Injection of enriched lithospheric mantle magmas explains the formation of microgranular enclaves in the Rio Jacaré Batholith, Borborema Province, Brazil

The Rio Jacaré Batholith (RJB; 617 ± 4 Ma) is inserted in the Poço Redondo Domain, Sergipano Orogenic System. This batholith is formed by monzodiorite, quartz monzodiorite, monzonite, and quartz monzonite, with abundant microgranular enclaves (MEs). The MEs vary from black to light gray and exhibit globular to slightly elongated shapes with clear-cut, crenulated, and cuspate, or, more rarely, diffuse contacts. They correspond to diorites, monzodiorites, quartz monzodiorites, and monzonites, and textural features indicate mixing of magmas, such as compositional zoning in plagioclase, inclusion zones in plagioclase phenocrysts, poikilitic alkali feldspar, acicular apatite, and ocellar quartz. Calculations of linear correlations of major elements showed that the smallest fraction of mafic magma involved in the mixing was 0.43. MEs represent the breakdown and cooling of a mafic magma that was injected into a cooler felsic magmatic chamber. Emplacement of this mafic magma occurred at different stages of crystallization of the RJB magmatic chamber. The MEs are magnesian and metaluminous, with affinity to the shoshonitic series. Ratios for Ba/Nb (> 23), Ba/La (> 15), and Nb/La (0.22–0.69) are characteristic of magmas generated from partial melting of an enriched lithospheric mantle source. Batch melting modeling suggests that source melting rates of less than 3% are necessary to generate magmas similar to those of the RJB MEs.

MEs are the most common types of inclusions in granitic bodies (Barbarin and Didier 1991) and are considered to be one of the keys to understanding the genesis and evolution of granites (Didier 1973, Barbarin and Didier 1991, Sarjoughian et al. 2017).
Some authors consider the presence of MEs with cooled edges and xenocrysts in granites as evidence of the coexistence of magmas with different viscosities (e.g., Vernon 1984, Kumar and Rino 2006, Siuda and Bagiński 2019).The rocks formed have characteristic textures (e.g., rapakivi texture, ocellar quartz, inclusion zones in phenocrysts, compositional zoning in plagioclase, and biotite blades) that indicate the actions of mingling between magmas (Hibbard 1991).Geochemical data can also preserve evidence of mixing; the mixing can cause, for example, the predominance of intermediate compositions, resulting from the mixture of basic and acid magmas, and linear trends in Harker-type diagrams (e.g., Nardi and Lima 2000, Reubi and Blundy 2009, Ruprecht et al. 2012, Kumar et al. 2017).
In the Sergipano Orogenic System (SOS; Conceição et al. 2016), there is evidence of voluminous Neoproterozoic plutonism that has been the target of several studies over the last few decades (e.g., Santos and Souza 1988, Davison and Santos 1989, Santos et al. 2001, Bueno et al. 2009, Oliveira 2014, Oliveira et al. 2015, Conceição et al. 2016, Fontes et al. 2018, Lisboa et al. 2019, Pinho Neto et al. 2019, Santos et al. 2019, Sousa et al. 2019, Fernandes et al. 2020).Many of these studies identified the presence of MEs in these intrusions; however geological, petrographic, and geochemical data from MEs in the SOS are still scarce.
Injection of enriched lithospheric mantle magmas explains the formation of microgranular enclaves in the Rio Jacaré Batholith, Borborema Province, Brazil This study presents and discusses the geological, petrographic, and geochemical data of the MEs of the Rio Jacaré Batholith (RJB), which is an important intrusion in the Poço Redondo Domain (PRD), located in the northern sector of the SOS.

REGIONAL CONTEXT
The SOS (Fig. 1A) is inserted in the southern portion of the Borborema Province (Almeida et al. 1977).This orogen is interpreted to be the result of the collision between the Sanfranciscana plate, to the south, and the Pernambuco-Alagoas Domain, to the northeast, during the Brasiliano Orogeny (D'el Rey Silva 1992, Oliveira et al. 2006, 2010).The seven geological domains of the SOS are limited by shear zones (Davison andSantos 1989, Silva Filho andTorres 2002): Estância, Vaza-Barris, Macururé, Marancó, Poço Redondo, Canindé, and Rio Coruripe.The Macururé, Marancó, Poço Redondo, and Canindé domains are characterized by abundant presence of granites.
The RJB occurs in the PRD (Fig. 1B), which, according to Santos et al. (2001), represents the deepest crustal exposure of the SOS.This domain is formed by the Poço Redondo Migmatitic Complex (Santos and Souza 1988) and by Neoproterozoic granites (Carvalho 2005, Pinho Neto et al. 2019, Sousa et al. 2019).The PRD is limited to the north by the Canindé Domain and the Macururé Shear Zone (Fig. 1A) and to the south by the Marancó Domain and the Poço Redondo Shear Zone.

Microgranular enclaves in the Sergipano Orogenic System
In the SOS, MEs have been described in several intrusions (Table 1).These enclaves, according to several authors (e.g., Gentil 2013, Silva 2014, Lima 2016, Lisboa et al. 2019, Pereira et al. 2019, Santos et al. 2019, Fernandes et al. 2020), show globular and elliptical shapes.Their sizes range from centimetric to metric.In the granites of the Macururé and Poço Redondo domains (e.g., Oliveira 2014, Silva 2014, Lisboa et al. 2019, Sousa et al. 2019, Fernandes et al. 2020), multiple enclaves, some with chilled margins, are described.These enclaves are randomly distributed in the intrusions or gathered in syn-plutonic dikes.In several of these enclaves, alkaline feldspar xenocrystals attributed to the host granites occur.These features provide evidence for mixing between mafic and felsic magmas during the evolution of these intrusions (e.g., Lisboa et al. 2019, Sousa et al. 2019).
The MEs of the Ediacaran bodies in the SOS have compositions ranging from diorite, quartz diorite, monzodiorite, quartz monzodiorite, monzonite, syenite, and alkali-feldspar syenite to alkali-feldspar-quartz syenite (Fig. 2A).The mafic minerals in these rocks are hornblende, biotite, diopside, and titanite, as accessory minerals, magmatic epidote, apatite, opaque minerals, and zircon are found.These rocks have silica contents varying from 44% to 63%, pointing to distinct degrees of evolution (Fig. 2B), and they have an affinity with shoshonitic series (Fig. 2C).
The Inequigranular Facies (Fig. 3A) is predominant in the RJB and consists of gray rocks with a medium to fine inequigranular texture.Eventually, these rocks have magmatic foliation and the elongated enclaves appear parallel or subparallel to the foliation of the host rocks.The Porphyritic Facies (Fig. 3B) differs from the previous facies due to the presence of alkali feldspar phenocrysts to macrocrystals, with sizes ranging from 1 to 5 cm.The rocks of these facies are composed of plagioclase (An 11-33 ), microcline (Or 75-98 ), quartz, biotite (0.3 < Fe/(Fe + Mg) < 0.6), Mg-hornblende, titanite, magmatic epidote, F-apatite, magnetite, ilmenite, and zircon.The RJB rocks are magnesian and metaluminous, and have a high-K calc-alkaline affinity and geochemical signature consistent with a post-collisional environment (Brito 1996, Sousa et al. 2019).
According to Oliveira et al. (2015), the RJB was probably formed by a mixture of mantle-derived and crustal magmas.These authors support this hypothesis based on ( 87 Sr/ 86 Sr) i ratios ranging from 0.70656 to 0.70789, with ε Nd(617 Ma) between -1.15 and -2.55 and T DM ranging from 1.2 to 1.3 Ga.

MATERIALS AND METHODS
The studied samples correspond to MEs, with colors ranging from light gray to dark gray.These rocks show no evidence of alteration and have magmatic textures.In this study, only samples from the central parts of the enclaves were collected in an attempt to avoid possible interactions between the periphery and the host magma.After grinding, the feldspar xenocrysts present in some enclaves were manually removed in order to obtain chemical data that corresponded as close as possible to the composition of the original magma that originated these rocks.
In this study, rocks were named using the International Union of Geological Sciences recommendations (Le Maître et al. 1989), and the modal data were obtained from the modified CIPW standard norm for hornblende-bearing rocks.
The geochemical analysis of major elements was obtained from pressed pellets using a Shimadzu XRF-1800 x-ray fluorescence spectrometer at the Condominium of Multiuser Laboratories of Geosciences of the Federal University of Sergipe.The pellets were made by mixing the samples with boric acid, which was sprayed onto the samples, with a ratio of samples to boric acid of 3:1.Then, the sample/boric acid mixtures were pressed in a hydraulic press with a pressure of 60 kN for 30 s.The degree of confidence of the analysis was evaluated through a comparison with certified reference materials (e.g., AVG-1, DTS-1, and QLO-1).The loss of ignition was determined by calcinating the samples at a constant temperature of 1,000°C in a muffle furnace for 2 h.
The trace elements were performed at the ALS commercial laboratory (details can be obtained on the lab website -www.alsglobal.com),Canada, through the package ME-MS81D.The method consists of lithium borate fusion prior to acid dissolution and ICP-MS analysis.

Geology
The RJB MEs are fine-grained and show sizes from 2 cm to 2 m, black to light gray colors, globular to elliptical shapes, and clear-cut, crenulated, and diffuse types of contacts.
In the eastern portion of the RJB, the MEs have smaller sizes, round shapes (Fig. 4A), and black color, and they are isolated.In the western region, the MEs are more abundant, have larger sizes, and occur more frequently in syn-plutonic dikes (Figs.4B-4D).These dikes are subvertical and have widths ranging from 1.5 to 6 m, and their lengths are greater than 10 m.In the western sector, there is a greater variety of enclave shapes exhibiting rounded to elongated features.They tend to present varying shades of gray.
Globular to elongated MEs with clear-cut contacts (Fig. 4E) predominate throughout the RJB.The elongated types are oriented parallel to the batholith's magmatic foliation.In the western region, the MEs are also clear-cut but with more complex contacts (Fig. 4F), including crenulated (Fig. 4G), lobate, sinuous, and cuspate.The MEs with crenulated contacts are typically 15 cm long, while the MEs with other types of contacts are larger.
Some MEs have a grain size that decreases from the nucleus to the border (Fig. 4E).Alkali feldspar and quartz xenocrysts in the MEs are recurrent features and can be identified by their grain size, which is similar to that of the host granite and larger than the grain size of the MEs (Fig. 4H).In some cases, multiple MEs are observed in the center of the RJB (Fig. 4I); these enclaves are gray and contain smaller, black enclaves.These black enclaves occur both within the gray enclaves and in the host granite.
Plagioclase occurs as phenocrysts (1.7-5.8 mm) and in the matrix (0.1-1.4 mm).These crystals are subhedral and show albite and albite-Carlsbad twinning and frequent compositional zoning.The zoning is parallel to the crystal faces and marked by the presence of opaque, biotite, and hornblende mineral inclusions (Fig. 6D).In some crystals, zoning develops from rounded plagioclase nuclei, suggesting dissolution (Fig. 6E).Patchy, boxy, cellular, and stepwise textures can occasionally occur, indicating complex evolution during crystallization.Sometimes, saussuritization is  observed in the grain nuclei of some crystals.A myrmekitic texture is occasionally present.
Brown biotite is subhedral and has brown to yellow pleochroism.It is frequently associated with hornblende crystals in mafic aggregates.Titanite crystals and anhedral opaque minerals occur as inclusions in grain margins and in cleavage planes.Green hornblende is subhedral to euhedral and presents pleochroism in shades of green.It Qtz: quartz; Hbl: hornblende; Bt: biotite; Pl: plagioclase; Ttn: titanite; Ep: epidote; Ap: apatite.commonly occurs in clusters along with biotite, titanite, and opaque minerals.
Epidote is subhedral or anhedral.Anhedral crystals are usually observed in the contacts with biotite, hornblende, and plagioclase.The subhedral crystals are considered to be magmatic, showing dissolution features.They can also occur as rims around allanite crystals.Rarely, vermicular quartz inclusions are observed in the epidote.Allanite occurs sporadically and subhedral titanite occurs as inclusions in most minerals and locally formed clusters.Apatite is euhedral and acicular (Fig. 6F), and, as individual elongated grains, it may be found often included in various minerals (e.g., in plagioclase and biotite).Zircon is euhedral (~0.1 mm) and occurs as inclusion.Anhedral opaque minerals (magnetite and ilmenite) no larger than 0.4 mm are associated with biotite, hornblende, and titanite crystals.

Geochemistry
The chemical data of representative samples of the RJB MEs are shown in Tables 2 and 3.
The RJB MEs are metaluminous (Fig. 7B) and belong to the magnesian suite (Fig. 7C).The K 2 O-SiO 2 , K 2 O-Na 2 O, and Ce/Yb-Ta/Yb relationships indicate a shoshonitic affinity (Figs.8A-8C).There is an increase in K 2 O in a group of samples with SiO 2 contents between 58 and 61%, splitting the population into two groups: one is positioned in the calc-alkaline field and the other in the shoshonitic field (Fig. 8A).This K 2 O variation may be due to an increase in the volume of alkali feldspar.The rare earth element patterns (Fig. 9) show enrichment in light rare earth elements (LREEs) rather than in heavy rare earth elements (HREEs).The [La/Yb] N and [La/Sm] N ratios range from 9.08 to 33.26 and from 2.04 to 4.77, respectively.Negative Eu anomalies are present with Eu/Eu* ranging from 0.48 to 0.88.It is observed that the samples are distributed into three groups of spectra (Fig. 9): 1: the sample SOS 850B (48.09% SiO 2 ), which has a higher sum of ETR; 2: a set of samples with weak negative Eu anomalies (0.68-0.88); and 3: samples SOS 844B and SOS 867B, which show the most negative Eu anomalies (0.48-0.65).

DISCUSSION
The MEs found in the RJB are easily observed in the field due to their abundance, high frequency in outcrops, and dark color, and because they are fine-grained, differing from the light-colored rocks that dominate this batholith.According to Kumar et al. (2004), enclaves with grain sizes finer than the host granites and lacking cumulate texture are not the residuum of a fractional crystallization that might have generated the host.According to Torkian and Furman (2015), the presence of MEs with fine-grained margins, microgranular or/and porphyritic textures, plagioclase crystals showing disequilibrium textures, and compositional variation indicates that these enclaves are products of magmatic mingling.These features are found in the RJB MEs and suggest that they were formed from magma and do not represent cumulates or restites.Therefore, the nature of these enclaves must reflect magmatic processes, such as the mixing of magmas and fractional crystallization.

Mixing
The RJB MEs show a large variation in their SiO 2 content (48-61%), but intermediate compositions predominate.According to Reubi and Blundy (2009) and Ruprecht et al. (2012), the generation of rocks with intermediate compositions results, in most cases, from the coexistence and mixing of contrasting magmas.According to Janoušek et al. (2004), the compositional variation of MEs can be considered the mixing of a mantle-derived mafic magma with crustal magmas.Some authors (e.g., Barbarin andDidier 1991, Shukla andMohan 2019) consider some features that are also found in the RJB MEs (e.g., variation in the color of the MEs, presence of multiple MEs, and diffuse contacts), a reflection of different degrees of homogenization and the role of mixing between the parental mafic magma and the felsic host.
The mixing of two magmas only occurs when their viscosities are similar (Fernandez andBarbarin 1991, Weidendorfer et al. 2014).According to Winter (2014), the catazone is a region in the crust where rocks experience high temperatures and the viscosity difference between different materials is relatively low.According to Sousa et al. (2019), the RJB rocks, the host rocks of the studied MEs, were crystallized at a depth of 25 km with a Mg-hornblende crystallization temperature of 826°C.Probably, these emplacement conditions of the RJB allowed its magma and the ME magma to have similar viscosities, favoring mixing processes to occur.
Mixing between magmas can often be inferred by identifying linear trends in binary diagrams.The samples studied in the CaO/SiO 2 versus FeO t /SiO 2 diagram show an alignment that suggests that mixing between magmas has occurred (Fig. 10A).This trend is consistent with two mixing components: a mafic magma (enclaves) and a felsic magma (host granite).
The variation in the SiO 2 content of the RJB MEs suggests that the compositions represent different degrees of hybridization.Therefore, the relative contributions of the mafic and felsic magmas were estimated using the linear correlation of major elements with the mixing algorithm of Fourcade and Allegre (1981).According to these authors, if mixing occurs, this process will affect each chemical element of the magmas, so that it will satisfy the following relation (Eq.1): Where: C i i = the concentration of element i in the hybrid magma; C i f = the concentration in the felsic magma; C i m = the concentration in the mafic magma; m = the fraction of the mafic magma in the mixture.
Using the algorithm by Fourcade and Allegre (1981), the samples SOS 850B (48% SiO 2 ) and SOS 854 (72.6% SiO 2 , 10/18 obtained from Sousa et al. 2019) were considered as representatives of the mafic and felsic magmas, respectively.To represent the hybrid magma, ME SOS 816C, which has a relatively high SiO 2 content (61.9%), was used, because it is the ME with the highest degree of hybridization (high SiO 2 and low V).A good linear correlation was obtained with the analyzed rocks, with R² = 0.991 (Fig. 10B).The angular coefficient obtained represents the fraction of the mafic magma involved in the mixing; for the SOS 816C sample, it is 43%.

Mingling
According to Perugini and Poli (2012), the evolution of the rheological contrast between magmas can be rebuilt from the study of magmatic enclaves.The various forms of MEs can be controlled by the differences in the viscosities/ rheologies of the magmas, and the more complex the forms, the greater these differences will be (Fernandez andBarbarin 1991, Perugini andPoli 2011).According to Petford (2003), several studies estimate that, regardless of composition, the transition from Newtonian to non-Newtonian behavior for magmas occurs when the magma is between 30% and 50% crystallized.Fernandez and Barbarin (1991) acknowledged that the injection of mafic magma at different stages of felsic magma crystallization can generate varied structures: • when the felsic host magma has a Newtonian behavior (up to 30% crystallized), active convection induces the dispersion of mafic magma droplets, generating globular MEs; • when the felsic magma has a viscoplastic behavior (30 to ~50% crystallized), the ME shapes can be deformed; • when the felsic magma is 70-90% crystallized, early fractures can be formed and allow the mafic magma to be injected, which will result in syn-plutonic dikes.
The formation of these syn-plutonic dikes can occur in two ways, depending on their thickness.When the mafic magma is injected as thin dikes, it quickly reaches a thermal balance by cooling down and becoming rigid.During the subsequent movements of the host magma, the dikes are broken, resulting in a syn-plutonic dike composed of MEs with angular contacts.When the mafic dike is thicker, its cooling is slower and it can overheat the host magma at the contacts, which will undergo limited partial melting.Local convection, caused by the increase in the thermal gradient, will induce the dispersion of the mafic magma as bubbles of various sizes, transforming the mafic dike into a corridor of MEs (syn-plutonic dike).
In the RJB, MEs with globular, elongated shapes and well-defined contacts (crenulated, cuspate, lobate, and sinuous) are found, in addition to syn-plutonic dikes composed of various enclaves of different shapes and sizes.These features indicate that mafic magmas were injected during two different crystallization stages in the RJB magmatic chamber.According to the model of Fernandez and Barbarin (1991), MEs with globular shapes were formed when mafic magma was injected into the felsic magmatic chamber of the RJB, with up to 30% crystallized, and disaggregated by convective movements; this also agrees with the interpretations of other authors about the genesis of globular MEs (e.g., Vernon et al. 1988, Castro et al. 1991, Liu et al. 2013, Shukla and Mohan 2019).Since MEs with such features are well distributed throughout the RJB, we believe that the input of mafic magma in this stage was important.It is believed that the RJB MEs with crenulated, cuspate, lobate, and sinuous contacts were formed when the felsic magmatic chamber had a degree of crystallization greater than 30%, as a greater difference in viscosity is necessary to generate these more complex forms (e.g., Perugini and Poli 2011).The input of mafic magma was probably more restricted at this stage, as enclaves with these types of contacts in the RJB only occur in the western region of the batholith.
The syn-plutonic dikes observed in the RJB indicate the occurrence of mafic magma pulses in the late stages of  crystallization, when 70-90% of the felsic magmatic chamber was crystallized, and that the presence of this mafic magma increased the local temperature, provoking the partial melting of the felsic magma.It is suggested that the contribution of mafic magma in the late stages of the crystallization of the RJB was restricted, as the syn-plutonic dikes are limited to the western region.The RJB's multiple ME types also suggest the occurrence of more than one mafic magmatic pulse during the evolution and formation of this batholith.Some textures found in the RJB MEs also indicate that these enclaves probably represent the breakdown of the mafic magma that was injected and cooled in a cooler felsic magmatic chamber: • zones of inclusion in plagioclase and ocellar quartz crystals (Hibbard 1991); • a boxy cellular plagioclase texture (Hibbard 1991); • acicular apatite (Wyllie et al. 1962, Hibbard 1991).
According to Torkian and Furman (2015), these textures and the crenulated and cuspate contacts between the MEs and the host rocks can be attributed to the mingling/mixing of magmas.
Feldspar and quartz xenocrystals in the ME can be observed in the field.The presence of xenocrystals in these enclaves indicates that the phenocrysts of the host magma surpassed the ME edges and were trapped inside (Barbarin andDidier 1991, Perugini et al. 2003).This indicates that the mafic and felsic magmas interacted with each other and had different rheologies, allowing the exchange of crystals between them in a mingling process (e.g., Perugini et al. 2003, Yang et al. 2015).
Therefore, it is suggested that the studied rocks are a product of partial chemical equilibrium between mafic and felsic magmas, representing a mingling/mixing process.

Magma of the microgranular enclaves
MEs in granites have been interpreted (e.g., Bonin 2004, Janoušek et al. 2004, Chen et al. 2007) as mantle-derived mafic magmas that underwent mixing/mingling after being injected into a deep crustal felsic magmatic chamber.The chemical compositions of the MEs studied reveal their affinity with the magnesian series and indicate that this mafic magma was hydrated and crystallized in an oxidizing environment, as suggested by Frost and Lindslay (1991) for rocks in this series.High fO 2 can also be inferred from the presence of titanite, quartz, magnetite, and hornblende (e.g., Wones 1989).Furthermore, most of the RJB MEs have high K 2 O, with K 2 O/Na 2 O > 1, which is the characteristic of shoshonitic rocks (Figs.8A-8C).K 2 O is high regardless of the rocks' SiO 2 content, and according to Turner et al. (1996), rocks with these characteristics probably reflect a potassium phase not only during fractionation but also at the source.
According to Furman and Graham (1999), an increase in the Rb/Sr ratio in relation to the primitive mantle may suggest that phlogopite was the hydrated mineral present at the source, while high Ba/Rb ratios suggest the presence of amphibole.The Rb/Sr ratios of the RJB MEs range from 0.14 to 0.55, and the primitive mantle has a ratio of 0.03 (Sun and McDonough 1989), suggesting mingling and can also indicate that the phlogopite in the source participated in the partial melt responsible for the magmas that generated the studied MEs (Fig. 11).
Shoshonitic magmas have as their main source the subcontinental lithospheric mantle or the asthenospheric mantle, which were both previously enriched in incompatible elements by subduction (e.g., Aldanmaz et al. 2000).The studied MEs show depletion in Ti, Nb, and Ta (Fig. 12) and high Th/ Yb ratios, which are typical signatures of magmas generated in an orogenic environment and represent contributions from the subducted plate (e.g., Foley and Wheller 1990, Ringwood 1990, Pearce 2008).RJB MEs have higher Th/Yb ratios than mantle evolution curves defined for MORBs and OIBs, which suggest subduction-induced source metasomatism (Fig. 13).The Hf, Th, Zr, Ce, and Nb content of the studied rocks indicates that this magma is formed in a post-collisional orogenic environment (Figs.14A and 14B).
High LILE and high Ba/Nb (> 13) and Ba/La (> 8) ratios are suggestive of enriched mantle sources (Ryan et al. 1996, Kepezhinskas et al. 2016).Such ratios in the RJB MEs are above 23 and 15, respectively, so they are compatible with enriched mantle sources.In addition, the low values of the Nb/La ratios (0.22-0.69) are consistent with a lithospheric mantle source (Fig. 15).
Sample SOS 850B is considered to be the most primitive of the RJB MEs, without evidence of cumulatic texture, low SiO 2 content (48%), moderate MgO (5.2%), and high CaO (8.2%) and V (227 ppm).It is also the only sample that presents normative olivine.Although the MgO content of this sample is not the highest among the MEs, its composition is similar to the compositions described for shoshonitic basalts (Morrison 1980) or trachybasalts of the Roman Province (Müller and Groves 2019).When calculating the partial melting of the metasomatized mantle by using the mantle composition (which consists of clinopyroxene (43%), amphibole (34%), phlogopite (22%), and spinel (1%)) of Kaczmarek et al. (2016), employing the batch melting model, the result points to a partial melting rate of less than 3% to generate magmas with compositions similar to that of sample SOS 850B (Table 4 and Fig. 16).According to Conceição and Green (2004)      for the formation of shoshonitic magmas; this is consistent with the values obtained in this work.Sousa et al. (2019) found normal zoning in plagioclase crystals of the RJB MEs.This type of zoning in plagioclase suggests that magmatic fractionation occurs during the process of mixing magmas.The occurrence of pronounced valleys in Ba and Sr, and the negative Eu anomalies in multielementary diagrams (Fig. 12) may indicate the fractionation of plagioclase.The predominance of P peaks (Fig. 12) may suggest the chemical diffusion of P from the host magma to the enclave magma, leading to the crystallization of apatite (Nardi and Lima 2000).The decrease in the P 2 O 5 and (La + Ce) content with the evolution of the ME magma supports the assumption that the fractional crystallization of apatite was an active process (Fig. 17).

14/18
Mafic magma: red color; MEs: black color.The Ti valleys in multielementary diagrams, in addition to representing a signature of the magmatic source, also suggest the fractionation of titanite and opaque minerals.By observing the behavior of compatible elements in some minerals (Sr and CaO in plagioclase, Sr and (FeO* + MgO) in amphibole, P 2 O 5 and (La + Ce) in apatite and V and TiO 2 in titanite) and the degree of ME magma evolution, it was observed that there is a decrease in these chemical elements with the evolution of the ME magmas (Fig. 17).This reinforces the hypothesis that the fractional crystallization of these minerals may have also contributed to the compositional variation of the MEs studied.
The geochemical data of the studied samples were compared with those ME of other plutons of the SOS.The geochemistry indicated that all these MEs are metaluminous and magnesian, and they have shoshonitic affinity.The abundances of trace elements and REEs in the MEs are also similar, and this is reflected by similar incompatible element patterns (Fig. 12).
Despite their different ages, the MEs from the Macururé and Poço Redondo plutons have similar characteristics, which suggest that the mafic magma responsible for the formation of these MEs had a similar source to the magma of the RJB MEs: the lithospheric mantle enriched in incompatible elements.This type of source was also attributed to K-diorites from the Borborema Province by Hollanda et al. (2003) and is confirmed when comparing the variation of the ( 87 Sr/ 86 Sr) i ratios (between 0.7059 and 0.71202) and of ε Nd (from -9.3 to -20.1).It is likely that the source of the RJB MEs is the same as the source described by Hollanda et al. (2003) for the potassic mafic magmas of the Borborema Province.

CONCLUSIONS
The origin of the RJB MEs can be summarized in four steps (Fig. 18): • Step 1: A 3% rate of partial melting of the lithospheric mantle previously enriched in incompatible elements by subduction, originating the shoshonitic mafic magma responsible for the generation of the MEs of the RJB; • Step 2: The injection of this mafic magma when the RJB magmatic chamber had crystallization rates ranging from 0 to 30% allowed mixing between these magmas, the disaggregation of the mafic magma by convection currents, and the subsequent formation of MEs with globular shapes throughout the RJB; • Step 3: New injections of shoshonitic mafic magma, which occurred when the RJB magmatic chamber was more than 30% crystallized, generating MEs with complex shapes and crenulated, sinuous and cuspate contacts in the western region of the batholith; • Step 4: The late injection of mafic magma in the western region of the RJB magmatic chamber (which was 70-90% crystallized) resulted in the formation of syn-plutonic dikes.
The chemical data of the studied MEs suggest that the mixing between the ME mafic magma and the RJB felsic magma was important, and also that the smallest fraction of mafic magma involved in this process was 43%.Mixing was responsible for the generation of MEs with various colors (black to gray) and contributed to the compositional variation of these rocks, which have diorite, monzodiorite, quartz monzodiorite, and monzonite compositions.Furthermore, the fractionation of plagioclase, hornblende, titanite, and apatite may have also contributed to the compositional variation of the RJB MEs.

Figure 2 .
Figure 2. Modal and chemical diagrams applied to the enclaves of different bodies of the geological domains of the SOS.(A) Streckeisen's (1976) QAP triangular diagram.(B) TAS diagram with fields proposed by Middlemost (1985).(C) Ta/Yb versus Ce/Yb diagram with fields defined by Pearce (1982).

Figure 3 .
Figure 3. RJB rocks in the field.(A) Inequigranular Facies and (B) Porphyritic Facies.Note the centimetric sizes of the alkali feldspar crystals and the finer grain of the matrix.Pinkish minerals with rectangular sections correspond to alkali feldspar crystals, white minerals correspond to plagioclase, and black minerals correspond to biotite and hornblende.The diameter of the black circle is 7 cm.

Figure 4 .
Figure 4. Field images showing different structures of the various types of MEs identified in the RJB.(A) MEs with globular to elongated shapes and clear-cut straight contacts.(B, C, and D) Set of elongated enclaves with different sizes interpreted as syn-plutonic dikes.Note the feature in the left corner of image D suggesting that the enclave's magma was undergoing rupture as it generated MEs.(E) ME with clear-cut contacts, showing a grain size increase from the edges to the center.Note the darker edges.(F) ME with crenulated to lobate margins.(G) Round ME with a crenulated contact in its left portion.(H) Alkali feldspar xenocrysts in ME.It is possible to observe crystals penetrating the enclave edges.(I) Multiple MEs in the RJB.Note the black enclaves inside the larger gray enclave.

Figure 5 .
Figure 5. Classification of the RJB MEs using the QAP diagram (Streckeisen 1976).The orange area represents the composition of the RJB rocks.The green area represents the compositions of the other SOS MEs.

Figure 6 .
Figure 6.RJB ME textures.(A) General view of the ME texture (parallel nicols).(B) Macroscopic image of ME showing the quartz ocellar texture (note black minerals at the edges of the crystal).(C) Quartz with ocellar texture.Note hornblende inclusions only at the edges of the crystal.(D) Compositional zoning and inclusion zone in plagioclase.Note that the compositional zoning and the inclusion zone are parallel to each other.(E) Plagioclase showing a nucleus with rounded faces and compositional zoning at the edges.(F) Acicular apatite crystals.

Figure 8 .
Figure 8. Geochemical diagrams for magmatic affinity inference.(A) K 2 O versus SiO 2 diagram of Peccerillo and Taylor (1976).(B) K 2 O versus Na 2 O diagram of Turner et al. (1996), characterizing the nature of the ME magma.(C) Ta/Yb versus Ce/Yb, with fields defined by Pearce (1982).The orange area corresponds to the RJB compositions.

Figure 11 .
Figure 11.Ba/Rb versus Rb/Sr diagram after Furman and Graham (1999), suggesting the presence of phlogopite in the mantle source of the RJB MEs.The green area represents the compositions of the other SOS MEs.

Figure 13 . 18 Figure 17 .
Figure 13.Nb/Yb versus Th/Yb diagram (Pearce 2008) applied to the RJB MEs.The green area represents the compositions of other SOS MEs.

Figure 18 .
Figure 18.Schematic model of the different steps of the formation of MEs in the RJB.

Table 1 .
Characteristics of the host plutons of MEs in the Macururé and Poço Redondo Domains of the Sergipano Orogenic System.

Table 2 .
Chemical analysis of major and minor elements and normative compositions (CIPW standard with hornblende) of the RJB MEs.
LOI: loss on ignition.

Table 3 .
Representative chemical analysis of trace elements of RJB MEs.Values are in parts per million.
PM: partial melting rate.