Abstract
Abstract. Measured upwelling radiances from Nimbus-7 SBUV (Solar Backscatter Ultraviolet) and seven NOAA SBUV/2 instruments have been used to calculate the 340 nm Lambertian equivalent reflectivity (LER) of the Earth from 1979 to 2011 after applying a common calibration. The 340 nm LER is highly correlated with cloud and aerosol cover because of the low surface reflectivity of the land and oceans (typically 2 to 6 RU, reflectivity units, where 1 RU = 0.01 = 1.0%) relative to the much higher reflectivity of clouds plus nonabsorbing aerosols (typically 10 to 90 RU). Because of the nearly constant seasonal and long-term 340 nm surface reflectivity in areas without snow and ice, the 340 nm LER can be used to estimate changes in cloud plus aerosol amount associated with seasonal and interannual variability and decadal climate change. The annual motion of the Intertropical Convergence Zone (ITCZ), episodic El Niño Southern Oscillation (ENSO), and latitude-dependent seasonal cycles are apparent in the LER time series. LER trend estimates from 5° zonal average and from 2° × 5° , latitude × longitude, time series show that there has been a global net decrease in 340 nm cloud plus aerosol reflectivity. The decrease in cos2(latitude) weighted average LER from 60° S to 60° N is 0.79 ± 0.03 RU over 33 yr, corresponding to a 3.6 ± 0.2% decrease in LER. Applying a 3.6% cloud reflectivity perturbation to the shortwave energy balance partitioning given by Trenberth et al. (2009) corresponds to an increase of 2.7 W m−2 of solar energy reaching the Earth's surface and an increase of 1.4% or 2.3 W m−2 absorbed by the surface, which is partially offset by increased longwave cooling to space. Most of the decreases in LER occur over land, with the largest decreases occurring over the US (−0.97 RU decade−1), Brazil (−0.9 RU decade−1), and central Europe (−1.35 RU decade−1). There are reflectivity increases near the west coast of Peru and Chile (0.8 ± 0.1 RU decade−1), over parts of India, China, and Indochina, and almost no change over Australia. The largest Pacific Ocean change is −2 ± 0.1 RU decade−1 over the central equatorial region associated with ENSO. There has been little observed change in LER over central Greenland, but there has been a significant decrease over a portion of the west coast of Greenland. Similar significant decreases in LER are observed over a portion of the coast of Antarctica for longitudes −160° to −60° and 80° to 150°.
Highlights
Ocean ScienceThe Earth’s energy balance is mostly determined by the shortwave solar energy received at the Earth’s surface, absorbed by the atmosphere and reflected back to space, and the fraction of longwave energy emitted to space
This study shows that a consistent common calibration and identical retrieval algorithm applied to seven Solar Backscatter Ultraviolet (SBUV) instruments over 33 yr are sufficient to detect long-term changes in cloud plus aerosol reflectivity that can be differentiated from seasonal or instrumental differences
This is partly demonstrated by the comparison of the 340 nm Lambertian equivalent reflectivity (LER) with the mulitvariate El Nino Southern Oscillation (ENSO) index (MEI), which showed high correlation for the larger ENSO events, especially in 1982–1983 and 1991–1992
Summary
The Earth’s energy balance is mostly determined by the shortwave solar energy received at the Earth’s surface, absorbed by the atmosphere and reflected back to space, and the fraction of longwave energy emitted to space. Two other long-term cloud data sets exist, AVHRR (visible and infrared channels) and HIRS (multiple broadband channels from 3 to 15 microns), which have surface reflectivity sensitivity in addition to diurnal cloud variation from drifting orbits similar to the SBUV/2 (Solar Backscatter Ultraviolet 2) instruments. Five of the instruments (NOAA-16, -17, -18, -19 SBUV/2, and OMI) continued to take daily observations into 2012, of which the first 3 are used to estimate long-term change in LER For those SBUV/2 instruments that had drifting orbits (slowly changing Equator-crossing times), large-scale diurnal changes in LER were minimized (Labow et al, 2011) by correcting to noon values. Since the SBUV and SBUV/2 are the only series of instruments having very similar observing characteristics, span the entire data record 1979 to present, and have a new common calibration, the LER time series (80◦ S–80◦ N), and noon corrected time series (60◦ S–60◦ N), are constructed entirely from their recalibrated measured radiances
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