.9±0.3 PW made up of strong components from both the Pacific and Indian Oceans and with a heat flux from the Pacific into the Indian Ocean in the Indonesian throughflow. The pattern of poleward heat fluxes is suggestive of a strong role for Ekman transports in the tropical regions.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Aagaard K, Greisman P (1975) Toward new mass and heat budgets for the Arctic Ocean. J Geophys Res 80:3821–3827
Ardanuy PE, Kyle HL, Hoyt DV (1992) Global relationships among the Earth's radiation budget, cloudiness, volcanic aerosols and surface temperature. J Clim 5:1120–1139
Barkstrom B, Harrison E, Smith G, Green R, Kibler J, Cess R, ERBE Science Team (1989) Earth Radiation Budget Experiment (ERBE) archival and April 1985 results. Bull Am Meteorol Soc 70:1254–1262
Boer GJ (1982) Diagnostic equations in isobaric coordinates. Mon Weather Rev 110:1801–1820
Boer GJ (1986) A comparison of mass and energy budgets from two FGGE datasets and a GCM. Mon Weather Rev 114:885–902
Boer GJ, Sargent NE (1985) Vertically integrated budgets of mass and energy of the globe. J Atmos Sci 42:1592–1613
Bönning CW, Herrmann P (1994) On the annual cycle of poleward heat transport in the ocean: results from high resolution modeling of the North and Equatorial Atlantic. J Phys Oceanogr 24:91–107
Bryden HL (1993) Ocean heat transport across 24°N latitude. In: Interactions between global climate subsystems, the legacy of Hann. Geophys Monogr 75 IUGG 15, IUGG, AGU, pp 65–75
Bryden HL, Roemmich DH, Church JA (1991) Ocean heat transport across 24°N in the Pacific. Deep-Sea Res 38:297–324
Carissimo BC, Oort AH, Vonder Haar TH (1985) Estimating the meridional energy transports in the atmosphere and ocean. J Phys Oceanogr 15:82–91
Dobson FW, Smith SD (1988) Bulk models of solar radiation at sea. Q J R Meteorol Soc 114:165–182
Errico RM (1991) Theory and application of nonlinear normal mode initialization. NCAR Tech Note NCAR/TN-344 + IA
Errico RM, Rasch PJ (1988) A comparison of various normal-mode initialization schemes and the inclusion of diabatic processes. Tellus 40A:1–25
Fortelius C, Holopainen EO (1990) Comparison of energy source estimates derived from atmospheric circulation data with satellite measurements of net radiation. J Clim 3:646–660
Hartmann DL, Ramanathan V, Berroir A, Hunt GE (1986) Earth radiation budget data and climate research. Rev Geophys Space Phys 24:439–468
Hastenrath S (1980) Heat budget of tropical ocean and atmosphere. J Phys Oceanogr 10:159–170
Hastenrath S (1982) On meridional heat transport in the world ocean. J Phys Oceanogr 12:922–927
Hellerman S, Rosenstein M (1983) Normal monthly wind stress over the world ocean with error estimates. J Phys Oceanogr 17:1093–1104
Hirst AC, Godfrey JS (1993) The role of Indonesian throughflow in a global ocean GCM. J Phys Oceanogr 23:1057–1085
Hsiung J (1985) Estimates of global oceanic meridional heat transport. J Phys Oceanogr 15:1405–1423
Hurrell JW, Campbell CG (1992) Monthly mean global satellite data sets available in CCM History Tape format. NCAR Tech Note NCAR/TN-371 + STR
Isemer H-J, Hasse L (1987) The Bunker climate atlas of the North Atlantic Ocean. Vol 2 air-sea interactions. Springer, Berlin Heidelberg New York, 252 pp
Keith D (1994) Meridional energy transport: uncertainty in zonal means. Tellus (in press)
MacDonald AM (1993) Property fluxes at 30°S and their implications for the Pacific-Indian throughflow and the global heat budget. J Geophys Res 98:6851–6868
Masuda K (1988) Meridional heat transport by the atmosphere and the ocean; analysis of FGGE data. Tellus 40A:285–302
Michaud R, Derome J (1991) On the mean meridional transport of energy in the atmosphere and oceans as derived from six years of ECMWF analyses. Tellus 43A:1–14
Oberhuber JM (1988) An atlas based on the CORDS data set: the budgets of heat, buoyancy and turbulent kinetic energy at the surface of the global ocean. Max Planck Institute for Meteorology Rep 15, Max Planck Institute for Meteorology, Hamburg, Germany
Oort AH, Vonder Haar TH (1976) On the observed annual cycle in the ocean-atmosphere heat balance over the Northern Hemisphere. J Phys Oceanogr 6:781–800
Ponater M, Frenzen G (1987) On the numerical evaluation of the energy conversion integral. Tellus 39A:515–520
Rieland M, Raschke E (1991) Diurnal variability of the earth radiation budget: sampling requirements, time integration aspects and error estimates for the Earth Radiation Budget Experiment (ERBE). Theor Appl Climatol 44:9–24
Sardeshmukh PD (1993) The baroclinic ξ problem and its application to the diagnosis of atmospheric heating rates. J Atmos Sci 50:1099–1112
Sardeshmukh PD, Liebmann B (1993) An assessment of low-frequency variability in the tropics as indicated by some proxies of tropical convection. J Clim 6:569–575
Saunders PM, Thompson SR (1993) Transport, heat and freshwater fluxes within a diagnostic numerical model (FRAM). J Phys Oceanogr 23:452–464
Savijärvi HI (1988) Global energy and moisture budgets from rawinsonde data. Mon Weather Rev 116:417–430
Semtner AJ Jr, Chervin RM (1988) A simulation of the global ocean circulation with resolved eddies. J Geophys Res 93:15502–15522
Semtner AJ Jr, Chervin RM (1992) Ocean general circulation from a global eddy-resolving model. J Geophys Res 97:5493–5550
Stephens GL, Campbell CG, Vonder Haar TH (1981) Earth radiation budgets. J Geophys Res 86:9739–9760
Stone PH, Risbey JS (1990) On the limitations of general circulation climate models. Geophys Res Lett 17:2173–2176
Trenberth KE (1979) Mean annual poleward energy transports by the oceans in the Southern Hemisphere. Dyn Atmos Ocean 4:57–64
Trenberth KE (1987) The role of eddies in maintaining the westerlies in the southern hemisphere winter. J Atmos Sci 44:1498–1508
Trenberth KE (1991) Climate diagnostics from global analyses: conservation of mass in ECMWF analyses. J Clim 4:707–722
Trenberth KE (1992) Global analyses from ECMWF and atlas of 1000 to 10 mb circulation statistics. NCAR Tech Note NCAR/TN-373 + STR
Trenberth KE, Olson JG (1988) An evaluation and intercomparison of global analyses from NMC and ECMWF. Bull Am Meteorol Soc 69:1047–1057
Trenberth KE, Branstator GW (1992) Issues in establishing causes of the 1988 drought over North America. J Clim 5:159–172
Trenberth KE, Large WG, Olson JG (1990) The mean annual cycle in global ocean wind stress. J Phys Oceanogr 20:1742–1760
Trenberth KE, Berry JC, Buja LE (1993) Vertical interpolation and truncation of model-coordinate data. NCAR Tech Note NCAR/TN-396 + STR
Vonder Haar TH, Oort AH (1973) A new estimate of annual poleward energy transport by the oceans. J Phys Oceanogr 3:169–172
Weare BC (1989) Uncertainties in estimates of surface heat fluxes derived from marine reports over the tropical and subtropical oceans. Tellus 41A:357–370
Weare BC, Strub PT (1981) The significance of sampling biases on calculated monthly mean oceanic surface heat fluxes. Tellus 33:211–224
Yanai M, Esbensen S, Chu J-H (1973) Determination of bulk properties of tropical cloud clusters from large-scale heat and moisture budgets. J Atmos Sci 30:611–627
Yanai M, Chu J-H, Stark TE, Nitta T (1976) Response of deep and shallow tropical maritime cumuli to large-scale processes. J Atmos Sci 33:976–991
Yanai M, Li C, Song Z (1992) Seasonal heating of the Tibetan plateau and its effects on the evolution of the Asian summer monsoon. J Meteorol Soc Japan 70:319–351
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Trenberth, K.E., Solomon, A. The global heat balance: heat transports in the atmosphere and ocean. Climate Dynamics 10, 107–134 (1994). https://doi.org/10.1007/BF00210625
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00210625