Environmental changes in the western Amazônia: morphological framework, geochemistry, palynology and radiocarbon dating data

Horbe, Adriana M.C.; Behling, Hermann; Nogueira, Afonso C.R.; Mapes, Russell

doi:10.1590/S0001-37652011005000030

Abstracts

The sediments from the Coari lake, a “terra firme” lake sculpted into Plio-Pleistocene deposits, and the Acará lake, a flooding-type lake developed on Quaternary sediments in the floodplain of the mid-Solimões river, in the western Amazônia, Brazil, were studied to investigate the environmental condition of their developing. This study includes mineral composition, geochemistry, Pb isotope, palinology, radiocarbon-age and morphological framework of the lakes obtained from SRTM satellite images. The geological and the environmental conditions in the two lakes are highly variable and suggest that their evolution reflect autogenic processes under humid rainforest condition. Although kaolinite, quartz, muscovite, illite, and smectite are the main minerals in both lakes, the geochemistry indicates distinct source, the Acará lake sediments have higher concentrations of Al2O3, Fe2O3, FeO, CaO, K2O, MgO, Na2O, P2O5, Ba, V, Cu, Ni, Zn, Pb, Sr, Li, Y and La and have more radiogenic Pb than the Coari lake sediments. The radiocarbon ages suggest that at 10160 yr BP the Coari lake started to be developed due to avulsion of the Solimões river, and the Acará lake was formed by the meander abandonment of Solimões river retaining its grass dominated shore at ca. 3710 yr BP.

Pb isotopes; lacustrine environment; paleovegetation; flooding plain; Holocene

Os sedimentos do lago Coari, de ambiente de terra firme eesculpido nos depósitos do Plio-Pleistocenos, e o Acará, típico lago de várzea e ambos formados nos sedimentos quaternários da planície de inundação do médio Solimões, no oeste da Amazônia, Brasil, foram estudados para investigar as condições ambientais durante sua formação. Este estudo inclui dados da composição mineralógica, química, isótopos de Pb, palinologia, datações de radiocarbono e a configuração morfológica dos lagos obtida por imagens SRTM. As condições geológica e ambiental dos lagos variam e sugerem que suas evoluções refletem processos autogenéticos em condições de floresta úmida e chuvosa. Embora caulinita, quartz, muscovita, illita e esmectita sejam os principais minerais em ambos os lagos, a geoquímica indica fonte distinta, os sedimentos do lago Acará têm maior concentração de Al2O3, Fe2O3, FeO, CaO, K2O, MgO, Na2O, P2O5, Ba, V, Cu, Ni, Zn, Pb, Sr, Li, Y e La e têm mais Pb radiogênico que os sedimentos do lago Coari. As idades de radiocarbono sugerem que há aproximadamente 10160 anos AP o lago Coari iniciou o desenvolvimento devido a avulsão do rio Solimões, enquanto o lago Acará foi formado devido ao abandono de meandro do rio Solimões e retendo o domínio das gramíneas nas suas praias há aproximadamente 3710 anos AP.

isótopos de Pb; ambiente lacustre; paleovegetação; várzea; Holoceno

Environmental changes in the western Amazônia: morphological framework, geochemistry, palynology and radiocarbon dating data

Adriana M.C. Horbe^I; Hermann Behling^II; Afonso C.R. Nogueira^III; Russell Mapes^IV

^IDepartamento de Geociências, Universidade Federal do Amazonas, Av. Rodrigo Otávio Jordão Ramos 3000, 69050-290 Manaus, AM, Brasil

^IIAlbrecht-von-Haller-Institut für Pflanzenwissenschaften der Georg-August-Universität Göttingen, Abteilung für Palynologie und Klimadynamik, Untere Karspüle 2, 37073 Göttingen, Germany

^IIIInstituto de Geociências, Universidade Federal do Pará, Rua Augusto Corrêa 1, 66075-110 Belém, PA, Brasil

^IVDepartment of Geological Science, University of North Carolina, Mitchell Hall, Chapel Hill, NC, 27599-3315, USA

^{Correspondence to} Correspondence to: Adriana Maria Coimbra Horbe E-mail: ahorbe@ufam.edu.br

ABSTRACT

The sediments from the Coari lake, a “terra firme” lake sculpted into Plio-Pleistocene deposits, and the Acará lake, a flooding-type lake developed on Quaternary sediments in the floodplain of the mid-Solimões river, in the western Amazônia, Brazil, were studied to investigate the environmental condition of their developing. This study includes mineral composition, geochemistry, Pb isotope, palinology, radiocarbon-age and morphological framework of the lakes obtained from SRTM satellite images. The geological and the environmental conditions in the two lakes are highly variable and suggest that their evolution reflect autogenic processes under humid rainforest condition. Although kaolinite, quartz, muscovite, illite, and smectite are the main minerals in both lakes, the geochemistry indicates distinct source, the Acará lake sediments have higher concentrations of Al₂O₃, Fe₂O₃, FeO, CaO, K₂O, MgO, Na₂O, P₂O₅, Ba, V, Cu, Ni, Zn, Pb, Sr, Li, Y and La and have more radiogenic Pb than the Coari lake sediments. The radiocarbon ages suggest that at 10160 yr BP the Coari lake started to be developed due to avulsion of the Solimões river, and the Acará lake was formed by the meander abandonment of Solimões river retaining its grass dominated shore at ca. 3710 yr BP.

Key words: Pb isotopes, lacustrine environment, paleovegetation, flooding plain, Holocene.

RESUMO

Os sedimentos do lago Coari, de ambiente de terra firme eesculpido nos depósitos do Plio-Pleistocenos, e o Acará, típico lago de várzea e ambos formados nos sedimentos quaternários da planície de inundação do médio Solimões, no oeste da Amazônia, Brasil, foram estudados para investigar as condições ambientais durante sua formação. Este estudo inclui dados da composição mineralógica, química, isótopos de Pb, palinologia, datações de radiocarbono e a configuração morfológica dos lagos obtida por imagens SRTM. As condições geológica e ambiental dos lagos variam e sugerem que suas evoluções refletem processos autogenéticos em condições de floresta úmida e chuvosa. Embora caulinita, quartz, muscovita, illita e esmectita sejam os principais minerais em ambos os lagos, a geoquímica indica fonte distinta, os sedimentos do lago Acará têm maior concentração de Al₂O₃, Fe₂O₃, FeO, CaO, K₂O, MgO, Na₂O, P₂O₅, Ba, V, Cu, Ni, Zn, Pb, Sr, Li, Y e La e têm mais Pb radiogênico que os sedimentos do lago Coari. As idades de radiocarbono sugerem que há aproximadamente 10160 anos AP o lago Coari iniciou o desenvolvimento devido a avulsão do rio Solimões, enquanto o lago Acará foi formado devido ao abandono de meandro do rio Solimões e retendo o domínio das gramíneas nas suas praias há aproximadamente 3710 anos AP.

Palavras-chave: isótopos de Pb, ambiente lacustre, paleovegetação, várzea, Holoceno.

INTRODUCTION

The current configuration of the middle Solimões-Amazon basin, developed since the Andean uplift during the Pliocene, is characterized by extensive floodplains with several types of lakes that are deposition sites of clay and silt and represent the dominant modern inland sedimentation style (e.g. Hoorn et al. 1995, Mertes et al. 1996, Nanson and Knighton 1996, Hooghiemstraand Van der Hammen 1998). During the evolution of the basin, the position of the channel and the morphology and the size of the fluvial plain of the Solimões-Amazon river has been modified in consequence of the neotectonic movements which may have caused avulsion, new impeded flooplains lakes and island development (e.g. Franzinelli and Latrubesse 1993, Mertes et al. 1996, Costa et al. 2001, Latrubesse and Franzinelli2002, Bezerra 2003). These changes were also influenced by climate and vegetation cover. Many researchers have associated the savanna and rainforest environment in Amazônia to dry and humid conditions (e.g. Suguio et al. 1985, Van der Hammen and Absy 1994, Van der Hammen and Hooghiemstra 2000, Behling et al. 2001, Sifeddine et al. 2001, Behling and Hooghiemstra 2000, 2001).

Investigation on the pollen contents, mineralogy, chemistry, Pb isotope and radiocarbon-age of lake sediments provided a record of the environmental changes and also helped to better understand the climate, the provenance and the geological and biological history of the western Amazônia during the Holocene. In the western Amazônia there are some studies about these aspects (Franzinelli and Igreja 1990, Franzinelli and Latrubesse 1993, Colinvaux et al. 1996, Behling et al. 2001, Latrubesse and Franzinelli 2002, Bezerra 2003, Rossetti 2004). With these purposes, two lakes, Coari and Acará, located at the mid-Solimões river flooded fluvial plain (Fig. 1) were ideal to study the Holocene evolution of the Amazon floodplain sedimentation in the western part of the Brazilian Amazon.

MATERIAL AND ANALYTICAL TECHNIQUES

Mineralogical, chemical, and palynological analyses of the lake sediments along with the radiocarbon dating were done based on the morphological framework obtained from SRTM satellite images. The sediment samples were obtained using a vibra-coring device. Although several cores were collected, only one of each lake, with more than 1.0 m deep, was recovered. The Coari lake core was sampled in the southern portion of the lake and reached 4.05 m deep while the 1.80 m deep Acará lake core was collected in the southwestern part of the lake (Fig. 1).

Mineralogical and chemical analyses of the lake sediments were carried out on eleven and four samples from the Coari and Acará lakes, respectively. Mineralogical analyses were done by X-ray diffractometry performed in a Shimadzu XRD 6000 device, equipped with a Cu anode at 5º to 60º 2θ intervals. Chemical analyses (Al₂O₃, Fe₂O₃, TiO₂, CaO, K₂O, MgO, Na₂O, P₂O₅, Ba, Mn, V, Co, Cr, Cu, Ni, Zn, Pb, Sr, Zr, Li, Y, Sc,Sb, La, Ag, Be, Mo, As, Bi, Sn and W) in melt and triacid solution were carried out by inductively coupled plasma mass spectrometry, except LOI and Hg, which were analyzed by gravimetry and atomic absorption spectrometry, respectively. Total SiO₂ was calculated by subtracting the sum of the oxide percentages from 100%, and FeO by volumetry. Organic carbon was analyzed by volumetry with potassium bychromat solution.

For Pb isotope analysis, 20-40 mg aliquots of sediments were digested in two stages using HF/HNO₃ and 6N HCl on a hot plate. Lead was isolated using an HBr anion exchange technique, loaded onto standard Re filaments with a mixture of silica gel and phosphoric acid, and analyzed with VG Sector 54 thermal ionization mass spectrometer running in static multicollection mode. Typical ²⁰⁸Pb ion beam intensity was ca. 2V with 10^-11Ω resistors. On the basis of multiple analyses of common Pb standard, NBS-981, samples were corrected 0.12%/amu for instrumental mass fractionation.

Samples collected at 0.5 and 1.3 m deep in Acará lake and at 1.8 m and 3.95 m deep in Coari lake were dated by AMS radiocarbon at the "Pysikalisches Institut der Universitat Erlangen-Nürnberg" in Germany. The calibration of the samples was done using the software found in http://radiocarbon.ldeo.columbia.edu that gives ages in years before present (yr BP).

As for the pollen analyses, samples (0.5 cm³) were generally sampled at 10 cm intervals along each core. All samples were treated using standard methods with hydrofluoric acid (47-52%) and acetolysis (Faegri and Iversen 1989). Pollen residues were mounted on slides in a glycerin gelatin medium. A minimum of 300 pollen grains per sample was counted. The pollen sum, excluding aquatic taxa, and fern and moss spores, was the basis for percentage pollen diagrams using TILIA and TILIAGRAPH software (Grimm 1987). The pollen diagrams include percentages of the most abundant pollen and spore taxa, the ecological groups, and the pollen sum. For identification, pollen morphological descriptions published by Absy (1979), Behling (1993), Herrera and Urrego (1996), Hooghiemstra (1984), Roubikand Moreno (1991) and Behling's own reference collection, were used.

PHYSIOGRAPHY AND MORPHOLOGY OF LAKES COARI AND ACARÁ

The Coari and Acará lakes are presently connected to the Solimões river and are influenced by the seasonal flood pulse, which reaches an annual span of 10 m. In satellite images, the Coari lake exhibits a straight pattern with the Mio-Pleistocene units commonly forming cliffs along its shores (Fig. 1). The Coari lake head is characterized by a flooded meandering pattern that enlarges downstream into a funnel-like geometry barred at its mouth by Holocene deposits which are supplied by the Solimões river. The lake is almost 10 km long and reaches 1 km at its maximum width (Figs. 1 and 2).This type of lake is known as "ria" or "terra firme" in the Amazon region (unflooded upland). The Acará lake,located in the right side of a large meander, is a floodplain or "várzea"-type lake and is characterized by a half-moon-shaped with almost 10 km of maximum width which is limited by Holocene deposits and cliffs of the Mio-Pleistocene units (Figs. 1 and 2).

The morphological framework obtained from SRTM satellite images indicates avulsion of the Solimões river with abandoning of the former channel turning it almost 90º to the south and then runs to east until reach the old floodplain in the downstream portion(Fig. 1) in accordance with the structural lineament sand the tectonic event in the region (Mertes et al. 1996, Latrubesse and Franzinelli 2002, Bezerra 2003, and others). In this process, the Solimões river cuts the Mio-Pleistocene units leaving only a straight tongue between the former and the present channel. It also suggests that the drainage precursor of the Coari lake was longer to east than today and the Solimões river used this portion to develop its new channel. The new channel starts to deposit sediments in the new mouth of the Coari lake that contributes to its enlargement (Fig. 2A) and causes inputs of suspended sediment from the Solimões river. The Acará lake, inside the meander floodplain, was developed after the avulsion in the abandoning meander.

The vegetation surrounding the Coari lake is a "terra firme" forest (unflooded upland) and the Acará lake is a "várzea" forest (seasonally inundated). The tree species; Flacourticeae, Bombacaceae, Rubiaceae, Bignoniaceae, Combretaceae, Euphorbiaceae, Vitaceae, Caparidaceae, Sapotaceae, Lauraceae, Tiliaceae, Moraceae, Leguminoceae-Mimosoideae, Polygonaceae, Cecropiaceae,Fabaceae, Lecythidaceae, Myristicaceae, Annonaceae, Anacardiaceae, Dichapetalaceae, and Apocynaceae are common to the study region (Wittmann et al. 2004).Some Poaceae, Cyperaceae, Asteraceae and a few other herbs comprise the lake shore vegetation. On the other hand, the vegetation of the Coari lake is enriched in Poaceae which is characteristic of large areas of floating meadows. This flora is favored by the climate conditions in the region with temperatures between 25ºC and 28ºC and rainfall of ~ 3,000 mm/yr.

COMPOSITION OF THE SEDIMENTS

The lowermost section in both cores is comprised of hard sandy to argillaceous light grey material while the upper portions are homogeneous and consist of unconsolidated organic gray argillaceous to silty material with yellow mottles of ferruginous material (Fig. 2). In the Coari lake, small pieces of charcoal and leaves are common. Kaolinite and quartz are the main mineral constituents, and goethite, muscovite, illite, and smectite occur in small quantities in all samples (Fig. 3). Rare siderite concretions, diatoms and Si-sponge spiculesoccur in the upper sediments. The presence of only 20.3º 2θ kaolinite XRD reflections show its lower order in the B axis which it is an indicative of a detritus origin and/or iron incorporation.

The bulk chemical composition of the Acará lake sediments contain higher Al₂O₃, Fe₂O₃, FeO, CaO, K₂O, MgO, Na₂O and P₂O₅ contents compared to the Coari lake sediments which contain higher SiO₂ (Table I). It is also possible differentiate the sandy to argillaceous sediment in the lowermost section of the Coari lake with higher contents of SiO₂ and lower of almost all the other elements, from the gray argillaceous to silty material upward. The chemical differentiation between lower and upper lake sediment is less perceptible in Acará lake, it has in the lower portion higher SiO₂, CaO and Na₂O contents, upward the FeO, MgO and P₂O₅ contents increase while the Al₂O₃ content does not vary considerably. Carbon content in lakes sediments from both cores (i.e. leaves and charcoal fragments) varies from 5% to 38% indicating significant variation in organic matter input (Table I). The sediments bear low contents of trace-elements as compared to bulk crustal values, particularly on what refers to Mn, V, Cu, Zn, Pb, Sr, Sc, La and Hg (Table I). The Ba, V, Cu, Ni, Zn, Pb, Sr, Li, Y and La concentrations are higher in Acará lake than in Coari lake. Most trace-element concentrations increase upward except Co, Ni, Y, Sb, and La in Coari lake and Co, Ni, Sr, and La in Acará lake (Table I). Acará lake sediments are homogeneous in the distribution of trace element contents (except Mn from 762 to 133 ppm) but in Coari lake, Ba, Mn, Zn, Pb, Y and Sc show a variation of over 100%. Most trace-elements (V, Co, Cu, Ni, Zn, Pb, Sr, Zr, Li) appear to be associated with occurrence of muscovite, illite, smectite, goethite and siderite. Table II shows the most significant correlation factors for trace elements against the major constituent oxides of those minerals (K₂O, MgO and Fe₂O₃). Correlations with kaolinite and quartz is less significant (r = < 0.7).

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LEAD ISOTOPIC COMPOSITION

The lead isotopic composition (²⁰⁶Pb/²⁰⁴Pb, ²⁰⁷Pb/ ²⁰⁴Pb, and ²⁰⁸Pb/²⁰⁴Pb) is different for each lake (Table III and Fig. 4); the Acará lake sediments show higher isotope homogeneity and are more similar to the Pleistocene and Holocene Amazon fan muds (McDaniel et al. 1997, 1998) while the Coari lake sediments are less radiogenic and yield a wider range of Pb isotope values. Moreover, the Pb isotopic composition of the Coari lake shows some similarity to those in the suspended sediment of the Modern Amazon (Asmerom and Jacobsen 1993, Allègre et al. 1996).

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PALYNOLOGICAL CONTENT

Figure 5 shows the most frequent taxa found in the sediment from the Coari lake. The lowermost section of the core is characterized by low tree and shrub pollen contents (25-40%), as well as, a high amount of herb pollen (max 75%), especially from Cyperaceae,Poaceae I (which is small-sized and bears a small annulus) and from Poaceae II. Upward, herb pollen content decreases and represents only 10-20% of all the pollen in the core. Asteraceae pollen content is relatively high in the middle part of the core. Amazonian tree and shrub pollen become less frequent ( ~ 70%) in the upper portion of the core, as well. Several taxa is relatively well-represented (e.g. Moraceae/Urticaceae, Mabea), while others are abundant only at specific levels (e.g. Bombacaceae, Salix, Amanoa). A sequence of maxima for different taxa start with Bombacaceae, Salix, Alchornea, and include Moraceae/Urticaceae, Amanoa the Macrolobium-type and the cf. Symmeria-type. Aquatic taxa (a few pollen grains of Sagittaria) and fern spores (shown only as sums in the diagram) are almost absent or play a minor role, respectively. There is one common unknown pollen type in the upper section of the core.

The pollen data from the Acará lake is marked by a high amount of herb pollen (around 80%)throughout the record, especially from Poaceae I, some Cyperaceae and Alternathera, and a few Asteraceae and Amaranthaceae/Chenopodiaceae (Fig. 5). Trees and shrubs are poorly represented in the lake deposits ando not vary markedly. Moraceae/Urticaceae, Alchornea, cf. Symmeria-type are the most common pollen types, followed by Myrtaceae, Cecropia, Melastomataceae/ Combretaceae, Mabea, and some other less significant taxa. Aquatic taxa are represented by just a few pollen grains from Sagittaria. Fern spores are also very scarce.

RADIOCARBON DATING AND δ ¹³C

Two AMS radiocarbon dates from each lake provide important information about the timing of lacustrine sedimentation (Table IV, Fig. 2). Sediment samples taken at 1.8 m and 3.95 m core depths from the Coari lake yielded ages of 4910±52 ¹⁴C yr BP or 5630 cal yr BP and 8975±59 ¹⁴C yr BP or 10160 cal yr BP respectively. Yet, sediments collected at 0.55 m and 1.3 m core depths in the Acará lake yielded ages of 2586± 50 ¹⁴C yr BP or 2720 cal yr BP and 3457±46 ¹⁴C yr BP or 3710 cal yr BP, respectively. The plant δ¹³C data has values ranging from -30.8 to -27.7 typical of C₃ plants, which reflect the organic matter contribution from surrounding forest vegetation accumulated in the lakes with a few contribution of herb vegetation.

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DISCUSSION AND CONCLUSIONS

The morphological framework of the floodplains and the composition of the sediments with their physical, mineralogical and chemical characteristics allow us to make important considerations about the environment where the Coari and Acará lakes were developed.

The sharp break in the sediment types from sandy to argillaceous in the bottom to organic gray argillaceous to silty material in the upper portion of the cores in both lakes, suggests changes in the environmental dynamic, as well as changes in the sources of the sediments which is better identified in the Coari lake. The organic gray argillaceous to silty material in the upper portion of the cores indicates that over the fluvial sediments a stagnated condition might have developed in a typical lake environment. This environment promoted the deposition of the fine-grained lacustrine sediments rich in kaolinite, illite and smectite in opposition to the sandy to argillaceous fluvial material enriched in quartz. Siderite concretions, product of iron oxide reduction, are absent in the sandy to argillaceous material and may be associated to seasonal water table fluctuation or mixing of oxygenated meteoric water in a stagnant lake conditions (Aslan and Autin 1996). This finding reinforces a shallow and probable lake depositional environment to the organic gray argillaceous to silty material in the upper portion of the cores. Accumulations of leaves, sponge spicules, and diatoms were produced by biological and metabolic activities of plants and animals while the existence of charcoal fragments suggest fire associated with dry periods or human activities.

This change in the deposition environment is also demonstrated by the geochemical pattern where most of the trace elements are more concentrated in the lacustrine sediments. Moreover, the geochemical patterns of the sediments from the two lakes are different (i.e. higher concentration of Al₂O₃, Fe₂O₃, FeO, CaO, K₂O, MgO, Na₂O, P₂O₅, Ba, V, Cu, Ni, Zn, Pb, Sr, Li, Y and La in the Acará lake and the Pb isotopic composition of the Acará lake is more radiogenic and shows a narrow range compared to the Coari lake). Their geochemical differences are attributed to their geological environment; the Coari lake developed in a "terra firme"Mio-Pleistocene units with inputs from the modern suspended sediment of Solimões river while the Acará lake, an Holocene "várzea"-like, is more isolate, being the Holocene bank the main source of sediments (Fig. 1). The high homogeneities in the SiO₂ and Al₂O₃ contents, that reflect the quartz and kaolinite proportion in the sediments of the lakes, point out a source and a paleoenvironmental stability during their development.

The AMS radiocarbon dates indicate that the depositional rate of the sedimentation decreased toward the present time for both lakes, from 0.047 to 0.032 cm/yr in the Coari lake and from 0.080 to 0.018 cm/year in the Acará lake. This decreased depositional rate is consequence of the set up of the lacustrine environment.The higher depositional rate for the Coari lake is consequence of the erosion of the cliffs along its shores and by the proximity to the Solimões river, which is the main source influx of sediments. The radiocarbon dates suggest that if the stagnant environment in the Coari lake would have started by 8975 ¹⁴C yr BP or 10160 cal yr BP the avulsion of the Solimões river would be immediate earlier. The probable age for the Acará lake 3457 ¹⁴Cyr BP or 3710 cal yr BP, indicates when the abandonment of the Solimões river meander was completed.

The avulsion of the Solimões river barring and enlarging the Coari lake causes the water level to rise flooding the open exposed banks up to the rainforest boundaries. This causes greater change in the vegetation surrounding the lake. The herbs, especially Cyperaceae and Poaceae I, that colonized the exposed, non flooded lake shore and bank were sudden substituted by tree and shrub pollens of Bombacaceae, Salix, Alchornea, Moraceae/Urticaceae that changed to Amanoa, Macrolobium-type, and cf. Symmeria-type.The Acará lake, developed by 3457 ¹⁴C yr BP or 3710cal yr BP maintains an open exposed banks condition where herb pollen is the main type.

Although the pollens indicate vegetation variability with prevalence of the Amazonian tree and shrub pollens for the Coari lake and herbs for the whole Acará lake, the C₃ are an indicative of the forest vegetation for the two lakes. These data suggest that the herbs,especially Cyperaceae and Poaceae I, colonized the exposed, non flooded lake shore and banks as is usually found nowadays in Amazonia in a forest environment condition. The argillaceous to silty material upper cores, indicative of the low erosional rate, is in accordance with a prevalence of forest vegetation. As the two lakes are less than 100 km way, we can point out forest environment in the region of the Coari-Acará lakes and therefore humid condition since 8975 ¹⁴C yr BP or10160 cal yr BP. Similar environment was found for the Calado lake located 150 km far way (Behling et al.2001). Nevertheless variable environmental condition were detected in the Amazonia during the time, drier in the central portion between 4000 and 3500 ¹⁴C yr BP and 2100 and 700 yr ¹⁴C BP (Absy 1979) and in 4000 ¹⁴C yr BP (Moreira et al. 2009) but also humid in 6000 and 2500 yr ¹⁴C yr BP in the east (Behling and Costa 2000), in the west since 8280 ¹⁴C yr BP (Behling et al. 2001) and in the central Amazonia in 4600 ¹⁴C yr BP (Irion et al. 2006). These insights suggest that the evolution of both lakes may reflect autogenic processes under humid rainforest condition and their geochemical and palynologic history are consequence of local environmental conditions.

ACKNOWLEDGMENTS

This study was sponsored by the Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), the Fundação de Amparo à Pesquisa do Estado do Amazonas (FAPEAM) and by the Universidade Federal do Amazonas. We thank to Drew Coleman for the opportunity to do the Pb isotopes analysis in the Department of Geological Science, University of North Carolina and for Marcelo B. Motta for help with the figures and to the anonymous referees whose suggestions helped improve the manuscript.

Manuscript received on November 25, 2009; accepted for publication on December 1, 2010

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HOOGHIEMSTRA H AND VAN DER HAMMEN T. 1998. Neogene and Quarternary development of the neotropical rain forest: the forest refugia hypothesis, and literature overview. Earth-Sci Rev 44: 147-183.
HOORN C, GUERRERO J, SARMIENTO GA, LOTENTE MA. 1995. Andean tectonic as a cause for changing drainage patterns in Miocene northern South America. Geol 23: 237-240.
IRION G, BUSH MB, DE MELLO JN, STUBEN D, NEUMANN T, MULLER G, DE MORAIS JO AND JUNK JW. 2006. A multiproxi paleeoecological record of Holocene lake sediment from the Rio Tapajós, eastern Amazonia. Paleogeogr Paleoclimatol Paleoecol 240: 523-535.
LATRUBESSE EM AND FRANZINELLI E. 2002. The Holocene alluvial plain of the middle Amazon River, Brazil. Geomorph 44: 241-257.
MCDANIEL DK. 1998. Provenance and weathering history of Amazon sediment, Dissertation, State University of New York at Stony Brook. (Unpublished).
MCDANIEL DK, MCLENNAN SM AND HANSON GN. 1997. Provenance of Amazon fan muds: constraints from Nd and Pb isotopes. Proceedings of the Ocean Drilling Program 155: 169-176.
MERTES LAK, DUNNE T AND MARTINELLI LA. 1996. Channel-floodplain geomorphology along the Solimőes-Amazon River, Brazil. Geol Soc Am Bull 108: 1089-1107.
MOREIRA LS, MOREIRA-TURCQ PF, CORDEIRO RC AND TURCQ BJ. 2009. Reconstituiçăo paleoambiental do Lago Santa Ninha, Várzea do Lago Grande de Curuaí, Brasil. Acta Amazônica 39: 609-616.
NANSON GC AND KNIGHTON AD. 1996. Anabranchingrivers: their cause, character and classification. Earth Surf. Proc Land 21: 217-239.
ROSSETTI D. 2004. Paleosurfaces from northeastern Amazonia as a key for reconstructing paleolandscapes and understanding weathering products. Sed Geol 169: 151-174.
ROUBIK DW AND MORENO JE. 1991. Pollen and Spores of Barro Colorado Island. Missouri Botanical Garden, St Louis, 270 p.
SIFEDDINE A, MATIN L, TURCQ B, VOLKMER-RIBEIRO C, SOUBIES F, CORDEIRO RC AND SUGUIO K. 2001. Variations of the Amazonian rainforest environment: a sedimentologial records covering 30,000 years. Paleogeogr Paleoclimatol Paleoecol 168: 221-235.
SUGUIO K, MARIN L, BITTENCOURT AC, BITTENCOURT ACSP, DOMINGUEZ JML, FLEXOR J-M AND DE AZEVEDO AEG. 1985. Flutuaçőes do nível do mar durante o Quaternário superior ao longo do litoral brasileiro e suas aplicaçőes na sedimentaçăo costeira. Rev Bras Geoc 15: 273-286.
VAN DER HAMMEN T AND ABSY ML. 1994. Amazonia during the last glacial. Paleogeogr Paleoclimatol Paleoecol 109: 247-261.
VAN DER HAMMEN T AND HOOGHIEMSTRA H. 2000. Neogene and Quaternary history of vegetation, climate, and plant diversity in Amazonia. Quat Sci Rev 19: 725-742.
WITTMANN F, JUNK WJ AND PIEDADE MTF. 2004. The várzea forest in the Amazonia: flooding and highly dynamic geomorphology interact with natural forest succession. For Ecol and Manag 196: 199-212.

Correspondence to:

Adriana Maria Coimbra Horbe

E-mail:

ahorbe@ufam.edu.br

Publication Dates

Publication in this collection
05 Aug 2011
Date of issue
Sept 2011

History

Received
25 Nov 2009
Accepted
01 Dec 2010

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

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[16] GRIMM EC. 1987. CONISS: A Fortran 77 program for stratigraphically constrained cluster analysis by the method of the incremental sum of squares. Comp and Geosc 13: 13-35.

[17] HERRERA LF AND URREGO LE. 1996. Atlas de polen de plantas útiles y cultivadas de la Amazonia colombiana. Pollen atlas of useful and cultivated plants in the Colombian Amazon region. Estudios en la Amazonia colombiana/Studies on the Colombian Amazonia, Tropenbos Colombia, Bogotá, Vol. XI.

[18] HOOGHIEMSTRA H. 1984. Vegetational and climatic history of the high plain of Bogotá, Colombia: a continuous record of the last 3.5 million years. Dissertationes Botanicae, J. Cramer, Vaduz. (Unpublished).

[19] HOOGHIEMSTRA H AND VAN DER HAMMEN T. 1998. Neogene and Quarternary development of the neotropical rain forest: the forest refugia hypothesis, and literature overview. Earth-Sci Rev 44: 147-183.

[20] HOORN C, GUERRERO J, SARMIENTO GA, LOTENTE MA. 1995. Andean tectonic as a cause for changing drainage patterns in Miocene northern South America. Geol 23: 237-240.

[21] IRION G, BUSH MB, DE MELLO JN, STUBEN D, NEUMANN T, MULLER G, DE MORAIS JO AND JUNK JW. 2006. A multiproxi paleeoecological record of Holocene lake sediment from the Rio Tapajós, eastern Amazonia. Paleogeogr Paleoclimatol Paleoecol 240: 523-535.

[22] LATRUBESSE EM AND FRANZINELLI E. 2002. The Holocene alluvial plain of the middle Amazon River, Brazil. Geomorph 44: 241-257.

[23] MCDANIEL DK. 1998. Provenance and weathering history of Amazon sediment, Dissertation, State University of New York at Stony Brook. (Unpublished).

[24] MCDANIEL DK, MCLENNAN SM AND HANSON GN. 1997. Provenance of Amazon fan muds: constraints from Nd and Pb isotopes. Proceedings of the Ocean Drilling Program 155: 169-176.

[25] MERTES LAK, DUNNE T AND MARTINELLI LA. 1996. Channel-floodplain geomorphology along the Solimőes-Amazon River, Brazil. Geol Soc Am Bull 108: 1089-1107.

[26] MOREIRA LS, MOREIRA-TURCQ PF, CORDEIRO RC AND TURCQ BJ. 2009. Reconstituiçăo paleoambiental do Lago Santa Ninha, Várzea do Lago Grande de Curuaí, Brasil. Acta Amazônica 39: 609-616.

[27] NANSON GC AND KNIGHTON AD. 1996. Anabranchingrivers: their cause, character and classification. Earth Surf. Proc Land 21: 217-239.

[28] ROSSETTI D. 2004. Paleosurfaces from northeastern Amazonia as a key for reconstructing paleolandscapes and understanding weathering products. Sed Geol 169: 151-174.

[29] ROUBIK DW AND MORENO JE. 1991. Pollen and Spores of Barro Colorado Island. Missouri Botanical Garden, St Louis, 270 p.

[30] SIFEDDINE A, MATIN L, TURCQ B, VOLKMER-RIBEIRO C, SOUBIES F, CORDEIRO RC AND SUGUIO K. 2001. Variations of the Amazonian rainforest environment: a sedimentologial records covering 30,000 years. Paleogeogr Paleoclimatol Paleoecol 168: 221-235.

[31] SUGUIO K, MARIN L, BITTENCOURT AC, BITTENCOURT ACSP, DOMINGUEZ JML, FLEXOR J-M AND DE AZEVEDO AEG. 1985. Flutuaçőes do nível do mar durante o Quaternário superior ao longo do litoral brasileiro e suas aplicaçőes na sedimentaçăo costeira. Rev Bras Geoc 15: 273-286.

[32] VAN DER HAMMEN T AND ABSY ML. 1994. Amazonia during the last glacial. Paleogeogr Paleoclimatol Paleoecol 109: 247-261.

[33] VAN DER HAMMEN T AND HOOGHIEMSTRA H. 2000. Neogene and Quaternary history of vegetation, climate, and plant diversity in Amazonia. Quat Sci Rev 19: 725-742.

[34] WITTMANN F, JUNK WJ AND PIEDADE MTF. 2004. The várzea forest in the Amazonia: flooding and highly dynamic geomorphology interact with natural forest succession. For Ecol and Manag 196: 199-212.