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Arctic radiation deficit and climate variability

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Abstract

One of the generally accepted climatic effects of stratospheric aerosol injection is the reduction of the global radiation in high latitudes by an order of 5% during El Chichon type eruptions. To test the effect of a high-latitude radiation deficit on global climate, a GCM experiment was performed with the ECMWF T21 atmosphere general circulation model (AGCM). The results provide physically-consistent evidence that this radiation deficit is a possible external forcing factor for severe climatic anomalies not only in the area directly affected by the reduced radiation, but also in the tropics. The most important factor is the creation of enhanced snow cover in regions of Asia that are distant from the location of the introduced radiation anomaly. The simulated results show certain features that are well known from observations in weak monsoon years, i.e. the weakened easterly jet in the upper troposphere over northern India, prolonged winter monsoon conditions, and prevailing anticyclonic vorticity anomalies over the entire Indian summer monsoon region. Over the western Pacific at the end of boreal winter (May), increased convective activity leads to a negative Walker circulation anomaly with westerly wind anomalies near the surface and easterly anomalies in the upper troposphere. This is known as one of the most important anomalies at the beginning of an El Niño/Southern Oscillation (ENSO) event.

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  1. Hans-F Graf

    Present address: Max-Planck-Institut für Meteorologie, Bundesstrasse 55, W-2000, Hamburg 13, Germany

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  1. Meteorologisches Institut, Humboldt Universität zu Berlin, Müggelseedamm 256, 1162, O-Berlin, Germany

    Hans-F Graf

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Graf, HF. Arctic radiation deficit and climate variability. Climate Dynamics 7, 19–28 (1992). https://doi.org/10.1007/BF00204818

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