The present contribution reviews previous studies to evaluate the severity of the impact of the Holocene RCCs in the eastern Mediterranean region with emphasis on the RCC of 1500–500 BCE. It also evaluates the constraints on the timing relationship between the end of the Bronze Age and expressions of the RCC of 1500–500 BCE in the eastern Mediterranean region.

The Holocene RCCs are also characterized by peaks in the sea-salt [Na⁺] series from the GISP2 ice core (Fig. 1.1). These sea-salt [Na⁺] variations closely reflect the intensity of the Icelandic Low (Meeker and Mayewski 2002). An intensified (deeper) Icelandic Low causes intensification of onshore winds to Greenland, so that sea ice stays longer each season, and more persists from season to season. The inferred increase of North Atlantic sea-ice extent and duration during the Holocene RCCs is supported by concomitant increases in Holocene, most likely sea-ice transported, ice-rafted debris concentrations in North Atlantic sediments during the RCCs (Bond et al. 2001).

A key record for the identification of Holocene RCCs in the eastern Mediterranean region has been developed by investigation of marine microfossil assemblages in sediment core LC21 (Rohling et al. 2002b). LC21 was recovered from the SE Aegean Sea, on the boundary between the north-south extended Aegean Sea and the west-east extended Levantine Sea. This is a highly sensitive location for the recording of expansions and contractions of the cooler Aegean signature relative to the warmer Levantine signature.

Temperature changes in the region of sediment core LC21 have been deduced from changes in the assemblages of marine unicellular zooplankton microfossils (planktonic foraminifera Rohling et al. 2002b). These were grouped in species clusters according to affinities to warmer or cooler conditions, yielding a relative record of warming and cooling. Based on mapping of the same assemblages in core tops from the Aegean Sea, the relative changes were roughly calibrated to quantitative estimates of sea surface temperature change. This suggested that the RCCs were associated with temperature drops of the order of 2–3°C in the SE Aegean region, notably in winter. We corroborate this initial estimate by similar values from statistically more robust calibrations of the faunal changes using an Artificial Neural Network approach (Fig. 1.1: for method, see Hayes et al. 2005). In central Aegean Sea core SL-11 (Casford et al. 2002; Casford et al. 2003), the ANN method suggests a magnitude of cooling of about 2.5°C for the Holocene RCCs (unpublished data). This may suggest that the impact of cooling was stronger in more northern sites, and somewhat weaker further to the south, which would agree with the inferred cause of the cooling events in the Aegean Sea (northerly outbreaks of cold air – see below).

The approximate 2°C magnitude of the Holocene RCCs in the Aegean compares well with the magnitude of contemporaneous cooling events in the western Mediterranean, which were quantified with organic geochemical techniques (Cacho et al. 2001). Oxygen isotope analyses from speleothems in southwest Romania (Poleva Cave) also provide evidence of climatic cooling within this time period. In that record, the oxygen isotope record is used as a relative temperature proxy, and the magnitude of the decrease was not quantified. However, the observed shift of about 1.5‰ in the isotope data implies a significant temperature decrease in the period between 1500 and 500 BCE (Constantin et al. 2007). Another speleothem record, from Spannagel Cave in the central Alps, also shows a marked interval of relatively heavy oxygen isotope ratios (about 1500–800 BCE), which starts with a shift that implies around 3°C winter cooling (Mangini et al. 2007). The temporal structure of the Spannagel Cave record closely resembles that of records of North Atlantic hydrographic/sea-ice variations, as obtained from ice-rafted debris counts in marine sediment cores (Bond et al. 2001) and supported by the GISP2 ice-core [Na⁺] series (Fig. 1.1). The combined information demonstrates a significant correlation between terrestrial and marine palaeoclimate records at this time, with an emphasis on winter-time perturbations.

The cooling events in the Aegean Sea have been ascribed to intensification and frequency increase of wintertime northerly outbreaks of cold polar and continental air over the basin, relative to the present (Rohling et al. 2002b). Such outbreaks still occur today (for a summary and data of such an event in the year 2001, see Casford et al. 2003). These outbreaks are a consequence of the Mediterranean’s latitudinal position and its mountainous northerly margin, which exert an important control on circulation and water-mass transformations in the Mediterranean Sea. Contemporaneous cooling events have been found in the Adriatic Sea and in the western Mediterranean (Rohling et al. 1997; Cacho et al. 1999; Cacho et al. 2000; Cacho et al. 2001; Casford et al. 2001; Rohling et al. 2002a; Frigola et al. 2007). To understand the relationship between the frequency and intensity of wintertime northerly outbreaks over the Mediterranean and the climatic patterns inferred from proxy records from the wider northern hemisphere (particularly the Greenland ice sheet), it is important to first consider the main drivers behind the general climatic conditions over the region.

During summer, climatic conditions over the Levantine Sea (the eastern sector of the eastern Mediterranean) are dominated by displacement of the North African subtropical high-pressure conditions to the north, causing widespread drought. The Aegean Sea then comes under the influence of northerly winds (‘Etesians’), caused by extension of the deep monsoon low-pressure system of northwest India over the Iranian highlands and Anatolia. Although this semi-permanent extension of the monsoon low causes local depression formation around Cyprus and the Middle East, dry summer conditions prevail due to descent in the upper troposphe...