Boletín de la Sociedad Geológica Mexicana

Volumen 66, núm. 3, 2014, p. 413-430

http://dx.doi.org/10.18268/BSGM2014v66n3a1

Geochemistry and depositional environment of the Losero Formation in the Mesa Central, México

María Jesús Puy-Alquiza1,*, Raúl Miranda-Aviles1, Maricela Cruz-Cruz1, Ofelia Pérez-Arbizu2, Marina Vega-González2, Gabriela Ana-Zanor3

1 Departamento de Minas, Metalurgia y Geología, Universidad de Guanajuato, Guanajuato, México.
2 Universidad Nacional Autónoma de México (UNAM), Campus Juriquilla-Queretaro, Queretaro, México.
3 División de Ciencias de la Vida, Universidad de Guanajuato, Irapuato, Guanajuato.

* This email address is being protected from spambots. You need JavaScript enabled to view it.

 

Abstract

The Losero Formation is exposed in the Guanajuato Mining District, conformably overlying the Guanajuato conglomerate. Most of the up-to-date studies of the Losero Formation have indicated that this formation corresponds to a Cenozoic volcanic sequence. However, sedimentological, petrographic and geochemical evidence that supports a sedimentary or volcanic origin has not been discussed extensively. We present a comprehensive geological analysis which includes collection of samples and elaboration of eight stratigraphic columns, followed by laboratory studies including petrography, trace element determinations using Inductively Coupled Plasma Mass Spectrometry (ICP-MS) and mineralogy by X-ray diffraction and Scanning Electron Microscopy (SEM). The petrographic analysis revealed that the Losero Formation is constituted by litharenite and arkose, mostly derived from granitic and metamorphic basement rocks typical of the interior of a craton. Primary sedimentary structures include ripples, antidunes, flute and groove casts, cross and parallel lamination, desiccation cracks and soft-sediment deformation structures interpreted as seismites. These findings demonstrate that the sandstones were deposited by supercritical and subcritical flows as well as by unidirectional flows within channels and bars in a river system. Elemental ratios critical of provenance (La/Sc, Th/Sc, La/Cr, Th/Cr and Ba/Sc) are similar to sediments derived from weathering of mostly felsic rocks. Using QmFLt and QtFL ternary diagrams allowed to infer that the sandstones of the Losero Formation were deposited in an active continental margin. Modal analysis of the samples indicates a recycled orogen and dissected arc. Most evidence suggests that the deposit was accumulated in a fluvial environment with conditions ranging from shallow to deep water. Based on these data and field observations, the sandstones from the Losero Formation can be considered as part of the distal facies of the Guanajuato Conglomerate.

Keywords: Losero Formation, Guanajuato, Geochemistry, Provenance, Tectonic setting.

 

Resumen

Los depósitos de la Formación Losero afloran en el Distrito Minero de Guanajuato, y sobreyacen concordantemente al conglomerado Guanajuato. Los estudios más recientes realizados sobre dicha formación señalan que forma parte de la secuencia volcánica Cenozoica. Sin embargo las evidencias sedimentológicas, petrográficas y geoquímicas sugieren un origen volcánico o sedimentario, el cual no ha sido discutido ampliamente. En este trabajo se presenta un análisis geológico que incluye el levantamiento de ocho columnas estratigráficas con su respectiva toma de muestras, seguido por un análisis petrográfico, geoquímico (ICP-MS), mineralógico mediante Difracción de Rayos-X y de Microscopio Electrónico de Barrido (SEM). El análisis petrográfico reveló que los depósitos de la Formación Losero están constituidos por litarenitas y arcosas que derivan de un basamento granítico y metamórfico típico de un cratón interior. Las estructuras primarias que presentan son: rizaduras, antidunas, marcas de flutes y grooves, laminación paralela y cruzada, grietas de desecación y estructuras de deformación (sismitas). La presencia de dicha estructuras primarias demuestra que dichas areniscas fueron depositadas por flujos supercríticos y sub-críticos así como por flujos unidireccionales dentro de canales y barras de un sistema fluvial. Las razones entre los elementos de procedencia (La/Sc, Th/Sc, La/Cr, Th/Cr y Ba/Sc) son similares a las de los sedimentos derivados del intemperismo en su mayoría de rocas félsicas. Mediante los diagramas ternarios QmFLt y QtFL se infirió que las areniscas de la Formación Losero fueron depositadas en un margen continental activo. El análisis modal de las muestras analizadas indican una proveniencia de un orógeno reciclado y un arco disectado. La mayoría de la evidencia sugiere que los depósitos de la Formación Losero se acumularon en un ambiente fluvial con condiciones de flujo somero a profundo. Con base en los resultados obtenidos y las observaciones de campo, las areniscas de la Formación Losero pueden ser consideradas como las facies distales del conglomerado Guanajuato.

Palabras clave: Formación Losero, Guanajuato, Geoquímica, Proveniencia, Ambiente tectónico.

 

1. Introduction

The Losero Formation crops out in the Sierra de Guanajuato (Figure 1), mainly in the Guanajuato Mining District. It is located in the transitional zone between two major volcanic provinces of Mexico: the Paleogene Sierra Madre Occidental (SMO) and the Cenozoic Trans-Mexican Volcanic Belt (TMVB) (Randall et al., 1994). The SMO volcanic sequence consists mainly of silicic ignimbrites and rhyolitic lava domes with ages between the Miocene and Eocene (Nieto-Samaniego et al., 1992; Ferrari et al., 1999). The MVB units are basalts and andesites with middle Miocene to late Pliocene ages and are exposed in the region located immediately southeast of the Guanajuato Mining District (Hasenaka et al., 1994; Valdez-Moreno et al., 1999). The volcanic sequences of the southeastern SMO and the Central TMVB (Gómez-Tuena et al., 2005; Randall et al., 1994) are exposed at the Sierra de Guanajuato. These two sequences overlie Mesozoic metamorphic and sedimentary rocks (Echegoyen-Sánchez et al., 1970; Dávila and Martínez, 1987). The southern Sierra de Guanajuato includes a thick red bed sequence (Guanajuato Conglomerate), rhyolitic tuffs and lava domes (La Bufa and Chichíndaro rhyolite), as well as andesitic volcanoes and lava flows (Cedro Andesite and Calderones). Normal faulting has produced uplifted blocks with N-W, N-S and N-E trends (Cerca-Martínez et al., 2000). The term “Losero Formation” has been previously used in many publications (Orozco, 1921; Guiza, 1949; Schulze, 1953; Edwards, 1955; Echegoyen-Sánchez et al., 1970; Aranda-Gómez et al., 1989; Randall et al., 1994; Aranda-Gómez and Mc Dowell, 1998; Aranda-Gómez et al., 2003); however, no detailed stratigraphic and petrographic descriptions have been available, and its origin has not been sufficiently discussed.

In this work, specific stratigraphic levels of the Losero Formation were studied at eight localities (Calderones, El Faro, Yerbabuena, La Bufa, La Curva, El Socavón, Los Caídos and El Pocito), as shown in Figure 1, in order to determine the origin, paleo-tectonic setting and the depositional environment in which the Losero Formation was accumulated. Geochemistry for major and trace elements, petrography and modal analyses were performed in 46 samples. Furthermore, characteristic sedimentary structures observed in the Losero Formation comprise one of the most invaluable sources of information concerning its depositional environment. Based on these data, the final goal of this work is to establish if the Losero Formation has a purely sedimentary origin (fluvial, lacustrine), volcanic origin (pyroclastic, epiclastic) or mixed origin.


Figure 1. General map of the area of Guanajuato, showing the eight studied locations.

 

2. Geological settings

The Sierra de Guanajuato, located in the Mesa Central province, represents a transition zone between two volcanic provinces of Mexico: the Sierra Madre Occidental (SMO) and the Trans-Mexican Volcanic Belt (Gómez-Tuena et al., 2005; Randall et al., 1994).

The SMO province consists mainly of Oligocene and Miocene silicic ignimbrites and rhyolitic domes (Nieto-Samaniego et al., 1992; Ferrari et al., 1999). These two sequences rest on metamorphic and sedimentary rocks of Mesozoic age (Echegoyen-Sánchez et al., 1970; Dávila and Martínez, 1987; Martini et al., 2011).

The Sierra de Guanajuato is a NW-SE oriented mountain range with an elevation between 2000 and 2500 m.a.s.l. (Aranda et al., 1989; Cerca-Martínez et al., 2000). This range lies in the central part of the Guerrero Terrane and is constituted by arc sequences, particularly the Late Jurassic early Cretaceous Alisitos-Teloloapan arc (Tardy et al., 1992). The Bajio fault represents an important boundary along the southwesterrn front of the Sierra de Guanajuato and marks the northern limit of the El Bajio depression (Aranda-Gómez et al., 1989; Nieto-Samaniego et al., 1992). The volcanic sequences of the southeastern SMO and the central TMVB are exposed at the Sierra de Guanajuato, represented by silicic ignimbrites, rhyolitic lava domes (Oligocene and Miocene ages) and basalts and andesites of middle Miocene to late Pliocene ages (Aranda- Gómez, et al., 1989; Aguirre-Díaz et al., 1998; Ferrari et al., 1999). Lapierre et al. (1992) and Ortíz-Hernandez et al. (1992) recognized two Mesozoic petrotectonic assemblages in the Sierra de Guanajuato: an intrusive complex and eruptive sequence assemblage and the Guanajuato arc assemblage. The intrusive complex is constituted by gabbro, diorite and tonalite (157 to 120 Ma, Lapierre et al., 1992), locally intruded by basaltic and doleritic dikes. The eruptive succession is composed of massive to pillow basalt 108 to 66 Ma in age, (Lapierre et al., 1992) and hyaloclastite interbedded with volcanic breccia, radiolarian chert, arkose, arkosic greywacke and scarce rhyodacitic tuff at the top of the sequence. The Guanajuato arc assemblage has been interpreted by Lapierre et al. (1992) and Tardy et al. (1994) as an intraoceanic arc, built on oceanic crust. Rocks of the arc assemblage overlie in thrust contact of the Arperos Basin assemblage, which consists the Arperos and Esperanza formations (Martini et al., 2011). The Arperos Formation consists of two petrotectonic assemblages: the Arperos and El Paxtle assemblage, (Martini et al., 2011). The Arperos assemblage consists of pillow basalts (93 to 85 Ma, Ortiz-Hernandez et al., 2003) and hyaloclastite, conformably overlain by volcanic sandstone, shale, radiolarian chert, scarce conglomerate and micritic limestone (Ortiz-Hernandez et al., 2003). On the other hand, the El Paxtle assemblage is constituted by El Paxtle Formation and the Tuna Manza intrusive complex. The Paxtle Formation is composed of pillow basalts and massive basaltic lava flows, hyaloclastite, basaltic tuff, fine grained chert, volcanic sandstones and shale, which are sheared and metamorphosed (Martini et al., 2011). The Esperanza Formation consists of polydeformed metavolcaniclastic rocks and limestone (Echegoyen-Sanchez, 1978). Martini et al. (2011) divided the Esperanza Formation into two units: the Esperanza and Valenciana formations. The Esperanza Formation consist of alternating thin beds of very fine to coarse grained sandstone, thin bedded siltstone, claystone and scarce lens-shaped conglomerate strata. The Valenciana Formation consists of finely bedded and laminated micritic limestone and shale. The Esperanza and Valenciana formations are overthrust by the El Paxtle assemblage (Martini et al., 2011). Units characterized by red bed sequences of Cenozoic age (Guanajuato conglomerate and Losero Formation) overlie the Mesozoic assemblage (intrusive complex and eruptive sequence, and Guanajuato arc). Geological evidence suggests that the Cenozoic sequence was contemporaneous with an extensional tectonic setting represented by a syn-volcanic conjugated set of normal faults. The Guanajuato conglomerate is considered of Eocene age (Ferrusquía-Villafranca, 1987; Aranda-Gómez and McDowell, 1998) with a thickness between 1,500 and 2,000 m and was divided by Edwards (1955) into two members. The lower member unconformably overlies the Mesozoic assemblage and has a thickness between 900-1,300 m. The base of this member presents conglomerate layers intercalated with andesite lava flows. The contact between the lower and upper members is represented by an erosional unconformity of undetermined age (Edwards, 1955). The upper member consists of a matrix supported conglomerate which has a thickness that varies from 170 to 700 m, increasing toward the southeast. The Losero Formation, which overlies the Guanajuato Conglomerate, has been considered as the base of the Oligocene volcanic cover, and has been previously studied by several authors (Orozco, 1921; Guiza, 1949; Schulze, 1953; Edwards, 1955; Echegoyen-Sanchez et al., 1970; Aranda-Gómez et al., 1989; Randall et al., 1994; Aranda-Gómez and Mc Dowell, 1998; Aranda-Gómez et al., 2003, Puy-Alquiza et al., 2013). The origin of the Losero Formation is poorly understood. Orozco (1921) described the Losero Formation as greenish detrital deposits formed by water transporting volcanic tuff, while Guiza (1949) mentioned that this formation is rhyolitic volcanic ash of uniform grain. On the other hand, Schulze (1953) described the Losero Formation as a tuffaceous deposit that resulted from aqueous-igneous flows. Echegoyen-Sánchez et al. (1970) first adopted the name of Losero Formation, following the definitions made by Monroy (1888) and Guiza (1949), who interpreted the deposit as a fine lapilli with a distinctive green color, apparently deposited in water. According to Randall et al. (1994), the Losero Formation is of Oligocene age and could be a surge deposit that preceded the emplacement of Bufa Rhyolite, which is in turn interpreted as a major ignimbrite. Based on this, the most recent interpretation about its origin is that the sequence is essentially made up of subaerial pyroclastic surge layers and tuffs of uncertain eruptive style deposited in (and locally reworked by) shallow water (Aranda-Gómez et al., 2003).

 

3. Methods

Representative samples were collected in eight different localities where the Losero Formation is exposed (in the Guanajuato Mining District), as shown in Figure 1. A detailed description and logging of the rock exposures at the studied locations were made. The first part of the investigation involved field work, sampling and observation and analysis of primary structures. The second part included petrography and major and trace element geochemistry. For the mineralogical study, 46 fresh samples of the Losero Formation were selected as representative for thin-section petrography. Following Ingersoll et al.(1984) point-counting was employed for quantitative compositional analysis of the different mineral grains. The modal analysis was performed by counting more than 300 points per thin section as done by Gazzi (1966) and Dickinson (1970); rock classification is based on the scheme proposed by Folk (1974). Trace elements composition (Y, Zr, Ti, Nb, Ta, Th, Sc, Hf, Co) was determined using an ICP-MS, and mineralogy by X-ray diffraction and Scanning Electron Microscopy (SEM) at the UNAM laboratories in Juriquilla, Querétaro.

 

4. Results and Discusion

4.1. Paleo-environment analysis

Two stratigraphic members can be clearly distinguished in the Losero Formation (Figure 2). The lower member, about 5 m thick, is composed mainly of brownish red sandstone and mudstone. Lithofacies are characterized by Sg (coarse sand with gradation normal), Sh (medium to fine sand with plane-parallel laminae and associated with desiccation cracks), St (medium sand with cross lamination) and Fm (mud, silt with desiccation cracks and cuspate ripple marks; Figure 3). The layering usually consists of beds of coarse to fine sand and mud. Most individual layers extend horizontally for hundreds of meters and a strike of NW83°SE with a dip of 35°NE can be observed at all locations. This lower member conformably overlies the Guanajuato conglomerate (Figure 3). The upper member, about 25 m thick, is composed of brownish red and green sandstone and mudstone and is characterized by lithofacies Sg (coarse sand with normal gradation), Sh (medium to fine sand with plane parallel laminae associated with desiccation cracks), St (medium sand with antidunes and cross laminations), Ss (fine sand with groove casts, flute casts and ripples) and Sd (soft-sediment deformation structures interpreted as seismites associated with normal faults) (Figure 3). The bed strike is NE45°SW with a dip of 20°SE. The main differences between these members observed in the field are the primary sedimentary structures.


Figure 2. Lithostratigraphic sections of the Losero Formation.

 


Figure 3. Columnar section of the Losero Formation.

 

4.1.1. Primary sedimentary structures in the lower member

The lower member is characterized by the following main primary sedimentary structures (Figure 4): plane parallel laminae, desiccation cracks, ripples and cross bed sets. The plane parallel laminae can be found in medium to fine sand. This primary structure is interpreted as evidence of tractive flow in upper flow regime (Harms, 1979). Some sets of laminae show ondulations and small cusps which indicate products of syn-sedimentary deformation, probably induced by water escaping during deposition. Vertical size grading is commonly observed in the lower part of beds. The mud beds show desiccation cracks of different sizes (1 to 6 cm) where the larger cracks truncate the smaller ones. Cuspate ripples are present in the upper portion of some beds and are often associated with desiccation cracks. These ripples present a curve geometry and are discontinuous. They additionally have high amplitude, tuning fork patterns with 10 cm distance from crest to crest and oriented towards the SE. These ripple types are commonly formed by moderate currents within a lower flow regimen (Harms, 1969). They indicate fluvial environments (channels or channel bars) and are most abundant along the lower reaches of streams where they are associated with parting lineations. They are also abundant at the distal ends of ephemeral streams (Picard and High, 1973). Another primary structure that can be found in the lower level is the cross bed sets. Most of the sets have a very low angle and seem to be a laterally extensive combination of trough and tabular types. Thickness of individual cross bed sets ranges from 0.5 to 1 cm. The set inclinations vary from 5 to 15 degrees and are oriented invariably towards the SE.


Figure 4. Primary sedimentary structures in the upper member of the Losero Formation: (a) Flute casts; (b) Groove casts; (c) Ripples; (d) Cross bedding; (e) Antidunes; (f) Soft deformation structures (seismites).

 

4.1.2. Primary sedimentary structures in the upper member

Planar low angle lamination is very common in the upper member (Figure 5) and is present in medium to fine sand. In the upper portion, tectonic features as inclined surfaces and angular contacts can be seen between the beds. Depositional features (lamina set) alternating with erosional features are commonly observed. Both depositional and erosional surfaces are planar and form low angles relative to the horizontal. Thickness of individual laminae sets ranges from 0.5 to 3 cm. The cross-bedded unit contains solitary, isolated trough sets. The set inclinations vary from 5 to 15 degrees and are oriented invariably towards the SE. Thickness of individual cross bed sets range from 0.5 to 1 cm. The trough sets are cut into older, planar laminated sandstone. Planar lamination occupies the lower and middle parts of the bed and long-crested ripples occupy only a few centimeters in the upper part. Some beds lack ripples and display only groove and flute casts. Ripples are asymmetrical, have low amplitude, pointed crests and rounded troughs. They have 1 ‒ 2 cm crest distances and their orientation is 65° SE. The ripples are present above the flutes and groove casts. This is probably due to formation in extremely shallow water, < 2 m deep, under flow conditions (Tanner, 1967, 1971; Aspler et al., 1994). The depositional couplet of planar lamination capped by oscillation ripples is common in the Losero Formation, which is due to storm events that produced a flow which combined both unidirectional and oscillatory motions. This combined flow resulted in planar laminated sand (Aspler et al., 1994). The antidunes that can be observed are associated with planar laminated sand and they are symmetrical in shape. They show a sinusoidal appearance and their amplitudes reach 1 to 2 cm. These structures are characteristic of supercritical and subcritical flow conditions (Núñez-González and Martín-Vide, 2010). These are also characteristic products under the upper flow regime (Gilbert, 1914). The flutes and groove casts only occupy the bottom part of the bed. Flutes are erosive structures that are produced by movements of a fluid over a cohesive substrate and they are also aligned in rows parallel to the flow. Blunt-nosed cylindrical forms are associated with more pointed and conical forms. They are approximately equal in size and are aligned more or less parallel to each other. The length of the flutes varies from 19 to 22 cm with an orientation of 35°SE. The flutes represent sediments that filled depressions on the immediately subjacent bedding plane and they are caused by erosion of freshly deposited mud on an underwater slope (turbidity current) (Ricci-Lucchi, 1995). The groove casts are associated with the flute casts; these are about a millimeter or so in height and 2 to 4 cm in length and they present an orientation of 45º towards the SE. They are remarkably straight and some of them are continuously exposed along the exposed bedding plane. This structure is produced by the flow of currents on soft mud (Crowell, 1955; McBride, 1962).

One meter below the Losero-Bufa contact are structures produced by soft-sediment deformation (Sd) which are interpreted as seismites. Some of the sedimentary deformation structures observed in Losero Formation are: asymmetric folds, pseudo-nodules, sand dikes, flame structures, non-sedimentary normal faults and convolute laminae. They are directly related to internal characteristics of sedimentary materials as well as to external factors acting on them. It is important to note that the Losero Formation conformably overlies the Guanajuato Conglomerate, which is observed at the localities of La Bufa, Calderones and Yerbabuena (see Figure 1) where the sand and silt facies of the upper member of the Guanajuato Conglomerate gradually become olive green facies, typical of the Losero Formation.


Figure 5. Primary sedimentary structures in the lower member of the Losero Formation: (a) Plane-parallel laminae; (b) Ripples; (c) Desiccation cracks; (d) Cross bedding.

 

4.2. Petrography and modal analysis

In the Losero Formation, the litharenites are coarse to medium grained, whereas arkoses are generally medium to fine grained. Petrographic studies reveal that the framework grains are mainly monocrystalline quartz (Qm), polycrystalline quartz (Qp), feldspars (F), biotite, and rock fragments (L) (Table 1). The most abundant lithic fragments are phyllite, quartzite, andesite and basalt. The matrix is composed of quartz. All the studied samples contain small amounts of potassium feldspar (K). Furthermore, the low potassium values (mean value for K2O = 8.18 wt %) of the bulk rock analyses of sandstone samples support the petrography results concerning the low K-feldspar content (Table 1). Plagioclase observed in thin sections includes twinned albite and is more abundant than K-feldspar. The K-feldspars are affected by K-feldspathization while albite is partially altered to sericite. Quartz and plagioclase grains are in higher proportions than lithic fragments. Modal analysis from point-counting of the framework grains are presented in Table 1. Monocrystalline quartz (Qm), polycrystalline quartz (Qp), total feldspar (F), and total lithic fragments (Lt) are identified. Petrographic features and composition of the sampled rocks are shown in Figure 6. Sub-angular to sub-rounded quartz grains are the most common. Sub-angular grains preferentially derived from volcanic and metamorphic rocks (see Figures 6d and 6f). A small quantity of opaque minerals (pyrite, magnetite and hematite) were observed in all samples. Alterations as intermediate argilic, propylitic, sericitic and potassic K-silicate are the most common in all samples. Development of silicate overgrowths with chlorite and calcite replacement of rock fragments and plagioclase becomes more pronounced as burial increases. Using Folk’s (1974) classification (QFL ternary plot), results show that the Losero Formation is constituted by lithic-arkoses reflecting their slightly mineralogical immature character (Figure 7A). The geochemical classification diagrams of Pettijohn et al.(1972) considering the boundaries redrawn by Herron (1988) for these sandstones (Figure 7B) show a bimodal distribution with litharenite and arkose clusters. To sum up, the overall petrologic assessment reveals that the observed lithic-arkose can be described as immature sandstone derived from basement uplift, as suggested by the presence of quartz-domination with variable amounts of feldspars and rock fragments, which indicate derivation mainly from acid igneous and metamorphic rocks.


Figure 6. (a,b) Photomicrograph showing quartz grains consisting mainly of polycrystalline quartz grains; (c) Quartz grains consisting mainly of microcrystalline grains; (d) Phyllite and volcanic fragments; (e) Monocrystalline quartz grains and plane parallel laminae; (f) Clast-supported fragments or grains; (g, h) Monocrystalline and polycrystalline quartz grains, phyllite fragments in silt-clay cement; (i) Petrographic features and composition of the lower and upper member of the Losero Formation.

 

Figure 7. (a) QRF triangular classification plot (Folk, 1974) of sandstone from the Losero Formation; (b) The Log (SiO2/Al2O3) vs Log (Fe2O3/K2O) diagram of Herron (1988); and (c) Chemical classification of samples of the Losero Formation based on the Log (SiO2/Al2O3) vs Log (Na2O/K2O), diagram of Pettijohn et al.(1972).

 

Table 1. Detrital modes of selected samples of sandstone form the Losero Formation (U, upper member; L lower member). Qm (monocrystalline quartz); Qp (polycrystalline quartz); Qt (Total quartzs grains [Qm+Qp]); F (Total feldspar grains [P+F]); Lv (volcanic rock fragments); Lm (metasedimentary rock fragments); Lt (Total lithic fragments [Lv+Lm]); Bt (biotite); Ac (Magnetite) (modified after Dickinson, 1985).

 

5. Provenance and tectonic setting

The use of geochemical composition of sedimentary rocks is a vital tool in understanding the nature of source rocks (Roser and Korsch, 1988; McLennan et al., 1993), as well as the tectonic setting of the depositional basin (Bathia, 1983; Bathia and Crook, 1986; Roser and Korsch, 1986). Provenance analysis is useful in reconstructing the depositional history of sediments or sedimentary rocks. Many attempts have been carried out in order to refine provenance models using framework composition (Dickinson, 1985; Zuffa, 1987), geochemical features (Bathia and Crook, 1986; Roser and Korsch, 1988), and heavy mineral assemblages (Morton, 1985; Chaodong et al., 2005). The major element geochemical parameters proposed by Bhatia (1983), such as Fe2O3 + MgO %, TiO2 %, (Al2O/SiO2), (K2O/Na2O) and (Al2O3/ [CaO + Na2O]) are used to discriminate the plate tectonic setting of sedimentary basins. Roser and Korsch (1986) used the K2O/Na2O ratio and SiO2 content of published data from an ancient sedimentary suite to define passive margin (PM), active continental margin (ACM) and oceanic island arc (ARC) settings. McLennan et al. (1993), as well as Taylor and McLennan (1985), have noted that concentrations of major trace and rare earth elements (REE) of sediments are well suited to constrain provenance and source rock composition due to the fact that the REE content is transferred with minimal fractionation from the source material into the sediments. Consequently, elemental ratios such as La/Sc, La/Co, Th/Sc and Zr/Cr, as well as La, Th, and Zr content (Ronov et al., 1974; Wronkiewicz and Condie, 1987, 1990), have proved to be good discriminators between mafic and felsic source rocks. Based on this, the Th/Sc ratios range from 0.86 to 1.02 for the lower member, and 0.90 to 2.07 for the upper member (Table 2). La/Th ratios range from 1.85 to 2.13 for the lower member, and 1.65 to 3.14 for the upper member (see Table 2). These data suggest a mixed source of sediments. Floyd and Leveridge (1987) stated that the elemental ratio of La/Th plotted versus the concentration of hafnium (Hf) demonstrates the degree of recycling in sandstones and it also provides information about the provenance. In this study, La/Sc, Th/Sc, La/Co, and Th/Co values of the sandstones of the Losero Formation are more similar to values of those sediments derived from felsic rocks than those for mafic rocks (Table 3). The La/Th versus Hf plot for the sandstone of the Losero Formation shows intense recycling and sedimentary source (Figure 8). In a La-Th-Sc diagram (Figure 8), used to discriminate felsic and basic provenance, the sediment data fell in a specific region that indicates a predominantly felsic source, but does not exclude an intermediate source or possible mixing between felsic and basic source rock. The maximum Ba and Sr concentrations in sandstones of the Losero Formation 611 ppm and 186 ppm, respectively (Table 4). The high Ba and Sr contents could suggest a stream sediment environment (Keshav et al., 2011).

Particularly, this high Ba enrichment can be attributed to feldspar weathering in silicate rocks. High levels of Sr are commonly found in acidic rocks, such as granite (Keshav et al., 2011). The sandstones have low Sc, Fe, Cr and Co contents and high concentrations of the REE, Th, and Hf, and high La/Sc, Th/Sc, La/Cr, Th/Cr and Ba/Sc ratios (Figure 9), indicating that they were derived mainly from felsic rocks (Cullers et al., 1987, 1988). The studied rocks are rich in Rb (88 ppm and 190 ppm) when compared to the average North America Shale Composite (NASC). The Cr/V values vary between 0.36 and 0.67 and Y/Ni values range between 1.64 and 9.2 (Table 2). In order to use major elements for provenance interpretations, the discriminant functions of Roser and Korsch (1988) were considered using Al2O3, TiO2, SiO2, Na2O, and K2O contents as variables. In Figure 10, the majority of the samples from the Losero Formation plot in the felsic igneous provenance field. This is equivalent to an active continental margin tectonic setting (Bhatia, 1983), (Figure 10). In the QtFL and QmFLt ternary diagrams of Dickinson et al.(1983), the point counting data plot in the recycled orogen and dissected arc (Figure 11).

Table 2. Ratios of Th/Sc, La/Th, Zr/Sc, Th/Cr, Cr/V, La/Co, La/Th, La/Cr, Zr/Cr, Th/Co, Cr/Th and Y/Ni for the lower member (L) and upper member (U), Inductively Coupled Plasma Mass Spectrometry (ICP-MS).

 

Table 3. Range of elemental ratios from sandstones from the Losero Formation compared to elemental ratios in sediments derived from felsic rocks, mafic rocks, and in the upper Continental Crust. 1 Cullers (2000); Cullers and Podkovyrov (2000); Cullers et al. (1988). 2 McLennan (2001); Taylor and McLennan (1985).

 

Table 4. Whole rock trace element composition of sandstones from the Losero Formation. Elemental concentrations are in parts per million. U (upper member), L(lower member), Inductively Coupled Plasma Mass Spectrometry (ICP-MS).

 

Figure 8. (a) Plot La-Th-Sc of sandstone from the Losero Formation (after Bathia and Crook, 1986); (b) Plot of Th/Sc versus Zr/Sc of sandstone from the Losero Formation (modified after McLennan et al.1993); (c) Source rock Hf-La/Th, discrimination diagram for the discussion of the clastic sediments and their compositions (Floyd and Leveridge, 1987) for sandstone from the Losero Formation.

 

Figure 9. Plots of (a) Th vs Cr; (b) La vs Cr; (c) Ba vs Sc; (d) La vs Sc; (e) Th vs Sc.


Figure 10. Discrimination diagrams for sandstone from the Losero Formation. (a) Bivariate plot of TiO2 vs (Fe2O3 + MgO) (after Bathia, 1983); (b) Discriminant function diagram for the provenance signatures (after Roser and Korsch, 1988).


Figure 11. QFLt and QmFLt ternary diagrams for sandstone of the Losero Formation based on Dickinson et al. (1983).

 

 

6. Conclusions

Based on a comprehensive study in studied rocks of the Losero Formation (petrography, geochemistry, modal analyses and ternary diagrams), this succession is interpreted as being formed by arkoses and litharenites. The following evidence that supports this interpretation is:

  • The primary structures observed in the Losero Formation are ripples, antidunes, flute and groove casts, cross and parallel lamination, and desiccation cracks.

  • The primary structures show that the sedimentation occurred in fluvial, shallow and deep water flow environments.

  • The syn-sedimentary features and the presence of seismites highlight the strong influence of tectonic activity during the Eocene in the Losero Formation with earthquakes of moderate magnitude which were capable of liquefying the sediment.

  • Paleocurrent data (flute and groove casts) indicate that sediment in the Losero Formation was derived from a northwest source area.

  • Trace element concentrations in the rocks of the Losero indicate deposition in an active continental setting that received detritus from the source areas.

  • The high Ba and Sr concentrations (611 ppm and 186 ppm, respectively) reinforce the interpretation of a sedimentary origin in detriment of a volcanic origin.

  • The Th/Sr ratios range from 0.86 to 2.07 and La/Th from 1.65 to 3.14, suggesting a mixed source of sediment.

  • The low contents of Sc, Fe, Cr and Co, and high, La/Sc, Th/Sc, La/Cr, Th/Cr and Ba/Sc ratios and Th and Hf concentrations indicate that they were derived mainly from felsic rocks.

  • The QtFLt and QmFLt ternary plots indicate a recycled orogen and dissected arc. The recycled orogen source derived from Mesozoic rocks of the Sierra de Guanajuato. This composition shows that the core of the Sierra de Guanajuato was exposed during the early Cenozoic.

  • Based on all the described evidences, it is proposed that the Losero Formation sandstones represent the distal facies of the Guanajuato conglomerate.

 

Acknowledgements

This research was conducted with the financial support of DINPO-University of Guanajuato, Project 000044/09.

 

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Manuscript received: September 22, 2013.
Corrected manuscript received: December 31, 2013.
Manuscript accepted: January 8, 2014.