Geomorphologic evidence for the late Pliocene onset of hyperaridity in the Atacama Desert

The Atacama Desert has experienced a long and protracted period of hyperaridity that has resulted in what may be the most unusual biome on Earth, but the duration of this aridity is poorly constrained. We reconstructed aspects of the fluvial and geochemical history of this region using integrated landscape features (alluvial fans, hillslope soils, soil chemistry, river profiles) in the southern portion of the present desert. Topographic reconstructions of a large watershed (11,000 km 2 ) show deep incision and sediment removal between the late Miocene and the end of the Pliocene, and modest to negligible incision in post-Pliocene times. These changes in incision suggest an ∼50–280× reduction in river discharge, which should reflect corresponding changes in precipitation. Changes in the nature of hillslope soils in the Atacama Desert indicate that in the Pliocene or earlier, hillslopes were mantled with silicate-derived soil. This mantle was stripped off and locally deposited as alluvial fans (late Pliocene to early Pleistocene) that now block or otherwise cause a rearrangement of Pliocene and earlier river channels. Finally, the hillslopes have largely accreted a soil mantle of dust and salt since the apparent late Pliocene stripping, suggesting a decline in annual precipitation of at least 125 mm yr -1 or more (mean annual precipitation [MAP] is now -1 ). Embedded in the long post-Pliocene era of salt accumulation, there are a variety of features suggesting overland flow on hillslopes (rills, striped gravel deposits, piping, and water spouts) and large, infrequent storms that infiltrated gentle alluvial fans (due to the depth of salt-rich horizons). Despite evidence for episodes that punctuate the hyperaridity, the magnitude and duration of these pluvial events have been insufficient to remove the regional accumulations of sulfate, chloride, and nitrate. The late Pliocene cessation of many fluvial features is coincident with recent research on the tropical Pacific, which shows that the Pacific was in a permanent El Nino state until ca. 2.2 Ma, at which time sea-surface temperatures offshore of South America declined greatly relative to those of the western Pacific, in turn setting up the present El Nino–Southern Oscillation (ENSO) climate system. These observations indicate that the latest period of aridity has been prolonged and largely continuous, and it appears to have occurred in step with the onset of the ENSO climate system, beginning ∼2 m.y. ago.

[1]  R. Allmendinger,et al.  Trench-parallel shortening in the Northern Chilean Forearc: Tectonic and climatic implications , 2005 .

[2]  A. Hartley,et al.  Controls on supergene enrichment of porphyry copper deposits in the Central Andes: A review and discussion , 2005 .

[3]  R. Sillitoe,et al.  Implications of the Isotopic Ages of Ignimbrite Flows, Southern Atacama Desert, Chile , 1967, Nature.

[4]  David R. Montgomery,et al.  A process-based model for colluvial soil depth and shallow landsliding using digital elevation data , 1995 .

[5]  R. Garreaud,et al.  Andean uplift, ocean cooling and Atacama hyperaridity: A climate modeling perspective , 2010 .

[6]  R. Amundson,et al.  Non-biological fractionation of stable Ca isotopes in soils of the Atacama Desert, Chile , 2008 .

[7]  J. Quade,et al.  Isotopic evidence for the source of Ca and S in soil gypsum, anhydrite and calcite in the Atacama Desert, Chile , 2003 .

[8]  Christopher P. McKay,et al.  Hypolithic Cyanobacteria, Dry Limit of Photosynthesis, and Microbial Ecology in the Hyperarid Atacama Desert , 2006, Microbial Ecology.

[9]  J. Darrozes,et al.  Late Cenozoic geomorphologic signal of Andean forearc deformation and tilting associated with the uplift and climate changes of the Southern Atacama Desert (26°S-28°S) , 2007 .

[10]  G. Hoke,et al.  Uplift of the Altiplano‐Puna plateau: A view from the west , 2010 .

[11]  Cedrig Mortimer,et al.  The Cenozoic history of the southern Atacama Desert, Chile , 1973, Journal of the Geological Society.

[12]  C. Marquardt,et al.  Coastal neotectonics in Southern Central Andes: uplift and deformation of marine terraces in Northern Chile (27°S) , 2004 .

[13]  Rech,et al.  A 22,000-Year Record of Monsoonal Precipitation from Northern Chile's Atacama Desert. , 2000, Science.

[14]  A. Hartley,et al.  Late Pliocene age for the Atacama Desert: Implications for the desertification of western South America , 2002 .

[15]  C. Mortimer DRAINAGE EVOLUTION IN THE ATACAMA DESERT OF NORTHERNMOST CHILE , 2010 .

[16]  M. Vuille,et al.  Climate change projections for the tropical Andes using a regional climate model: Temperature and precipitation simulations for the end of the 21st century , 2009 .

[17]  J. Syvitski,et al.  Geology, Geography, and Humans Battle for Dominance over the Delivery of Fluvial Sediment to the Coastal Ocean , 2007, The Journal of Geology.

[18]  Christopher P. McKay,et al.  Mars-Like Soils in the Atacama Desert, Chile, and the Dry Limit of Microbial Life , 2003, Science.

[19]  D. Fabel,et al.  Global cooling initiated stony deserts in central Australia 2-4 Ma, dated by cosmogenic 21Ne-10Be , 2005 .

[20]  C. Hillaire‐Marcel,et al.  Coastal deformation and sea-level changes in the northern Chile subduction area (23°S) during the last 330 ky , 1996 .

[21]  G. Wefer,et al.  Linking desert evolution and coastal upwelling: Pliocene climate change in Namibia , 2005 .

[22]  A. Ravelo,et al.  Evidence for El Niño–like conditions during the Pliocene , 2006 .

[23]  M. Wara,et al.  Permanent El Niño-Like Conditions During the Pliocene Warm Period , 2005, Science.

[24]  W. Dietrich,et al.  Late Quaternary erosion in southeastern Australia: a field example using cosmogenic nuclides , 2001 .

[25]  G. Hérail,et al.  Sedimentation and preservation of the Miocene Atacama Gravels in the Pedernales-Chañaral Area, Northern Chile: Climatic or Tectonic Control? , 2008 .

[26]  G. E. Ericksen GEOLOGY AND ORIGIN OF THE CHILEAN NITRATE DEPOSITS , 1981 .

[27]  P. Gibbard,et al.  Formal ratification of the Quaternary System/Period and the Pleistocene Series/Epoch with a base at 2.58 Ma , 2010 .

[28]  Paul Davis,et al.  Cenozoic climate change as a possible cause for the rise of the Andes , 2003, Nature.

[29]  R. Allmendinger,et al.  Young displacements on the Atacama Fault System, northern Chile from field observations and cosmogenic 21Ne concentrations , 2006 .

[30]  B. Bookhagen,et al.  The topographic imprint of a transient climate episode: the western Andean flank between 15·5° and 41·5°S , 2010 .

[31]  G. Wahba Spline models for observational data , 1990 .

[32]  W. Dietrich,et al.  The sensitivity of hillslope bedrock erosion to precipitation , 2011 .

[33]  J. Betancourt,et al.  Soils at the hyperarid margin: The isotopic composition of soil carbonate from the Atacama Desert, Northern Chile , 2007 .

[34]  W. Weinrebe,et al.  Subduction erosion along the North Chile margin , 1999 .

[35]  C. Marquardt,et al.  Neogene-quaternary coastal and offshore sedimentation in north central chile: record of sea-level changes and implications for andean tectonism , 2005 .

[36]  J. Böhlke,et al.  Long term atmospheric deposition as the source of nitrate and other salts in the Atacama Desert, Chile: New evidence from mass-independent oxygen isotopic compositions , 2004 .

[37]  G. Tucker,et al.  Dynamics of the stream‐power river incision model: Implications for height limits of mountain ranges, landscape response timescales, and research needs , 1999 .

[38]  Jorge Quezada,et al.  Alzamiento litoral Pleistoceno del norte de Chile: edades 21Ne de la terraza costera más alta del área deCaldera-Bahía Inglesa , 2007 .

[39]  B. Currie,et al.  Neogene climate change and uplift in the Atacama Desert, Chile , 2006 .

[40]  K. Nishiizumi,et al.  Chemical isolation of quartz for measurement of in-situ-produced cosmogenic nuclides , 1992 .

[41]  M. Collins,et al.  El Niño- or La Niña-like climate change? , 2005 .

[42]  William E. Dietrich,et al.  Cosmogenic nuclides, topography, and the spatial variation of soil depth , 1999 .

[43]  J. Wehmiller,et al.  Low Uplift Rates and Terrace Reoccupation Inferred from Mollusk Aminostratigraphy, Coquimbo Bay Area, Chile , 1992, Quaternary Research.

[44]  G. Vecchi,et al.  Weakening of tropical Pacific atmospheric circulation due to anthropogenic forcing , 2006, Nature.

[45]  C. Darwin Journal of researches into the natural history and geology of the countries visited during the voyage of H.M.S. Beagle round the world : under the command of Capt. Fitz Roy, R.N. / by Charles Darwin. , 1860 .

[46]  S. Lamb,et al.  Origin of the high plateau in the central Andes, Bolivia, South America , 1997 .

[47]  J. Rutllant,et al.  Climate dynamics along the arid northern coast of Chile: The 1997–1998 Dinámica del Clima de la Región de Antofagasta (DICLIMA) experiment , 2003 .

[48]  C. Alpers,et al.  Middle Miocene climatic change in the Atacama desert , 1988 .

[49]  Samuel Niedermann,et al.  Evidence for active landscape evolution in the hyperarid Atacama from multiple terrestrial cosmogenic nuclides , 2010 .

[50]  T. Dunai,et al.  Late Neogene passive margin denudation history: cosmogenic isotope measurements from Central Namib desert. , 2001 .

[51]  M. Wara,et al.  Regional climate shifts caused by gradual global cooling in the Pliocene epoch , 2004, Nature.

[52]  F. Bondoux,et al.  Non-steady long-term uplift rates and Pleistocene marine terrace development along the Andean margin of Chile (31°S) inferred from 10Be dating , 2009 .

[53]  Tibor J. Dunai,et al.  Oligocene Miocene age of aridity in the Atacama Desert revealed by exposure dating of erosion-sensitive landforms , 2005 .

[54]  M. Hutchinson A new procedure for gridding elevation and stream line data with automatic removal of spurious pits , 1989 .

[55]  D. Lal,et al.  Cosmic ray labeling of erosion surfaces: in situ nuclide production rates and erosion models , 1991 .

[56]  J. Betancourt,et al.  Microbial Life in the Atacama Desert , 2004, Science.

[57]  J. Southon,et al.  Absolute calibration of 10Be AMS standards , 2007 .

[58]  M. Leybourne,et al.  Supergene enrichment of copper deposits since the onset of modern hyperaridity in the Atacama Desert, Chile , 2009 .

[59]  J. Houston,et al.  Variability of precipitation in the Atacama Desert: its causes and hydrological impact , 2006 .

[60]  R. Amundson,et al.  Rainfall limit of the N cycle on Earth , 2007 .

[61]  Christopher P. McKay,et al.  A threshold in soil formation at Earth's arid-hyperarid transition , 2006 .

[62]  David R. Montgomery,et al.  Climate, tectonics, and the morphology of the Andes , 2001 .

[63]  M. Cane,et al.  El Nino's tropical climate and teleconnections as a blueprint for pre-Ice Age climates , 2002 .

[64]  S. Wells,et al.  Influences of eolian and pedogenic processes on the origin and evolution of desert pavements , 1987 .

[65]  Bodo Bookhagen,et al.  Orographic barriers, high‐resolution TRMM rainfall, and relief variations along the eastern Andes , 2008 .

[66]  Christopher P. McKay,et al.  Changes in the soil C cycle at the arid‐hyperarid transition in the Atacama Desert , 2008 .

[67]  F. Lamy,et al.  Tracing the impact of glacial-interglacial climate variability on erosion of the southern Andes , 2007 .

[68]  A. Sáez,et al.  Late Neogene lacustrine record and palaeogeography in the Quillagua–Llamara basin, Central Andean fore-arc (northern Chile) , 1999 .

[69]  K. Nishiizumi Preparation of 26Al AMS standards , 2004 .