Holocene land cover change in south-western Amazonia inferred from paleoflood archives

This study provides new data on the evolution of the landscape in south-western Amazonia during the Holocene and the impact of climate change and fluvial dynamics on the region's ecosystems. South-western Amazonia is covered by an extensive seasonally flooded savannah, known as the Llanos de Moxos. Severe drought during the southern hemisphere winter, followed by months of permanent waterlogging, means that forests only grow on the most elevated parts of the landscape, mostly river and paleoriver levees and crevasse splays. Paleoclimate reconstructions from surrounding areas show that a shift to wetter conditions at around 4 kyr BP caused an increase in forest cover. However, the impact that this change in climate had on the landscape of the Llanos de Moxos is unknown. Published lacustrine archives from the area only cover the last 2 kyr. Here we present new data from the analysis of paleosols located along a 300 km transect across the central Llanos. The analyses of stable carbon isotopes, from 36 paleosols, and biogenic silica, from 29 paleosols, show that the patchwork of forests and savannahs that we see today was established after the 4 kyr BP climate change. During the dry period between 8 and 4 kyr BP, most of the central Llanos de Moxos, nowadays covered with seasonally flooded savannah, were covered by Cerrado-like savannah in the west and by forest in the east. However, results also suggest that, at both regional and local scales, vegetation cover has been influenced by changes in topography resulting from the region's river dynamics.

[1]  U. Lombardo,et al.  Alluvial plain dynamics and human occupation in SW Amazonia during the Holocene: A paleosol-based reconstruction , 2018 .

[2]  M. Krishna Isostatic response of the Central Indian Ridge (Western Indian Ocean) based on transfer function analysis of gravity and bathymetry data , 1996 .

[3]  A Alexandre,et al.  International code for phytolith nomenclature 1.0. , 2005, Annals of botany.

[4]  T. Killeen,et al.  Millennial-scale dynamics of southern Amazonian rain forests. , 2000, Science.

[5]  H. Synal,et al.  14C Analysis and Sample Preparation at the New Bern Laboratory for the Analysis of Radiocarbon with AMS (LARA) , 2014, Radiocarbon.

[6]  P. Antoine,et al.  How does the Nazca Ridge subduction influence the modern Amazonian foreland basin?: COMMENT and REPLY REPLY , 2007 .

[7]  Adam Wainwright,et al.  Late Holocene Neotropical agricultural landscapes: phytolith and stable carbon isotope analysis of raised fields from French Guianan coastal savannahs , 2010 .

[8]  Javier Tomasella,et al.  Multi-temporal flood mapping and satellite altimetry used to evaluate the flood dynamics of the Bolivian Amazon wetlands , 2018, Int. J. Appl. Earth Obs. Geoinformation.

[9]  M. Power,et al.  Impact of a drier Early–Mid-Holocene climate upon Amazonian forests , 2008, Philosophical Transactions of the Royal Society B: Biological Sciences.

[10]  U. Lombardo,et al.  Human–environment interactions in pre-Columbian Amazonia: The case of the Llanos de Moxos, Bolivia , 2013 .

[11]  J. Wynn Carbon isotope fractionation during decomposition of organic matter in soils and paleosols: Implications for paleoecological interpretations of paleosols , 2007 .

[12]  Caroline A.E. Strömberg,et al.  Methodological concerns for analysis of phytolith assemblages: Does count size matter? , 2009 .

[13]  D. Embert,et al.  Spatial patterns of biological diversity in a neotropical lowland savanna of northeastern Bolivia , 2011, Biodiversity and Conservation.

[14]  D. Mann,et al.  A 45 kyr palaeoclimate record from the lowland interior of tropical South America , 2011 .

[15]  U. Lombardo,et al.  Pre-Columbian agriculture in the Bolivian Lowlands : Construction history and management of raised fields in Bermeo , 2015 .

[16]  Stanley A. Schumm,et al.  Active Tectonics and Alluvial Rivers , 2002 .

[17]  Geoffrey O. Seltzer,et al.  The history of South American tropical precipitation for the past 25,000 years. , 2001, Science.

[18]  R. Bonnefille,et al.  Phytoliths as paleoenvironmental indicators, West Side Middle Awash Valley, Ethiopia , 1999 .

[19]  A. Ballouche,et al.  The Early Holocene palaeoenvironment of Ounjougou (Mali) : Phytoliths in a multiproxy context , 2009 .

[20]  U. Lombardo,et al.  Raised fields in the Bolivian Amazonia: a prehistoric green revolution or a flood risk mitigation strategy? , 2011 .

[21]  P. Antoine,et al.  How does the Nazca Ridge subduction influence the modern Amazonian foreland basin , 2007 .

[22]  J. Soto,et al.  Environmental impact of geometric earthwork construction in pre-Columbian Amazonia , 2014, Proceedings of the National Academy of Sciences.

[23]  J. Guiot,et al.  Phytolith indices as proxies of grass subfamilies on East African tropical mountains , 2008 .

[24]  José Iriarte,et al.  Impact of pre-Columbian “geoglyph” builders on Amazonian forests , 2017, Proceedings of the National Academy of Sciences.

[25]  M. Kraus,et al.  Eocene Hydromorphic Paleosols: Significance for Interpreting Ancient Floodplain Processes , 1993 .

[26]  N. Sheldon,et al.  Quantitative paleoenvironmental and paleoclimatic reconstruction using paleosols , 2009 .

[27]  J. Dumont Neotectonics of the Subandes-Brazilian craton boundary using geomorphological data: the Marañon and Beni basins , 1996 .

[28]  M. Silman,et al.  Holocene fires, forest stability and human occupation in south‐western Amazonia , 2013 .

[29]  D. Piperno,et al.  Sparse Pre-Columbian Human Habitation in Western Amazonia , 2012, Science.

[30]  A. Ngomanda,et al.  Reconstructing savanna tree cover from pollen, phytoliths and stable carbon isotopes , 2012 .

[31]  A. Plotzkia,et al.  Geomorphology and evolution of the late Pleistocene to Holocene fluvial system in the south-eastern Llanos de Moxos, Bolivian Amazon , 2017 .

[32]  U. Lombardo,et al.  Mid- to late-Holocene fluvial activity behind pre-Columbian social complexity in the southwestern Amazon basin , 2012 .

[33]  Q. Hua,et al.  SHCal13 Southern Hemisphere Calibration, 0–50,000 Years cal BP , 2013, Radiocarbon.

[34]  U. Lombardo,et al.  Design of pre-Columbian raised fields in the Llanos de Moxos, Bolivian Amazon: Differential adaptations to the local environment? , 2018 .

[35]  P. DeCelles,et al.  Foreland basin systems , 1996 .

[36]  Robert Langstroth,et al.  FOREST ISLANDS IN AN AMAZONIAN SAVANNA OF NORTHEASTERN BOLIVIA , 2002 .

[37]  U. Lombardo River logjams cause frequent large-scale forest die-off events in southwestern Amazonia , 2017 .

[38]  U. Lombardo Alluvial plain dynamics in the southern Amazonian foreland basin , 2015 .

[39]  G. Hérail,et al.  Neogene shortening contribution to crustal thickening in the back arc of the Central Andes , 1997 .

[40]  S. Higgins,et al.  When is a ‘forest’ a savanna, and why does it matter? , 2011 .

[41]  W. Tan,et al.  Paleovegetation reconstruction using δ 13 C of Soil Organic Matter , 2008 .

[42]  John H. Walker The Llanos de Mojos , 2008 .

[43]  Rosa M. Poch,et al.  Hydromorphic and clay-related processes in soils from the Llanos de Moxos (northern Bolivia) , 2003 .

[44]  Sin Chan Chou,et al.  Development of regional future climate change scenarios in South America using the Eta CPTEC/HadCM3 climate change projections: climatology and regional analyses for the Amazon, São Francisco and the Paraná River basins , 2012, Climate Dynamics.

[45]  E. Neves,et al.  Evidence for mid-Holocene rice domestication in the Americas , 2017, Nature Ecology & Evolution.

[46]  M. Madella,et al.  Combining phytoliths and δ13C matter in Holocene palaeoenvironmental studies of tropical soils: An example of an Oxisol in Brazil , 2013 .

[47]  F. A. McInerney,et al.  The Neogene transition from C3 to C4 grasslands in North America: assemblage analysis of fossil phytoliths , 2011, Paleobiology.

[48]  J. Clarke The occurrence and significance of biogenic opal in the regolith , 2003 .

[49]  U. Cubasch,et al.  Mid- to Late Holocene climate change: an overview , 2008 .

[50]  R. Plotkin Biogeography of the Llanos de Moxos: natural and anthropogenic determinants , 2012 .

[51]  C. Feller,et al.  Physical control of soil organic matter dynamics in the tropics , 1997 .

[52]  Hongye Liu,et al.  Phytoliths as a method of identification for three genera of woody bamboos (Bambusoideae) in tropical southwest China , 2016 .

[53]  U. Lombardo,et al.  Long-term man–environment interactions in the Bolivian Amazon: 8000 years of vegetation dynamics , 2016 .

[54]  L. Raz,et al.  Phytoliths as a tool for archaeobotanical, palaeobotanical and palaeoecological studies in Amazonian palms , 2016 .

[55]  G. McPherson,et al.  Stable carbon isotope analysis of soil organic matter illustrates vegetation change at the grassland/woodland boundary in southeastern Arizona, USA , 1993, Oecologia.

[56]  U. Lombardo Neotectonics, flooding patterns and landscape evolution in southern Amazonia , 2014 .

[57]  R. Aravena,et al.  Late Quaternary Vegetation Dynamics in the Southern Amazon Basin Inferred from Carbon Isotopes in Soil Organic Matter , 2001, Quaternary Research.

[58]  U. Lombardo,et al.  Linking soil properties and pre-Columbian agricultural strategies in the Bolivian lowlands: The case of raised fields in Exaltación , 2017 .

[59]  W. Wilcke,et al.  Soil Carbon-13 Natural Abundance under Native and Managed Vegetation in Brazil , 2004 .

[60]  U. Lombardo,et al.  Early and Middle Holocene Hunter-Gatherer Occupations in Western Amazonia: The Hidden Shell Middens , 2013, PloS one.

[61]  L. Tieszen,et al.  Stable Carbon Isotopes in Terrestrial Ecosystem Research , 1989 .

[62]  R. Aravena,et al.  The carbon isotope record in soils along a forest-cerrado ecosystem transect: implications for vegetation changes in the Rondonia state, southwestern Brazilian Amazon region , 1998 .

[63]  José Iriarte,et al.  Pre-Columbian landscape impact and agriculture in the Monumental Mound region of the Llanos de Moxos, lowland Bolivia , 2013, Quaternary Research.

[64]  B. Meggers Handbook of South American Archaeology , 2011 .

[65]  J. Bates,et al.  Biogeographic Patterns and Conservation in the South American Cerrado: A Tropical Savanna Hotspot , 2002 .

[66]  J. A. Ratter,et al.  The Brazilian Cerrado Vegetation and Threats to its Biodiversity , 1997 .

[67]  H. Birks,et al.  Biodiversity baselines, thresholds and resilience: testing predictions and assumptions using palaeoecological data. , 2010, Trends in ecology & evolution.

[68]  T. Killeen,et al.  Differentiation of neotropical ecosystems by modern soil phytolith assemblages and its implications for palaeoenvironmental and archaeological reconstructions , 2013 .

[69]  P. Meir,et al.  Long-term forest–savannah dynamics in the Bolivian Amazon: implications for conservation , 2007, Philosophical Transactions of the Royal Society B: Biological Sciences.

[70]  M. Fournier,et al.  Geodynamic environment of Quaternary morphostructures of the subandean foreland basins of Peru and Bolivia: Characteristics and study methods , 1994 .

[71]  Javier Ruiz-Pérez,et al.  Sonication improves the efficiency, efficacy and safety of phytolith extraction , 2016 .

[72]  U. Lombardo,et al.  The unique functioning of a pre-Columbian Amazonian floodplain fishery , 2018, Scientific Reports.

[73]  U. Lombardo,et al.  Soil properties and pre-Columbian settlement patterns in the Monumental Mounds Region of the Llanos de Moxos, Bolivian Amazon , 2014 .

[74]  V. Rull,et al.  Quaternary palaeoecology and nature conservation: a general review with examples from the neotropics , 2011 .

[75]  D. Piperno,et al.  The silica bodies of tropical American grasses : morphology, taxonomy, and implications for grass systematics and fossil phytolith identification , 1998 .

[76]  U. Lombardo,et al.  Geomorphology and evolution of the late Pleistocene to Holocene fluvial system in the south-eastern Llanos de Moxos, Bolivian Amazon , 2015 .

[77]  R. Dorn,et al.  Stable Carbon Isotope Ratios of Rock Varnish Organic Matter: A New Paleoenvironmental Indicator , 1985, Science.

[78]  U. Lombardo,et al.  The origin of oriented lakes: evidence from the Bolivian Amazon , 2014 .

[79]  W. Junk,et al.  EFFECTS OF CLIMATE CHANGE ON WETLANDS Current state of knowledge regarding South America wetlands and their future under global climate change , 2012 .

[80]  D. Piperno,et al.  Vegetational History of a Site in the Central Amazon Basin Derived from Phytolith and Charcoal Records from Natural Soils , 1996, Quaternary Research.

[81]  U. Lombardo,et al.  An insight into pre-Columbian raised fields: the case of San Borja, Bolivian lowlands , 2016 .

[82]  P. A. Baker,et al.  Holocene hydrologic variation at Lake Titicaca, Bolivia/Peru, and its relationship to North Atlantic climate variation , 2005 .

[83]  A. Mariotti,et al.  Forest savanna ecotone dynamics in India as revealed by carbon isotope ratios of soil organic matter , 1994, Oecologia.

[84]  R. Bonnefille,et al.  Comparative study of modern phytolith assemblages from inter-tropical Africa , 2007 .

[85]  F. Preusser,et al.  Geomorphological and sedimentary evidence for late Pleistocene to Holocene hydrological change along the Río Mamoré, Bolivian Amazon , 2013 .

[86]  T. Feldpausch,et al.  Differentiation of neotropical ecosystems by modern soil phytolith assemblages and its implications for palaeoenvironmental and archaeological reconstructions II: Southwestern Amazonian forests , 2016 .

[87]  A. Busacca,et al.  Reconstruction of the late Pleistocene grassland of the Columbia basin, Washington, USA, based on phytolith records in loess , 2002 .

[88]  S. Gotsch,et al.  Ecological thresholds at the savanna-forest boundary: how plant traits, resources and fire govern the distribution of tropical biomes. , 2012, Ecology letters.

[89]  U. Lombardo,et al.  Eco-archaeological regions in the Bolivian Amazon , 2012 .

[90]  J. Darrozes,et al.  Geomorphic evidence for recent uplift of the Fitzcarrald Arch (Peru): a response to the Nazca Ridge subduction , 2009 .

[91]  F. Preusser,et al.  Holocene floodplain soils along the Río Mamoré, northern Bolivia, and their implications for understanding inundation and depositional patterns in seasonal wetland settings , 2015 .