Wallace S. Broecker Superimposed on the episodes of climate decline are prominent 20,000-year cycles (see Figure 5). The existence of these cycles tips us off as to what drives glaciations for their timing beautifully matches that of changes in the distribution among the seasonals of the heat received from the Sun. These cycles which involve increases and decreases in the contrast be- tween winter and summer insolation, are the result of the precession of the Earth’s spin axis in combination with its elliptical orbit. In addition to the pacing by the 20,000-year precession cycles, evidence for an or- bital influence on climate comes from the timing of the terminations which brought to an abrupt end each of the 100,000-year climate cycles. Each of these ter- minations occurred at a time of maximal contrast be- tween summer and winter. The match between or- bital changes and earth climate is so convincing that it is now universally accepted that glacial cycles were paced by changes in seasonal contrast. The impor- tant point for this paper is that when these seasonal- ity changes are introduced into the same models used to predict the impact of rising greenhouse gases, the models barely respond. This tells us that there must be interactions taking place in the real world (but not in the models) which greatly amplify the impact of nudges associated with changes in the distribution of solar heat among the seasons. Example 2. Paleoclimatologists were puzzled to note that while the changes in air temperature and in atmospheric CO2 content recorded in ice from long borings in the Antarctic ice cap (see Figure 5) nicely conform to expectation based on cycles in the Earth’s orbit, the record from Greenland ice is quite different. It was, as shown in Figure 6, dominated by abrupt jumps spaced at millennial intervals. During the last glacial cycle, about twenty of these back and forth jumps occurred (Stuiver and Grootes, 2000). They appear not only in the temperature record, but also in those of the dust content (Mayewski et al., 1994) of the ice and of the methane content (Brook et al., 1996) of air trapped in bubbles in the ice. Because Green- land’s ice has prominent annual layers, it is possible to show that each of these transitions occurred with great rapidity – i.e., they were completed in a few decades. The mean annual temperature change associated with these jumps has been rigorously documented to be on the order of 10◦C (Severinghaus et al., 2001). This discovery triggered a search for equivalents in records from elsewhere on the planet. In rapid succession evidence turned up at widely spaced north temperate and tropical locales. But at Southern Hemi- sphere locales, if present, they were muted and shifted in time. While from the beginning it was postu- lated that these shifts were triggered by reorganiza- tions of the large scale conveyor-like circulation in the Atlantic Ocean (see Figure 7), nearly twenty years passed before an explanation for their abruptness and widespread geographic distribution was found. The key turned out to be a huge amplification resulting from large changes in the extent of sea ice cover in the northern Atlantic (Chiang et al., 2003). These changes occurred in response to a turning on and off of the Atlantic’s conveyor-like circulation. In its on mode, the conveyor’s northward flowing upper limb flooded the Norwegian Sea with water warmed dur- ing its passage through the tropics. This warmth pre- vented ice from forming. But, when the conveyor shut down, this delivery of tropical heat no longer oc- curred, allowing winter sea ice to cover the northern Atlantic as far south as Great Britain. This ice would not only have blocked the transfer of ocean heat to the atmosphere, but also it would have reflected away much of the incoming sunlight. As a result, winters in Europe would have rivaled those which now plague Siberia. But it was the search for the connection to the tropics which posed the greatest challenge. Climate records from caves in China and from sediments from the Arabian Sea clearly indicate that the monsoons were greatly weakened during periods when sea ice covered the northernAtlantic. Further, the record con- tained in sediments from the Cariaco Basin just off the Caribbean coast of South America and that in sta- lagmites from a cave in southeastern Brazil revealed that during times when sea ice covered the northern Atlantic, the belt tropical rainfall was shifted south- ward. Models endowed with northern Atlantic sea ice were able to account for both the weakening of the monsoons and for the southward shift of the tropical rain belt (Chiang et al., 2003). The latter reflected the 8 JÖKULL No. 55, 2005

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