The 1.88 Ga Uatumã Magmatism in the Serra dos Magalhães region: petrology and implications to the extension of the south-eastern edge of the Amazonian Craton

The Amazonian Craton (AC) is a Pre-Cambrian tectonic segment that extends over 4.3 × 10 5 km 2 at the northern portion of the South American Platform. Phanerozoic sedimentary basins cover most of the edges of the AC and sparse occurrences of Precambrian rocks may aid the definition of its extension. One of these occurrences is the volcano-plutonic rocks that outcrop in the Serra dos Magalhães region, which relates to the Uatumã Magmatism, an expressive Orosirian magmatic event that constitutes a Siliceous Large Igneous Province. Effusive rhyodacites and rhyolites comprise the volcanic unit and the plutonic counterpart consists of epizonal monzogranites. Whole-rock geochemistry indicates an A2-type granite affinity to all magmatic rocks. Contrasting signatures suggest a magmatic evolution from a single stratified magma chamber. U-Pb zircon crystallization ages are 1870 ± 11 Ma for the rhyodacites, 1879 ± 5 Ma for the monzogranites, and a slightly younger age of 1863 ± 14 Ma for the rhyolites. Interpretation of satellite and geophysical images allows the recognition of regional lineaments in the Parecis and Bananal basins that suggest the extension of the AC up to the Tucurui Fault in the eastern portion (Bananal Basin) and up to the Brasnorte High in the southern part (Parecis Basin).


INTRODUCTION
The Amazonian Craton (AC) is a Mesoarchean to Mesoproterozoic tectonic segment that extends over 4.3 × 10 5 km 2 at the northern portion of the South American Platform (Fig. 1). The north-western, western, and south-western limits make up the Andean Orogenic Belt, the southern border extends to the Neoproterozoic Paraguay Belt and the eastern and south-eastern edges prolong to the Neoproterozoic Araguaia Belt. Phanerozoic sedimentary basins cover most of the AC borders, as the Parecis, Chaco, Eastern Venezuela, and Bananal basins. The Phanerozoic Solimões-Amazonas Basin divide the Amazonian Craton into the Guyana Shield (northern part) and the Brazil Central Shield (southern portion).
The most expressive intraplate magmatic event of the AC, the Uatumã Magmatism, relates to the Uatumã Silicic Large Igneous Province (USLIP) (Klein et al. 2012) and consists of undeformed intermediate to acid volcanic rocks crosscut by cogenetic isotropic granitoids. This volcano-plutonism widespread from the northern portion of the AC to the south-eastern region. Well-known occurrences concentrate in the Pitinga Mining District, Presidente Figueiredo, and Erepecuru-Trombetas region (Guyana Shield), and in the Tapajós and Carajás mineral provinces, São Félix do Xingu and Confresa region (Brazil Central Shield) (Fig. 2). The volcanic rocks include effusive and hypabyssal andesites, dacites, trachytes, and rhyolites, beside ignimbrites, surge and ash-fall tuffs, and sedimentary volcanogenic rocks. The cogenetic granitoids comprise subvolcanic batholiths and stocks of coarse-to fine-grained monzogranites and syenogranites. Geochemical data indicate an I-to A-type affinity to the volcanic rocks and A-type to the granitoids. U-Pb crystallization ages range from 1.90 to 1.87 Ga (Dall' Agnol et al. 1999, Costi et al. 2000, Lamarão et al. 2002, Santos et al. 2004, Teixeira et al. 2005, Valério et al. 2009, Ferron et al. 2010, Pierosan et al. 2011, Barros et al. 2011, Fernandes et al. 2011, Rocha et al. 2012, Barreto et al. 2014, Tarelow Neto et al. 2017. Paleo-to Mesoproterozoic siliciclastic sedimentary rocks partially cover the USLIP and relate to the Gorotire Formation and Rio Fresco Group (Vasquez and Rosa-Costa 2008). The Phanerozoic sedimentary basins that cover most of the AC borders preclude an accurate definition of its limits. Thus, sparse occurrences of inliers amid the sedimentary basins play a key role to prescribe the extension of the AC edges. In this scenario, the present work deals with the geological investigation (field and petrographic information, whole-rock geochemistry, and U-Pb zircon isotopes) of the Serra dos Magalhães region that allows the determination of their petrological characteristics, aiming an appropriate correlation to the known occurrences within the AC. Moreover, this correlation supports meaningful considerations concerning the AC limits and its geotectonic implication to the South American Platform evolution.

GEOTECTONIC CONTEXT
The Tassinari and Macambira (1999) and Santos et al. (2000) models and further updates focus on the Brazilian part of the Amazonian Craton and describe, generically, the Archean nuclei followed by the successive magmatic arc and accretionary events whose ages decrease from the north-eastern to the south-western portion. Vasquez and Rosa-Costa (2008) presented a model based on the Santos (2003) update that improves the description and interpretation of the geotectonic evolution of the central and south-eastern regions of the AC. This model defines new domains within some provinces and refines the limits of the south-eastern area.
The south-eastern portion of the Amazonian Craton, according to Vasquez and Rosa-Costa (2008), consists of Archean crustal segments included in the Carajás Province (Rio Maria and Carajás domains). The structural and metamorphic aspects of these domains indicate that the Transamazonian Cycle Source: adapted from Lacerda Filho et al. (2004), Reis et al. (2006) and Vasquez and Rosa-Costa (2008). (2.26 to 1.95 Ga) did not affect these rocks. On the other hand, the Archean crustal segments reworked by the Transamazonian Cycle and the Paleoproterozoic juvenile rocks generated during this orogenic cycle integrate the Transamazonian Province. The Transamazonian Province is divided into the Amapá Block and the Bacajá, Carecuru, and Paru domains, in the eastern part, and in the Santana do Araguaia Domain in the south-eastern portion.
The Santana do Araguaia Domain includes Neoarchean metavolcanossedimentary sequences and granite-gneiss-migmatite associations, and Rhyacian pre-collisional granitoids. Posttectonic Orosirian granitoids crosscut the older units and intracratonic sedimentary basins cover part of the domain. The Neoarchean metavolcanossedimentary sequences relate to greenstone belts, from which Pb-Pb zircon data of detrital grains show a youngest age of 2833 ± 7 (Monteiro et al. 2004), interpreted as the maximum sedimentation age. The Santana do Araguaia Complex and the Rio Campo Alegre Orthogneiss comprise the Archean granite-gneiss-migmatite associations and show Pb-Pb zircon protolith ages from 3066 ± 3 to 2828 ± 21 Ma (Alves et al. 2010, Vasquez and Rosa-Costa 2008, Corrêa and Macambira 2014, Ribeiro and Alves 2017. The Pb-Pb zircon crystallization age of the Rio Dezoito Tonalite of 2187 ± 28 Ma (Vasquez and Rosa-Costa 2008) and the structural and lithological aspects of this unit suggest that the Rhyacian granitoids relate to the pre-collisional stage of the Transamazonian Cycle. Post-collisional magmatism relates to the volcano-plutonic association of the Jarinã Formation and the Vila Rica Intrusive Suite, respectively (Lacerda Filho et al. 2004, Alves et al. 2010, Ribeiro and Alves 2017. The crystallization ages of the Jarinã Formation vary from 2009 ± 9 to 1987 ± 14 Ma and of the Vila Rica Intrusive Suite from 1995 ± 14 to 1968 ± 2 Ma (Padilha et al. 2007, Barros et al. 2008, Alves et al. 2010, Ribeiro and Alves 2017, Braga et al. 2020.
The Central Amazonian Province represents one of the most poorly known areas of the AC, mainly due to the dense rainforest cover and several biological and indigenous reserves. The basement rocks consist of schists, para-and orthogneisses, and migmatitic gneisses with leucossome ages from 2155 ± 8 to 1983 ± 5 Ma, protolith age of 1990 ± 3 Ma, and inherited age of 2160 ± 8 Ma (Vasquez et al. 2019). The volcano-plutonic event of the USLIP concentrates in the Central Amazonian Province and spread throughout the Tapajós-Parima, Transamazonian, and Carajás provinces. In the south-eastern region of the AC, the volcanic rocks comprise intermediate to acid effusive and pyroclastic lithotypes of I-to A-type affinity and crystallization from 1896 ± 5 to 1865 ± 5 Ma (Rocha et al. 2012, Tarelow Neto et al. 2017, Vasquez and Rosa-Costa 2008. The Rio Dourado Intrusive Suite groups the granitoids in the south-eastern of the AC, which essentially show A-type signature and ages that range from 1891 ± 3 to 1864 ± 5 Ma (Alves et al. 2010, Barros et al. 2005, Pinho et al. 2004.
The Tapajós-Parima Province occurs in the central portion of the AC, as defined by Santos et al. (2000) and Santos et al. (2004), and includes successive magmatic arcs developed between 2.10 and 1.87 Ga. These arcs associate to metavolcanossedimentary sequences of the Jacareacanga Group with ages of deposition around 2.1 Ga and metamorphic rocks of the Cuiú-Cuiú Complex of U-Pb zircon protolith ages from 2033 ± 7 to 2005 ± 7 Ma (Klein et al. 2001, Santos et al. 2001, Vasquez et al. 2013). An isotropic volcano-plutonic association (Vila Riozinho Formation and correlated volcanic rocks and Creporizão Intrusive Suite and correlated granitoids) shows shoshonitic to I-type signatures, respectively, and U-Pb zircon crystallization ages from 2002 ± 4 to 1955 ± 4 Ma (Lamarão et al. 2002, Santos et al. 2001, Santos et al. 2004, Vasquez et al. 2000, 2013, Cassini et al. 2020. Extensive sedimentary rocks cover older units of the Carajás, Transamazonian, Tapajós-Parima, and Central Amazonian provinces. In the south-eastern portion, they are related to the Gorotire Formation and Rio Fresco Group (Vasquez and Rosa-Costa 2008). Cunha et al. (1981) indicate a maximum sedimentation age of 1.88 Ga for the sedimentary rocks of the Gorotire Formation. However, Alves et al. (2010) assume, based on stromatolites levels, a deposition period between 1.96 and 1.88 Ga, and group the sedimentary rocks in the Cubencranquém Formation. The lack of provenance studies, mainly of U-Pb zircon data, hinder a better definition of these sedimentary rocks.
The Mesozoic sedimentary Parecis Basin covers the central-south edge of the Amazonian Craton and consists of an Upper Cretaceous sequence, named Rio Tapirapé Formation by Rubert et al. (2017Rubert et al. ( , 2019, which comprises one restrict intracontinental lacustrine and deltaic-fluvial sequence. The bottom layer records a chemical and low energy clastic sedimentation of mudstones, marls and limestones, siltstones, and fine sandstones, that relates to a lacustre and marine environment in a context of fast initial subsidence and low sedimentation rate in the base of the package. Laminated siltstones and massive to stratified sandstones and conglomerates overlay the bottom package and are comprised of a prodelta and deltaic progradation environment that become dominant to the top of the package. Massive to laminated sandstones and mudstones compose the top of the sequence and relate to fluvial, alluvial plain, and aeolian deposition. The south-eastern border of the Amazonian Craton is covered by the Parecis Basin, composed by Cenozoic packages of Paleogene of the Ronuro Formation that records the reworking of the Cretaceous sedimentary sequence and consists of packages of unconsolidated sediments as silts, sands, and gravel interbedded with laterite levels (Alves et al. 2010). The Neogene Araguaia Formation (Barbosa et al. 1966) belongs to the Bananal Basin, which also covers the south-eastern border of the Amazonian Craton, and comprises partially unconsolidated conglomerates at the bottom, covered by sands, silts, and clays of low selection and related to terraces and abandoned channels of fluvial systems. Valente (2007) relates this unit to the Pleistocene period.

MATERIALS AND METHODS
Seventeen outcrops were identified and described in the Serra dos Magalhães region during two field trips. Representative samples of the different lithotypes were collected for petrographic, geochemical, and geochronological studies. The thin section preparation and petrographic studies followed conventional procedures and were performed at the Geoscience Faculty labs of Universidade Federal do Mato Grosso (FAGEO/UFMT), Brazil.
Ten samples were crushed and powdered in a jaw crusher and disc mill at the FAGEO/UFMT. The commercial lab Acmelab performed the geochemical analysis by Inductively Coupled Plasma-Atomic Emission Spectrometry (ICP-AES) for major and minor elements and Inductively Coupled Plasma-Mass Spectrometry (ICP-MS) for trace elements, including rare earth elements (REE). The quality control report of the Acmelab included two analyses of the SO-18 standard, one blank, and two sample duplicates. All results are within the expected error. Temperature calculations were run through the model of Hanchar and Watson (2003). Rheological data were calculated according to the Giordano et al. (2008) model. Best-fit of viscosity and glass transition temperature data versus estimated water content were run through nonlinear curve by an exponential decay with 2 degrees of freedom.
Three samples were crushed and sieved to 250, 210, 177, 125, 90, and 63 mesh fractions to select zircon grains for the U-Pb geochronological analysis. Fractions of 90 and 63 mesh were selected for magnetic and density zircon separation. Around 100 zircon grains were hand-picked from each sample. Geochronological analyses of samples DI-14a and DI-17a were performed at the Geochronological Research Centre of Universidade de São Paulo (CPGeo/USP), Brazil, where the isotopic U-Pb ratios were obtained through LA-ICP-MS using a Neptune instrument from Thermo Finnigan. The instrument's parameters consisted of a ratio frequency of 1,100 W, Ar gas flow rates of 15 L/min (cool), 0.7 L/min (auxiliary), and 0.6 L/min (sample). The excimer laser had an energy of 6 mJ at a repetition rate of 6 Hz and a spot size of 32 μm. Collectors positions consisted of IC3: 202 Hg, IC4: 204 Pb, L4: 206 Pb, IC6: 207 Pb, L3: 208 Pb, H2: 232 Th, H4: 238 U, and C: virtual mass. The U-Pb analysis sequence was of 2 blanks, 2 NIST standard glass, 3 external standards (GJ1), 13 unknown samples (zircon), 2 NIST standard glass, 2 external standards (GJ1) and 2 blanks. GJ1 external standard has a reference age of 608.5 ± 0.4 Ma ( Jackson et al. 2004) and yielded an age of 602.2 ± 0.9 Ma. Two sequences were performed for each sample, totalizing 26 analyzed zircon grains. Each zircon grain was analyzed by 40 cycles of 1s/cycle. 202 Hg was used to correct the 204 Hg interference in 204 Pb. The common Pb was subsequently corrected using the 204 Pb method with a composition taken from the model of Stacey and Kramers (1975). The sample DI-10a was analyzed by the ionic microprobe SHRIMP II of the geochronology lab of the Curtin University, Perth, Australia. The analytical methodology followed the parameters described by Williams (1998). The following masses were analyzed in the zircons: 196 Zr 2 O, 204 Pb, background, 206 Pb, 207 Pb, 208 Pb, 238 U, 248 ThO, 254 UO. Calibration was performed using the M257 zircon reference material (561.3 Ma). Common lead correction was run by counting the 204 Pb. The international reference material BR-266, which 206 Pb/ 238 U age is of 559 Ma, was used for calculation correction. The diagrams and ages were calculated using the Isoplot 4 software by Ludwig (2012).

Field aspects and petrography
The study area consists of an inlier of volcanic (Iriri Group), granitic (Rio Dourado Intrusive Suite), and sedimentary rocks (Gorotire Formation), surrounded and partially covered by recent alluvial deposits and terraces (Araguaia Formation) (Fig. 3). Volcanic rocks outcrop in the western portion of the study area and form the geomorphological highs of the Serra dos Magalhães. Granitic and sedimentary rocks outcrop at around 25 km from the Serra dos Magalhães region, in the northeast region of the study area. The basement of the volcanic and sedimentary rocks and the country rocks of the granitoids do not outcrop. Alluvial deposits and terraces cover most of the study area.
Outcrops of all units are rare and sparse and consist of boulders, blocks, and subordinate flooring outcrop of fresh to weakly weathered volcanic and granitic rocks and strongly weathered sedimentary rocks amid regolithic soils and alluvial deposits. The limits of the volcanic rocks were identified by relief and satellite images analysis allied to the occurrence of outcrops of the alluvial deposits. The limits of the granitic body were kept as those established by Cunha et al. (1981) due to the lack of continuous outcrops or relief and satellite image features that allowed a better delimitation. Figure 3 presents the geological map generated by this work and the geological section from its interpretation.
Based on field and petrographic observations, three volcanic lithotypes, one granitic, and one sedimentary were recognized. Volcanic rocks comprise massive rhyodacite, massive rhyolite, and flow-banded rhyolite. The granitoid consists of porphyritic monzogranite and the sedimentary rocks are a polymictic conglomerate.
Plagioclase is the most abundant phenocryst, comprises around 50 modal%, and is subhedral to euhedral, with sizes from 0.3 to 2.0 mm (Fig. 4C). Alkali-feldspar (around 10 modal%) shows subhedral to euhedral habit and size from 0.5 to 2.5 mm. Carlsbad twinning occurs locally. Quartz sums 20% of the phenocrysts, ranges from 0.2 to 3.5 mm, and is subhedral to euhedral with bipyramidal forms and common embayments. Hornblende is subhedral to anhedral, comprises around 20% of the phenocrysts and ranges from 0.3 to 1.5 mm (Fig. 4D). The pleochroism varies from medium green to light brown color. Pseudomorphs of chlorite+epidote partially to completely replace the hornblende. Apatite, zircon, and opaque minerals are present in the groundmass as accessory minerals. Subsolidus alteration minerals are subordinate, distribute pervasively through the groundmass, and mostly replace phenocrysts. They consist of chlorite and epidote as replacement

Massive rhyolites (Iriri Group)
Massive rhyolites are of light grey to light red color, holocrystalline, and porphyritic with around 25 modal percent of alkali-feldspar, quartz, and plagioclase phenocrysts in crypto-to microcrystalline aphanitic and quartz-feldspathic groundmass (Figs. 5A and 5B). Phenocrysts are dominantly subhedral to euhedral and crystal fragments are subordinate.
Alkali-feldspar phenocrysts are subhedral, of prismatic to round habit and with 0.2 to 4.0 mm. They show the common film to chessboard perthites (Fig. 5C) and less Carlsbad twinning and compose around 45% of the phenocrysts. Quartz phenocrysts are anhedral to subhedral of short prism to rounded forms with recurrent embayments. They vary from 0.2 to 3.5 mm and comprise around 45% of the phenocrysts. Plagioclase consists of subhedral to euhedral prismatic phenocrysts with characteristic polysynthetic twinning, varying from 0.3 to 2.0 mm and amounts of 10%. A jigsaw texture occurs locally and consists of fragments of quartz and feldspars phenocrysts with microscopic dislocation of the fragments filled by a thin portion of groundmass (Fig. 5D). This feature frequently associates with the recurrent embayments of  the quartz phenocrysts. Accessory minerals are comprised of common subhedral to euhedral prismatic zircon, frequently metamict, anhedral opaque minerals, and rare subhedral prismatic apatite. Subsolidus minerals are subordinate, distribute in the groundmass, and replace the phenocrysts. White mica is the main alteration of plagioclase along with calcite, epidote partially replaces the alkali-feldspar and opaque minerals pervasively distribute throughout the groundmass.

Flow-banded rhyolites (Iriri Group)
The flow-banded rhyolites are of grey to dark grey color, hypocrystalline, porphyritic and contain around 10 modal% of alkali-feldspar, quartz, and plagioclase phenocrysts in a cryptocrystalline aphanitic to glassy groundmass (Figs. 6A and 6B). Phenocrysts are subhedral to euhedral and fragmented terminations are common.
Quartz phenocrysts are subhedral to euhedral with bipyramidal forms and common embayments. They vary from 0.2 to 1.5 mm and comprise around 50% of the phenocrysts. Alkali-feldspar phenocrysts are dominantly subhedral, show Carlsbad twinning in some crystals, compose around 45% of the phenocrysts, and range from 0.5 to 2.0 mm. Plagioclase is euhedral to subhedral, from 0.5 to 1.8 mm, and consists of less than 5.0% of the phenocrysts. Subhedral prismatic zircon is the only accessory mineral observed. Groundmass displays a prominent flow foliation marked by the regular alternation of millimetric layers of different crystallinity degree since glassy to crypto-and microcrystalline. Flow foliation is a dominantly planar structure and locally depicts open to convolute folds (Fig. 6C), sometimes outlining phenocrysts. The glassy portion of the groundmass presents isolated and aggregated spherulites of millimetric size with radial morphology of quartz and feldspars microlites and crystallites (Fig. 6D). Micropoikilitic texture is subordinate and consists of acicular microlites of quartz enclosing granular microlites of feldspars. Calcite, epidote, and white mica are rare, sparsely distribute throughout the groundmass, and partially replace feldspars.
Alkali-feldspar is subhedral to rarely euhedral and usually varies from 1.5 to 4.0 mm. Megacrysts of alkali-feldspar randomly distribute through the rock and range from 0.7 to 3.5 cm. The poikilitic texture is common and consists of < 1.0 mm crystals inclusions of euhedral to subhedral plagioclase, hornblende and biotite, and anhedral quartz, within the alkali-feldspar grains (Fig. 7B). Perthitic intergrowths are subordinate and comprise thin films of exsolved albite. Rapakivi texture occurs locally and characterizes as a millimetric sized mantle of plagioclase enveloping the alkali-feldspar crystals. Plagioclase crystals are subhedral to euhedral of tabular forms, with characteristic polysynthetic twinning and size between 0.5 and 4.0 mm. Quartz is dominantly anhedral interstitial and varies from 0.25 to 2.5 mm. Hornblende show light to dark green pleochroism, subhedral forms, and range from 0.3 to 2.0 mm (Fig. 7C). Biotite shows a characteristic lamellar habit with subhedral to euhedral forms and width from 0.4 to 2.0 mm (Fig. 7D). Biotite pleochroism varies from light green to brown color. Mafic and accessory minerals, mainly opaque minerals, frequently occur as aggregates of up to 1.0 cm. Accessory minerals consist of anhedral titanite, subhedral to anhedral opaque minerals, subhedral prismatic zircon, and subhedral to euhedral apatite with a short prism to acicular habit. Subsolidus phases are scarce and comprise of chlorite, which locally replaces hornblende and biotite crystals as pseudomorphs, and white mica and rare epidote that usually associates to feldspars.

WHOLE-ROCK GEOCHEMISTRY
Whole-rock geochemical data of three massive rhyodacites, four massive rhyolites, one flow-banded rhyolite, and two porphyritic monzogranites are reported in Table 1. SiO 2 content of the massive rhyodacites is around 65wt. % and are similar to the silica content of the porphyritic monzogranites (65.62 and 68.55wt. %), whereas the rhyolites show higher values, from 74.91 to 81.53wt. %. Binary diagrams of major, minor, and trace elements demonstrate higher values of Al 2 O 3 , FeO t , MgO, CaO, TiO 2 , P 2 O 5 , Ba, Sr, Zr, and Eu in the massive rhyodacites and the porphyritic monzogranite compared with the flow-banded and the massive rhyolites. Exceptions are the Ba, Zr, and Eu content of the flow-banded rhyolites that are higher than the massive ones. K 2 O, Rb, Nb, Th, and Yb are higher in the rhyolites than in other lithotypes, except the Th content of the flow-banded rhyolite (Fig. 8). The element distribution in the binary diagrams indicates similarities between massive rhyodacites and porphyritic monzogranite that contrast to the rhyolites. There are no positive or negative correlations among the different lithotypes. These features suggest that they preferably evolved from distinct batches of magma rather than by crystal fractional crystallization and/ or magma mixing processes.
The spidergram of major and trace elements normalized to the Thompson (1982) chondrite demonstrates a decrease in elements content with the compatibility increase, from Rb to Yb. All lithotypes show negative anomalies of Ba, Nb, Ta, Sr, P, and Ti. However, Sr, P, and Ti negative anomalies are smaller in the massive rhyodacites and porphyritic monzogranite than in the rhyolites (Fig. 9A). The spidergram of REE normalized to the Boynton (1984) chondrite illustrates the higher REE contents, except Eu, of the flow-banded and massive rhyolites, compared with the massive rhyodacites and the porphyritic monzogranites. Eu negative anomaly is strong in    the massive rhyolites, moderate in flow-banded rhyolite and slight in massive rhyodacites and porphyritic monzogranites. Both spidergrams evidence the strict similarity between the massive rhyodacites and the porphyritic monzogranites and the lack of transitional features from these lithotypes to the rhyolites (Fig. 9B). The geochemical classification of volcanic rocks, mainly based on immobile major and trace elements, corroborates the petrographic individualization of rhyodacites and rhyolites and indicates the corresponding field of the granitoids to the porphyritic monzogranite (Figs. 10A and 10B). The diagrams by Frost et al. (2001) point out to the metaluminous character of the porphyritic monzogranites and the flow-banded rhyolite, the metaluminous to the slightly peraluminous signature of the massive rhyodacites and the slightly peraluminous of the massive rhyolites (Fig. 10C). Moreover, the diagram of Figure 10D shows the affinity of all lithotypes with the ferroan magmas, since the geochemical terminology of granitoid applies to silicic volcanic rocks. Ferroan magmas usually present strict correlation to the A-type granites (or silicic volcanic rocks) of Loiselle and Wones (1979) as the Whalen et al. (1987) diagrams demonstrate (Figs. 11A and 11B). The Eby (1992) division of A-type granites indicates that all studied lithotypes correspond to magmas of A2-type signature (Fig. 11C). Eby (1992) discusses that the A2-type granites can represent magmas that originate from partial remelting of the lithosphere that has undergone a previous melting process or forms partial melting of continental crust.

RHEOLOGY OF VOLCANIC ROCKS
Rheological information from geochemical data were obtained through the Hanchar and Watson (2003) and Giordano et al. (2008) models (see section Materials and Methods for details) and allows meaningful interpretation concerning the emplacement of volcanic rocks. Zircon saturation temperature approximates the magma liquidus temperature since zircon is usually an early mineral to crystallize in the magma history. Massive rhyodacites present a mean zircon saturation temperature of 800°C, lower than the rhyolites average (831°C).
The viscosity calculation of each rock considers the assumed magma liquidus temperatures to estimate the viscosity data in dry and wet (1 to 4% of H 2 O) conditions. Viscosity in the dry condition is lower in the massive rhyodacites and the flow-banded rhyolite, from 9.74 to 10.37 log η Pa s and of 9.90 log η Pa s, respectively. The massive rhyolites show higher values that range from 10.30 to 11.57 log η Pa s. The increase in H 2 O estimation exponentially decreases viscosity, down to around 5.00 log η Pa s in massive rhyodacites and flow-banded rhyolite, and from 5.28 to 6.09 log η Pa s in massive rhyolites (Figs. 12A and 12B).
Estimated glass transition temperatures in dry conditions are of around 995°C in massive rhyodacites, 1,015°C in flowbanded rhyolite, and range from 1,037 to 1,072°C in massive rhyolites. Similarly, the glass transition temperatures exponentially decrease with the H 2 O input (Figs. 12C and 12D). However, the reduction is more effective in the rhyolitesdown to 670°C in flow-banded rhyolites and around 685°C in massive ones -than in the massive rhyodacites (~690°C).
The results of 9 grains of the DI-010a sample show Th/U ratios ranging from 0.49 to 1.38 and low common Pb contents that vary from 0.04 to 0.44%. The geochronological calculation allows the determination of a concordia age at 2σ of 1870 ± 11 Ma, representing the crystallization age of the massive rhyodacites. Mean-squared weighted deviates (MSWD) of concordance is 0.063 (Fig. 13).
Zircon grains of the DI17a sample are euhedral to subhedral with rare fragmented terminations. The size ranges from 110 to 220 μm and the internal structure show translucent crystals with prominent internal oscillatory zoning and rare inherited cores. The common Pb contents of 21 grains are low and vary from 0.13 to 1.05%. These zircon grains also present low to high Th/U ratios, from 0.52 to 1.69. Most apparent ages are strongly concordant and allow the statistical calculation of an intercept at 1879 ± 5 Ma at 2σ, which represents the crystallization age of the porphyritic monzogranites. MSWD of concordance is 0.78 (Fig. 14).
Zircon grains of the DI14a sample are euhedral to subhedral with frequent fragmented terminations and size from 90 to 150 μm. The internal structure reveals a frequent oscillatory zoning and rare inherited cores. Most of the grains are metamict. Crystals sizes are from 90 to 150 μm, Th/U ratios    and common Pb contents are low and range from 0.44 to 0.75 and 0.08 to 1.08%, respectively. Most of the zircon grains are positively discordant due to the relative uranium gain during the metamictization process. According to Andersen et al. (2019) and references therein, redistribution of uranium and lead within zircon grains can occur in crystals that undergone radiation damage, as metamictization, mainly under tropical weathering. Statistical regression yields an intercept at 1863 ± 14 Ma at 2σ, interpreted as crystallization age of the rhyolites. MSWD of concordance is 0.38 (Fig. 15).
The main internal characteristic of the zircon crystals of all samples is the prominent oscillatory zoning. Corfu et al. (2003) point out that the well-developed growth zoning is the more typical feature of magmatic zircon. Moreover, the low to high Th/U ratios are also characteristic of zircon grains of igneous origin (Belousova et al. 2002, Kirkland et al. 2015.

Petrology
The volcanic rocks of the Serra dos Magalhães region present porphyritic texture with dominantly subhedral to euhedral phenocrysts with common embayments and subordinate crystals fragments. The amount of phenocryst fragments in volcanic rocks, as pointed out by Allen and McPhie (2003), may indicate the eruption nature. These authors suggest that the fragmentation of phenocrysts occurs along zones of internal weakness created by the expansion of melt inclusions due to the increased internal pressure caused by decompression during ascent. Moreover, these authors assume that the amount of feldspars and quartz fragments rarely exceed 12% in lavas, even in those with phenocrysts content of up to 28 modal%. The groundmass is holocrystalline aphanitic to hypocrystalline with abundant microlites and crystallites. Lithic and glassy fragments are absent. These features, as presented in Figures 4, 5 and 6, corroborate to the effusive nature of the original eruptions that generated the rhyodacitic and rhyolitic lava flows of the Serra dos Magalhães region.
The subhedral alkali-feldspar megacrysts with abundant xenomorphic quartz inclusions in the porphyritic monzogranites, allied to the xenomorphic quartz crystals of the medium-grained matrix, as presented in Figure 7, suggest a late stage of crystallization for both phases. The common subhedral to euhedral alkali-feldspar crystals of the matrix indicate the presence of several nuclei during the early stage of crystallization, attesting high nucleation (N) rates of the alkali-feldspar. Reduced nucleation rate and elevated growth rate (G) at a low degree of undercooling at the early stage of crystallization do not properly explain the origin of this feature, as suggested by Swanson (1977) and expected for porphyritic volcanic and subvolcanic systems. Higgins (1999) assumes the presence of alkali-feldspar megacrysts as the result of textural coarsening (or Ostwald ripening) of small and early formed crystals during a late magmatic stage of the pluton crystallization. According to the author, the undercooling buffers near the liquidus of the alkali-feldspar for a long period so that the texture becomes coarsened.
The geochemical signature of the volcanic rocks indicates an intrinsic relation of the massive rhyodacites to the porphyritic monzogranites, with similar contents of major, minor, and trace elements (Fig. 9A), including REE (Fig. 9B). Differently, the geochemical character of massive and flow-banded rhyolites contrasts with the other lithotypes and shows an evolved pattern with higher incompatible elements and high rare earth elements (HREE) content. Binary diagrams show a distribution pattern of distinct poles and no curvilinear correlation among the different rocks. These characteristics suggest a magmatic origin of different batches of melt from a single magmatic source, due to the intrinsically similar geochemical features, whose rhyodacites and monzogranites slightly predated the rhyolites.
Rheological information of the volcanic rocks of the Serra dos Magalhães region indicates high liquidus temperature, usually > 800°C, high viscosity, and glass transition temperature at dry conditions, which both significantly decreased with the water increment. According to Dingwell and Webb (1990), the glass transition of a silicate melt is the phenomenon that marks a shift of the magma dynamics from a crystal-like to a liquid-like behavior. This propriety is temperature-dependent and indicates that above the glass transition temperature the dynamics of a silicate melt are of a true liquid (viscous system), whereas below the glass transition temperature the melt dynamics are solid (elastic system). The model of Giordano et al. (2008) demonstrates that the glass transition temperature is also H 2 O-dependent. This dynamic behavior of silicate melts, defined by the glass transition, is fundamental to the understanding of eruptional processes, where a viscous system (i.e., liquid behavior) favors an effusive eruption, and an elastic system (i.e., solid behavior) supports a pyroclastic eruption. Rhyodacites and rhyolites of the Serra dos Magalhães region are effusive volcanic rocks formed by subaerial lava flows. The calculated glass transition temperature and its variation with H 2 O allow interpreting the dynamics of the magmatic flow of rhyodacites and rhyolites. Assuming the zircon saturation temperature as the true magma temperature of rhyodacites and rhyolites and comparing the variation of the calculated glass transition temperature with the water increment (Figs. 12C and 12D), it is possible to suggest that the rhyodacite and rhyolite magma hosted H 2 O content as high as 1.5 and 1.8 wt. %, respectively. Water content higher than these values decrease the viscosity (Figs. 12A and 12B) and the glass transition temperature of rhyodacites and rhyolites below the magma temperature and thus attribute a viscous behavior (i.e., lava flow) rather than an elastic one that favors pyroclastic eruption.

Geotectonic implications
Several authors present interpretations of the geotectonic setting of Uatumã Magmatism emplacement. In the Pitinga and Presidente Figueiredo region, the tectonic setting of the volcano-plutonism of the Uatumã Magmatism is interpreted as related to the post-collisional setting (Valério et al. 2009, Ferron et al. 2010, Pierosan et al. 2011). In the Tapajós Mineral Province, Lamarão et al. (2002) relate the tectonic setting of the Uatumã Magmatism to an intracontinental taphrogenetic event, similarly to the initial assumptions of Dall' Agnol et al. (1994) to the extensive magmatism in the Central Amazonian Province and of Dall' Agnol et al. (1999) to the granitoids of the Carajás Mineral Province region. On the other hand, Cassini et al. (2020) assume that the first pulses of the Iriri Group in the Tapajós Mineral Province are synchronous with the Parauari Intrusive Suite relate to slab break off processes that promote astenospheric upwelling, followed by the emplacement of the Maloquinha Intrusive Suite and Iriri volcanic rocks in an early-anorogenic setting. Fernandes et al. (2006Fernandes et al. ( , 2011, in the São Félix do Xingu region, indicate that the Iriri Group volcanic rocks and related granitoids emplaced through the transition from the latest stage of an Andean-type subduction event to the earliest stage of a dominantly extensional setting of a continental rift. In the southeastern of the Amazonian Craton, Rocha et al. (2012) indicate that the tectonic setting of the Iriri Group relates to the melting of lithospheric mantle previously modified by subduction events. Barros et al. (2008) interpret the tectonic setting of the Rio Dourado Intrusive Suite emplacement, as well as the associated felsic volcanism of the Iriri Group, as related to a post-collisional to anorogenic setting.
Petrographic, geochemical, and geochronological information of the volcanic and granitic rocks of the Serra dos Magalhães region indicate a lithostratigraphic correlation to the units of the Amazonian Craton, as the Iriri Group and the Rio Dourado Intrusive Suite, respectively. Since Cenozoic and recent alluvial deposits partially cover the Paleoproterozoic volcanic and granitic rocks occurrences, the area represents an inlier of the Amazonian Craton and implies in the presence of a Paleoproterozoic (or Archean) basement underlying parts of the Bananal Basin. Regional lineaments, mainly identified from satellite images and geophysical investigations, like those presented by Bahia et al. (2007) and Faria (2015), suggest that the eastern edge of the Amazonian Craton extends as far as the NNW Tucurui Fault in the Araguaia River. Similarly, the Amazonian Craton southern edge underlies most of the north-eastern part of the Parecis Basin and prolongs up to the lineaments that limit the Brasnorte High and the Pimenta Bueno Graben (Fig. 16).

CONCLUSIONS
Petrologic features of the three volcanic lithotypes indicate at least three eruptive events of effusive character: a less evolved and moderately crystallized (massive rhyodacites) and two evolved and poorly crystallized (massive rhyolites and flowbanded rhyolites). The intrusive event that generates the porphyritic monzogranite underwent a particular crystallization history with typical N/G rate at low to medium undercooling, during its initial stage, and an increasing undercooling at its late stage, promoting the textural coarsening of alkali-feldspar megacrysts. Rhyodacites and monzogranites strongly correlate with one another in terms of geochemical data and show a less evolved ferroan A2-type signature. Geochronological data of these two units present similar crystallization ages. Flow-banded rhyolites share some geochemical similarity to the rhyodacites and monzogranites. The geochemical affinity of massive rhyolites fits a more evolved ferroan A2-type and the crystallization age is slightly younger than the rhyodacites and monzogranites. All lithotypes are comagmatic and contemporaneous and evolved from distinct batches of magma from a single stratified magma chamber.
These Paleoproterozoic volcanic and granitic rocks outcrop amid alluvial deposits, correlate to the known occurrences of the volcano-plutonic association of the Uatumã Magmatism, and point out to the existence of a Paleoproterozoic or Archean basement underlying the Cenozoic sedimentary deposits. This implies the extension of the Amazonian Craton to south-eastern of the assumed region, underlying significant parts of the Parecis and Bananal basins.

ACKNOWLEDGMENTS
This work was supported by Universidade Federal do Mato Grosso (UFMT), as field logistic support and sample and thin section preparation, and by the National Council of Scientific and Technological Development (CNPq -project No. 481327/2013-4), for financial support. The personal grants of I.F. Lima and D.I.A. Okuno were supported by the Coordination of Superior Level Staff Improvement (CAPES) and by the PROPeq/UFMT, respectively. Authors also thank the meaningful contributions of the two anonymous reviewers to the improvement of the manuscript.