Abstract
The arid Central Andes are a key site to study changes in intensity and movement of the three main atmospheric circulation systems over South America: the South American Summer Monsoon (SASM), the Westerlies and the El Niño Southern Oscillation (ENSO). In this semi-arid to arid region glaciers are particularly sensitive to precipitation changes and thus the timing of past glaciation is strongly linked to changes in moisture supply. Surface exposure ages from study sites between 41° and 22°S suggest that glaciers advanced: i) prior to the global Last Glacial Maximum (gLGM) at ~40 ka in the mid (26°- 30°S) and southern Central Andes (35°-41°S), ii) in phase with the gLGM in the northern and southern Central Andes and iii) during the late glacial in the northern Central Andes. Deglaciation started synchronous with the global rise in atmospheric CO2 concentration and increasing temperature starting at ~18 ka. The pre-gLGM glacial advances likely document enhanced precipitation related to the Southern Westerlies, which shifted further to the North at that time than previosuly assumed. During the gLGM glacial advances were favored by decreased temperatures in combination with increased humidity due to a southward shifted Intertropical Convergence Zone (ITCZ) and SASM. During the late-glacial a substantial increase in moisture can be explained by enhanced upper tropospheric easterlies as response to an intensified SASM and sustained La Niña-like conditions over the eastern equatorial Pacific that lead to glacial advances in the northern Central Andes and the lake level highstand Tauca (18-14 ka) on the Altiplano. In the southernmost Central Andes at 39º-41°S, further north at 31°S and in the northernmost Central Andes at 22°S glacial remnants even point to precipitation driven glaciations older than ~115 ka and 260 ka.
Highlights
The mass balance of glaciers is sensitive to changes in temperature and precipitation
Glacial features from 41°S (Bariloche) to the north in the Ruchachoroi valley, Cordón de Doña Rosa, El Encierro valley, and even as far north as 26°S (Sierra de Quilmes) document that maximum ice extent for the most extensive glacial advance occurred as early as ~40 ka (MIS 3) both west and east of the Andean divide arguing for wetter conditions before the gLGM
In the arid Central Andes glaciers are very sensitive to changes in the precipitation regime
Summary
The mass balance of glaciers is sensitive to changes in temperature and precipitation. Reconstructing past climate from paleoglaciers yields important insights into timing and magnitude of climate changes regionally and into changes in the atmospheric circulation system and related climate dynamics. The Argentinean and Chilean Central Andes (22°-41°S) situated between the tropical and extratropical atmospheric circulation systems are a key area to study past climate changes in the Southern Hemisphere on orbital and millennial timescale. Multiple questions remain regarding the influence and interplay between the tropical circulation system and the Westerlies in the core region of the arid Central Andes, the so-called Arid Diagonal (Fig. 1). We summarize previous research studies (Zech R. et al, 2007, 2008, 2009, 2010; Zech J. et al, 2009) about the late Pleistocene glaciation history and present new surface exposure ages (10Be) along a N-S transect through the Central Argentinian and Chilean Andes between 41° and 22°S and interpret them in terms of climate variability
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