Lavas or ignimbrites? Permian felsic volcanic rocks of the Tisza Mega-unit (SE Hungary) revisited: A petrographic study

Permian felsic volcanic rocks were encountered in petroleum exploration boreholes in SE Hungary (eastern Pannonian Basin, Tisza Mega-unit, B ek es–Codru Unit) during the second half of the 20th century. They were considered to be predominantly lavas (the so-called “Battonya quartz-porphyry”) and were genetically connected to the underlying “Battonya granite.” New petrographic observations, however, showed that the presumed lavas are crystal-poor (8–20 vol%) rhyolitic ignimbrites near Battonya and resedimented pyroclastic or volcanogenic sedimentary rocks in the T otkoml os and the Biharugra areas, respectively. The studied ignimbrites are usually massive, matrix-supported, fiammebearing lapilli tuffs with eutaxitic texture as a result of welding processes. Some samples lack vitroclastic matrix and show low crystal breakage, but consist of oriented, devitrified fiammes as well. Textural features suggest that the latter are high-grade rheomorphic ignimbrites. Felsic volcanic rocks in SE Hungary belong to the Permian volcanic system of the Tisza Mega-unit; however, they show remarkable petrographic differences as compared to the other Permian felsic volcanic rocks of the mega-unit. In contrast to the crystal-poor rhyolitic ignimbrites of SE Hungary with rare biotite, the predominantly rhyodacitic–dacitic pyroclastic rocks of the Tisza Mega-unit are crystalrich (40–45 vol%) and often contain biotite, pyroxene, and garnet. Additionally, some geochemical and geochronological differences between them were also observed by previous studies. Therefore, the Permian felsic volcanic rocks in SE Hungary might represent the most evolved, crystal-poor rhyolitic melt of a large-volume felsic (rhyodacitic–dacitic) volcanic system. The Permian volcanic rocks of the studied area do not show any evident correlations with either the Permian felsic ignimbrites in the Finiş Nappe (Apuseni Mts, Romania), as was supposed so far, or the similar rocks in any nappe of the Codru Nappe System. Moreover, no relevant plutonic–volcanic connection was found between the studied samples and the underlying “Battonya granite.”

Ancient volcanic rocks might have undergone various processes of syn-and post-volcanic alteration; thus, it could be a real challenge to determine their original volcanic facies. Primary textural features could have been overprinted or modified, making the genetic interpretation (e.g., pyroclastic rock or lava) of such rocks a difficult task for volcanologists (e.g., Allen 1988;Henry and Wolff 1992;Gifkins et al. 2005a, b). The incomplete destruction of primary textures and the different alteration styles can also have resulted in the development of false textures or pseudotextures. Thus, false pyroclastic textures (false shards, false eutaxitic texture) as well as false massive textures can have been formed, usually causing significant difficulties in the reliable interpretation of ancient volcanic rocks (Allen 1988;Gifkins et al. 2005a, b).
Permian felsic volcanic rocks of the Hungarian part of the Tisza MU were previously described and interpreted in the reports of uranium ore (southern Transdanubia) and petroleum (SE Hungary) exploration work during the second half of the 20th century (e.g., Barab as-Stuhl 1988;F€ ul€ op 1994;K} or€ ossy 2005a, b). According to the archive reports the rocks were considered to be dominantly lavas ("quartzporphyry" using the appropriate paleovolcanic name; Szederk enyi 1962;Szepesh azy 1967;Barab as-Stuhl 1988;K} or€ ossy 2005a, b); however, modern petrographic observations (e.g., Hidasi et al. 2015;Szemer edi et al. 2016Szemer edi et al. , 2017 reinterpreted most of them as ignimbrites in the area of southern Transdanubia. In a similar way such a (re)examination of the Permian felsic volcanic rocks in SE Hungary was also required.
Three main subsurface areas of the Permian felsic volcanic rocks can be distinguished within southern Transdanubia: (i) the Western Mecsek Mts, (ii) the M ariak em end-B ata Basement Range (M ariak em end-B ata BR), and (iii) the northern foreland of the Vill any Mts ( Fig. 1a; Barab as-Stuhl 1988;Szemer edi et al. 2016Szemer edi et al. , 2017. The Western Mecsek Mts and the M ariak em end-B ata BR are represented by crystal-rich fiamme-bearing rhyodaciticdacitic ignimbrites, while in the northern foreland of the Vill any Mts such ignimbrites and subordinate felsic lavas occur (Szemer edi et al. 2016(Szemer edi et al. , 2017(Szemer edi et al. , 2020. In the Apuseni Mts ( Fig. 1a; Codru and Biharia Nappe Systems) rhyodacitic-dacitic ignimbrites are present; however, they are accompanied by mafic-to-intermediate lavas (basalt and subordinate andesite) as the result of a mainly bimodal volcanic activity (Codru Nappe System; Nicolae et al. 2014;Szemer edi et al. 2018).
Detailed petrographic studies have not targeted the Permian felsic volcanic rocks of the eastern Pannonian Basin (Battonya-Pusztaf€ oldv ar Basement Ridge and Kelebia area, Hungary; Fig. 1a). These rocks were briefly described in the  (Szepesh azy 1967;  K} or€ ossy 2005a, b). Geochemically, all of the Permian felsic volcanic rocks in the Tisza MU show similar general characteristics. Nevertheless, some weak chemical differences were observed in the samples of the Battonya-Pusztaf€ oldv ar Basement Ridge (Battonya-Pusztaf€ oldv ar BR) that are rhyolites according to the immobile element-based rock classification (Zr/TiO 2 vs. Nb/Y), while the others are rhyodacites-dacites (Szemer edi et al. 2020). Moreover, felsic pyroclastic rocks in SE Hungary proved to be slightly younger than other Permian volcanic rocks of the Tisza MU (Szemer edi et al. 2020).
The aim of this study is to provide a detailed petrographic description of the Permian felsic volcanic rocks of SE Hungary, using all available drill cores and thin sections from the boreholes near the villages of Battonya, Biharugra, and T otkoml os ( Fig. 1b and c). Furthermore, we attempt to interpret the former and new descriptions in the light of modern volcanological views of the ancient, altered volcanic sequences (e.g., Gifkins et al. 2005a, b).

Geologic background
In SE Hungary, ca. 50 boreholes (near the villages of Battonya, Biharugra, Kelebia, Mez} okov acsh aza, Nagysz en as, Pitvaros, Pusztaf€ oldv ar, T otkoml os, and V egegyh aza) of hydrocarbon exploration work penetrated felsic volcanic rocks, predominantly within the Battonya-Pusztaf€ oldv ar BR (Figs 1c and 2;Szepesh azy 1967;T. Kov acs and Kurucz 1984; Cs asz ar 2005; K} or€ ossy 2005a, b). The highest density of drilling is represented by the ca. 60 km 2 Battonya area ( Fig. 1c) and most of the materials of the presented study derive from there (Szepesh azy 1967; Cs asz ar 2005; K} or€ ossy 2005a). The Permian felsic volcanic rocks are collectively named the Gy} ur} uf} u Rhyolite Formation in the Hungarian lithostratigraphic literature and they form the regionally most widespread Permian formation (F€ ul€ op 1994;Cs asz ar 2005;Szemer edi et al. 2020). Stratigraphically, the basement of the volcanic rocks consists of Permian continental red beds (Korp ad Sandstone Formation) but they are also often underlain by Variscan metamorphic rocks (two-mica schist and gneiss) or S-type granites ("Battonya granite," Fig. 2; T. Kov acs and Kurucz 1984;F€ ul€ op 1994;Cs asz ar 2005;K} or€ ossy 2005a, b). The overlying formation is the Triassic Jakabhegy Sandstone; however, in most cases the volcanic rocks are covered by much younger Cenozoic sediments (e.g., Miocene sandstone). The Permian felsic volcanic rocks were penetrated in their greatest thickness in the T otkoml os-I borehole (∼400 m, Fig. 2; Cs asz ar 2005; K} or€ ossy 2005a). According to the archive reports the felsic volcanic rocks in SE Hungary were described as "quartz-porphyry" and predominantly interpreted as lavas or subvolcanic rocks with subordinate amounts of pyroclastics (Szepesh azy 1967;F€ ul€ op 1994;Cs asz ar 2005;K} or€ ossy 2005a, b). A volcanicplutonic connection was also supposed between the Permian volcanic rocks (thought to be dykes or lavas) and the underlying "Battonya granite" (thought to be Variscan) despite the absence of any geochemical or geochronological evidence (Szepesh azy 1967). Based on the strongly similar stratigraphic column of the T otkoml os-I borehole (i.e., between 2,693 and 3,998 m beneath the surface: Mesozoic sedimentary rocks, Permian volcanic rocks and continental red beds, possible Precambrian granites; K} or€ ossy 2005a), the Battonya-Pusztaf€ odv ar BR was correlated with the Finiş Nappe of the Codru Nappe System (Codru NS), Apuseni Mts, Romania (Szepesh azy 1979; Cs asz ar 2005; K} or€ ossy 2005a). Recently, however, Nicolae et al. (2014) documented crystal-rich, garnet-bearing pyroclastic rocks in the Finiş Nappe, that suggests differences when compared to the Permian volcanic rocks of the aforementioned areas.

MATERIALS AND METHODS
During the second half of the 20th century, hundreds of boreholes were drilled by the legal forerunner of the Hungarian Oil & Gas Company Plc (MOL Rt.) in the eastern Pannonian Basin (Hungary) in order to explore hydrocarbon reservoirs (Szepesh azy 1967; Cs asz ar 2005; K} or€ ossy 2005a, b). The drilling usually ended in Permian felsic volcanic rocks, representing the Paleozoic basement of the Tisza MU (Fig. 2). Drill cores from 17 boreholes (2-3 pieces/ borehole) and 29 thin sections from three subsurface occurrences of the Permian felsic volcanic rocks, namely the Battonya, the Biharugra, and the T otkoml os areas, have been available for the present study at the Department of Table 1. The most important data of the studied samples and boreholes in SE Hungary and the summary of the results of the archive reports and this study. Samples with available whole-rock (major and trace elements) geochemical data are put in italics and bold while samples with zircon U-Pb ages are highlighted by asterisk (data in Szemer edi et al. 2020). Lithofacies (Lf) description are listed in Table 2 Sample code Borehole ( Fig. 1b). The most important data of the sampling sites and the investigated thin sections are summarized in Tables 1 and 2. The studied boreholes in the Battonya area are also highlighted in Fig. 1c. Petrographic studies, including mineralogical and textural observations, were conducted on hand specimen and thin sections. In this study, modal compositions (vol%) were generally estimated based on micropetrography. Nevertheless, modal (volume) proportions of rock-forming minerals, fragments, as well as groundmass were also measured, quantitatively at least, on one selected representative sample of each distinct lithofacies, using a grid of 500 cells for each measurement (Table 3). The terminology used in the petrographic descriptions and interpretations were derived from the following principal references: Table 3. Modal (volume) proportions (in %) of rock-forming minerals, fiammes, as well as the groundmass, measured quantitatively at least, on one selected representative sample of each distinct lithofacies. The meaning of the abbreviations applied for the lithofacies (facies code) are described in Table 2. Abbreviations: bt: biotite, cp: coated particle, f: fiamme, g: groundmass, kfs: K-feldspar, L v : volcanic lithic clast, L nv : non-volcanic lithic clast, pl: plagioclase, qz: quartz. *In the case of lithic-rich, massive, strongly sericitized, poorly-sorted volcaniclastics strongly sericitized groundmass and altered juvenile fragments (fiammes and glass shards) were indistinguishable and given together as groundmass  Gifkins et al. (2005b) Central European Geology 63 (2020) 1, 1-18 , , Henry and Wolff (1992), McPhie et al. (1993), Branney and Kokelaar (2002), Gifkins et al. (2005a, b), Paulick and Breitkreuz (2005), Brown et al. (2012), and Breitkreuz (2013). The most important terms used in the petrographic descriptions and interpretations as well as the abbreviations of each lithofacies name are summarized in Tables 2  and 4, respectively.

RESULTS
Based on the petrographic observations, five distinct lithofacies can be distinguished among the volcanic rock samples (Table 2) which are separately described and interpreted below.
Description. Felsic rocks are purplish or greenish gray in color, and can be classified as massive, non-porous matrixsupported lapilli tuffs that consist of macroscopically dark, flattened, devitrified fiammes (10-12 vol%), usually mm in size, together with various poorly-sorted and fragmented phenocrysts (8-18 vol%) in a fine groundmass of predominantly quartz and feldspar (73-80 vol%).
Well-visible oriented texture (Fig. 3) is defined by deformed, devitrified glass shards (from ∼100 mm up to the  Fig. 3a and c) and devitrified fiammes (from several mm in size up to 1.5-2.5 cm; Fig. 3b, e, and f). In the fiamme rims, axiolites are common, whereas rare spherulites occur inside it (Fig. 3f). Fiammes and altered glass shards in the fine groundmass are replaced by mosaic quartz and feldspar ( Fig. 3b and e). Inside the larger fiammes quartz and feldspar crystals (from 200 to 300 mm up to 1 mm) and secondary minerals (e.g., carbonate, sericite, and opaque minerals) are also present.
Interpretation. The major mineral assemblage (predominantly quartz and K-feldspar, less plagioclase and rare biotite) of the rocks suggests a rhyolitic composition. The unsorted massive appearance points to a pyroclastic flow (ignimbrite) origin. Oriented, eutaxitic texture indicates high-temperature plastic deformation of the vitroclasts (both pumice and glass shards; e.g., Gifkins et al. 2005a, b). Strong devitrification affected the juvenile fragments, creating high temperature crystallization domains (HTCDs ;Breitkreuz 2013). This effect is demonstrated by spherulites inside the fiammes and axiolites at their rims (Fig. 3f). Additionally, incipient to strong welding is indicated by the flattened fiammes and sintering glass shards that determines the observed orientation of the rocks (e.g., Gifkins et al. 2005a, b;Fig. 3a and b), corresponding to the eutaxitic texture mentioned above. Purplish gray color of the macroscopic samples indicates the oxidation of the Fe-phases at high temperature during welding, while the greenish tones point to different degrees of subsequent mineralization (e.g., the formation of celadonite and/or chlorite during secondary alteration processes).
Description. The samples of this group are purplish or greenish-gray in color, and can be classified as massive nonporous matrix-supported felsic volcanic rocks, having a similar mineralogical composition (20 vol% phenocryst content: 61% quartz, 23% K-feldspar, and 16% plagioclase) as the emLT lithofacies (Fig. 3). Crystalloclasts are less common compared to the former lithofacies. The groundmass (70 vol%) predominantly contains fine-grained homogeneous mosaics of quartz, feldspar, and sericite (Fig. 4ac). However, in some parts (e.g., around coarser phenocrysts or separately in the matrix), mm-sized oriented patches (10 vol%, up to 2-2.5 mm) of coarser (150-200 mm) groundmass crystals with the same composition, showing no definite, sharp edge and rarely spherulites inside them, do occur ( Fig. 4d-f). The mentioned patches (Fig. 4d-f) of predominantly quartz and feldspar bear well-visible orientation that could barely be observed macroscopically but always in thin sections in crossed polars (Fig. 4). On the other hand, such an orientation could be observed neither in the fine-grained part of the groundmass (Fig. 4a-c) nor in plane-polarized light in the whole material. According to the observed features, these rocks have a predominantly felsitic, porphyric texture ( Fig. 4a-c); however, the oriented patches of coarser groundmass crystals, resembling altered fiammes, show eutaxitic characteristics (Fig. 4e and f). These two distinct textural features can be commonly observed in one thin section next to each other as is displayed by a representative sample in Fig. 4.
Interpretation. The major mineral assemblage with predominant quartz and K-feldspar phenocrysts suggests the same rhyolitic composition. However, the genetic interpretation (pyroclastic rocks or lavas) of the samples is rather difficult. Parts showing felsitic, porphyric texture with homogeneous groundmass and resorbed, large phenocrysts resemble silicic lavas, apparently suggesting a coherent lava facies origin (McPhie et al. 1993;Fig. 4a-c). However, the mm-sized oriented patches of coarser (150-200 mm) quartz, feldspar, and sericite crystals in the groundmass with no definite, sharp edge ( Fig. 4d-f) could be interpreted as the remnants of devitrified fiammes. Based on the observed features, including the lack of vitroclastic texture and lithic clasts, low crystal breakage, but the presence of lineations (devitrified fiammes), the most feasible is that these samples are high-grade rheomorphic ignimbrites Henry and Wolff 1992). As the result of rheomorphism and/or devitrification, vitroclastic features (i.e., well-visible altered glass shards in the groundmass) are lacking; however, the orientation of the flattened devitrified fiammes (Fig. 4) indicates a rheomorphic flow that postdates or might have occurred during the ignimbrite emplacement and deposition Henry and Wolff 1992). Each step of the spectrum can be seen in Fig. 5 from eutaxitic welded ignimbrites (emLT lithofacies), having a vitroclastic texture with evident altered fiammes and glass shards (a-b) to high-grade rheomorphic ignimbrites (c-f) with barely recognizable remnants of fiammes. Thus, the samples of the rheoLT lithofacies could represent the same ignimbrite sheet as the emLT lithofacies; however, they were formed along slightly different (i.e., higher) temperature and compositional circumstances, e.g., lower volatile content, minimizing the amount of vesiculation, resulting in low explosivity of the eruptions (low crystal breakage) in the Battonya area (Henry and Wolff 1992).
Description. The crystal-poor (quartz: 2 vol%, K-feldspar 8 vol%) sample shows a fine-grained felsitic groundmass (89 vol %) of quartz, feldspar, and sericite with good sorting; however, it differs from all the other samples of the Battonya area in containing mm-sized coated particles (armored pellets, formed around porphyric quartz crystals, 1 vol%; Fig. 6a-c). The size of the particles ranges between 0.8 mm and 1.7 mm (but never reaches the lapilli size: 2 mm), while the quartz crystals in the center range between 0.5 and 0.8 mm.
Interpretation. Armored lapilli and pellets are typical in pyroclastic fallout, flow, and surge deposits formed by ash accumulation around coarser crystals (in this case porphyric quartz) under wet conditions (Brown et al. 2012). In this way the sample could be associated with the ignimbrite lithofacies (emLT and rheoLT), most possibly formed in a pyroclastic ash cloud (air-fall ash deposit). Good sorting of Lithic-rich, massive, strongly sericitized, poorly-sorted volcaniclastics (lmLT) The presence of the lmLT lithofacies was demonstrated in two boreholes in SE Hungary, namely the Biharugra-I and the T otkoml os-K-3 boreholes (see details in Table 1), Vill any-Bihor Unit and B ek es-Codru Unit, respectively (Figs 1b and 2).
Description. The samples are purplish or greenish-gray in color, massive non-porous pyroclastic or volcanogenic sedimentary rocks that consist of completely sericitized juvenile fragments (from ∼100 mm sized glass shards up to 1-2 mm long fiammes; Fig. 7a and f), various fragmented crystals (11-14 vol%, up to mm size) and subrounded lithics (12-15 vol%, up to 2-3 cm, but generally around 1-5 mm; Figs 7e and 8) with a wide range of origin in a fine matrix (69-76 vol%) of sericite, quartz, and feldspar. The mentioned components show very poor sorting in all samples and their proportion is extremely variable.
Very thin bands of sericite up to ∼2.5 mm (showing no preferred orientation) occur in all of the samples (Fig. 7a and   f). Randomly oriented mm-sized patches of sericite can be found in the fine groundmass as well. The aforementioned components are most possibly altered, devitrified juvenile fragments (the former: altered, sericitized fiammes, the latter: sericitized glass shards).
Interpretation. Strongly sericitized juvenile fragments (altered glass shards and fiammes) have an unequivocally pyroclastic origin. The lack of preferred orientation of the pyroclastic material suggests non-welded texture. Crystals could be primary magmatic such as resorbed, magmatic quartz, K-feldspar, plagioclase, and biotite or derive from older igneous and metamorphic rocks (polycrystalline quartz with undulose extinction, microcline, muscovite). Lithics also represent a wide range of origin; volcanic clasts (Figs 7e and 8a-d) are more abundant than lithics from the underlying sedimentary (claystone, siltstone) or metamorphic (mica schist or gneiss) rocks ( Fig. 8e and f). The chaotic texture with various subrounded lithics, juvenile and crystal fragments suggests that sedimentation and volcanic activity could occur simultaneously. The rocks could be interpreted as resedimented volcanic rocks (T otkoml os-K-3) or the more mixed material of the Biharugra-I borehole as a volcanogenic sedimentary rock (tuffaceous sandstone according to the grain size; McPhie et al. 1993).

Spherulitic, vitrophyric lava-like ash tuffs (vlava-likeT)
The presence of the vlava-likeT lithofacies was demonstrated in the T otkoml os-I borehole (Figs 1b and 2), B ek es-Codru Unit. Drill cores from 3 separate depths were observed (drill cores 13-15, see details in Table 1). In this area, corresponding to a separated tectonic block of the basement, the Permian sequence is covered by Mesozoic sedimentary basement formations (Fig. 2). The cores exposed felsic volcanic rocks in a minimum thickness of 156 m; however, they are petrographically rather homogeneous; only the lowest part of the sequence (drill core 15) differs in being strongly deformed in brittle style (brecciated).
Description. Samples of the T otkoml os-I borehole show vitrophyric texture with 10 vol% quartz and altered feldspar phenocrysts in a devitrified, completely spherulitic groundmass (90 vol%; Fig. 6d and e). The diameter of the spherulites range between 50 and 100 mm. On the other hand, no additional textural features (i.e., remnants of juvenile fragments) could be observed. The major mineral assemblage is rather similar to the ignimbrites of the Battonya area with porphyric (up to 1-2 mm) euhedral or subhedral quartz (55 vol%; Fig. 6d and f) and sericitized or carbonatized feldspar crystals (45 vol%; Fig. 6f), showing low-crystal breakage.
Interpretation. According to the mineralogical composition, the samples of the T otkoml os-I borehole are rhyolites; AGK-1340-2, fragmented quartz and euhedral biotite crystals. (e) Sample AGK-1267, muscovite and felsic volcanic lithic clast, having felsitic texture. (f) Sample BATR/1, porphyric microcline, broken quartz crystals and sericitized juvenile fragments. Abbreviations: bt: biotite; f: altered fiamme, fsp: feldspar, L: lithic clast, mc: microcline, ms: muscovite, qz: quartz, PPL: plane polarized light, XPL: crossed polars however, their genetic interpretation is very complicated. Spherulitic texture suggests high-temperature crystallization which could be the feature of the inner part of both lavas and welded ignimbrite sheets (Breitkreuz 2013). Although the thickness (∼150 m, measured from borehole data, Table 1) and some textural features (e.g., spherulites in microcrystalline matrix) are consistent with the central part of silicic lavas (Orth and McPhie 2003), the altered vitroclastic groundmass, broken phenocrystals, and compositional similarity to all the other studied lithologies (i.e., pyroclastic rocks) might indicate a pyroclastic origin. The spherulite and groundmass crystallization could occur in the interior of the unit under moderate cooling conditions (ΔT: 50-200 8C, Swanson et al. 1989). Lower breccia zones could generally point to brittle fragmentation near the flow base; however, in this case, taking into consideration the tectonic evolution of the T otkoml os area (see details of the local faulting in Fig. 2), it is more probable that tectonic deformation and brecciation occurred. In some samples, the entire rock, even the spherulitic matrix, is crosscut by fractures.

Petrographic (re)interpretations according to the new observations and archive reports
New petrographic observations resulted in a quite different approach to Permian volcanism in SE Hungary. The detailed description and classification of textural features allow us to distinguish between different transport and emplacement mechanisms associated with effusive and explosive eruption styles. Based on the variations in lithology, the studied samples were identified mainly as pyroclastic rocks (predominantly ignimbrites) and volcanic sediments. The textural investigations established the discrimination of two major lithofacies groups: (i) the Battonya area is represented by crystal-poor (8-20 vol%) welded (with eutaxitic texture: emLT) and rheomorphic ignimbrites with rhyolitic composition that often resemble lavas (rheoLT), while, the other group (ii) consists of AGK-1267, polycrystalline metamorphic quartz. Abbreviations: bt: biotite, fsp: feldspar, qz: quartz, s: altered glass shard, PPL: plane polarized light, XPL: crossed polars strongly sericitized, lithic-rich, reworked pyroclastic (probably non-welded ignimbrites) and volcanogenic sedimentary rocks that occur in the T otkoml os and Biharugra areas, respectively (lmLT).
Interpretation of rheomorphic ignimbrites was difficult as they do not have vitroclastic groundmass and show low crystal breakage. However, oriented and devitrified fiammes in these rocks without sharp, definite edge serve as potential evidence of their rheomorphic origin. Such parts of the samples were previously interpreted as the alternation of volatile-rich and volatile-poor bands within the presumed lava flow by Szepesh azy (1967). It is important to note that, in the ca. 60 km 2 area (Fig. 1c), all felsic volcanic rocks are derived from similar well depths of the boreholes (Table 1; Fig. 2). Their average minimum thickness is around 20 m (with no information about the whole thickness of any volcanic sequences near Battonya), and the calculated minimum volume of the volcanic products is 1.2 km 3 . The lack of characteristic lava-associated facies variations (e.g., no brecciated lava carapace facies) in an area that could be commensurable with a rhyolitic lava flow (or dome) rather points to an ignimbrite sheet that consists of altered crystalpoor, fiamme-bearing lapilli tuffs with rhyolitic composition formed under distinct steps of the ignimbrite grade continuum Henry and Wolff 1992). Most possibly, however, only a piece of an ignimbrite sheet was drilled in the Battonya area, as both conventional and rheomorphic ignimbrite sheets are generally much more extensive (their length is up to ∼60 km and max. thickness is ∼100 m; Henry and Wolff 1992). The Battonya-7 borehole encountered a pyroclastic rock with armored pellets (around quartz crystals; accfrichT), suggesting its formation in a pyroclastic ash cloud under wet conditions. Beside the fact that such coated particles are so far unique regarding the Permian volcanism of the Tisza MU, they reinforce the explosive origin of the surrounding rocks (i.e., rheoLT facies < 1 km away). Moreover, Permian volcanic rocks of the Tisza MU are dominantly felsic ignimbrites, while lavas are rather subordinate (Nicolae et al. 2014;Szemer edi et al. 2016Szemer edi et al. , 2017Szemer edi et al. , 2018Szemer edi et al. , 2020. Reworking of such pyroclastic rocks could result in the volcanogenic sedimentary sequences of the Biharugra and the T otkoml os areas that are rich in volcanic lithics and sericitized juvenile fragments. These rocks could have been formed in a basin where volcanic and non-volcanic sedimentation occurred at the same time. Such volcanogenic sedimentary rocks are also known from the Western Mecsek Mts within the Cserdi Conglomerate Formation that covers the Permian felsic volcanic rocks in that region (Varga 2009). The various volcanic lithics in lmLT might suggest multiple-phase Permian volcanic activity that was also documented from the Apuseni Mts (Codru NS; Nicolae et al. 2014). In the T otkoml os-I borehole, the felsic volcanic rocks (drill cores from three distinct depths) have vitrophyric texture, completely spherulitic groundmass and minor broken crystals. Based on these features (with the lack of altered fiammes) it is not possible to interpret the samples unequivocally (ignimbrites or lavas); however, it is the most probable that they represent the ultimate step of the ignimbrite grade continuum as lava-like ash tuffs (vlava-likeT;Henry and Wolff 1992). However, being part of a tectonic block separate from the Battonya area (Fig. 2), it is also possible that these samples represent a completely distinct (i.e., younger or older) volcanic episode.
According to the previous petroleum exploration reports (Szepesh azy 1967; K} or€ ossy 2005a) a direct plutonic-volcanic relationship was supposed between the "Battonya quartzporphyry" (thought to be Lower Permian) and the underlying Variscan "Battonya granite." This view was based on the interpretation that the former represents either subvolcanic or surficial lavas that continue as granite towards crustal depths. Our new volcanological interpretation precludes such a direct connection between the ignimbrite and the underlying granite and suggests tectonic or erosional unconformity between them.

Syn and post emplacement textural development
As ancient volcanic rocks might be affected by various processes of alteration, their primary (syn) and secondary (post emplacement) textural features could be rather difficult to distinguish (e.g., Allen 1988;Henry and Wolff 1992;Gifkins et al. 2005a, b). Based on the petrographic observations of the studied rocks, various lithofacies were distinguished (Table 2); however, some general textural features do deserve additional discussion. All of these features are summarized in Table 5, and the relative timescale of the related processes is displayed in Fig. 9, which is based on several experimental and volcanological case studies (Lofgren 1971;Swanson et al. 1989;Stevenson et al. 1994;Orth and McPhie 2003;Breitkreuz 2015). Primary (magmatic) phenocrysts are similar in all lithofacies, suggesting compositionally similar rhyolitic sources (crystallization above 850-800 ºC and low ΔT; Swanson et al. 1989). Microcrystalline groundmass of quartz, feldspar, and sericite is also a common feature of the studied samples. Felsitic textures suggest pervasive groundmass crystallization simultaneously and after microlith formation (at high ΔT; Swanson et al. 1989), while spherulite formation as another type of post emplacement high-temperature (800-500 ºC) groundmass crystallization occurred at restricted point sources at moderate (50-150 ºC) ΔT (vlava-likeT; Swanson et al. 1989;Breitkreuz 2013).
Volcanic and non-volcanic lithics were ripped by explosive eruptions and represent older components than the host material. Coated particles were formed by ash accumulation around coarser crystals under wet conditions in the ash cloud of eruption or pyroclastic density flow (Brown et al. 2012).

Local and regional correlation
Based on the Mesozoic evolution (Alpine nappe stacking) of the Tisza MU, the B ek es-Codru Unit was correlated with the Codru NS, Apuseni Mts (Szederk enyi et al. 2013 and references therein; Fig. 10). Thus, the area of this study (based on the lithological sequence of the T otkoml os-I borehole) was correlated with the Finiş Nappe, Codru NS (Szepesh azy 1979; K} or€ ossy 2005a; Fig. 10). Regarding the petrography, however, significant differences were found between the samples of the Codru NS (Finiş, Dieva, and Moma Nappes, based on Nicolae et al. 2014) and the felsic volcanic rocks of SE Hungary (B ek es-Codru Unit). Pyroclastic rocks in the Apuseni Mts are crystal-rich (∼40 vol%) and contain abundant biotite, altered pyroxene, and accessory garnet crystals (Nicolae et al. 2014;Szemer edi et al. 2018). On the other hand, the samples of this study show much lower crystal content (8-20 vol%); biotite is very rare and no pyroxene or garnet crystals were identified. Neither is any evidence of bimodal Permian volcanic rocks known from the boreholes of SE Hungary, while in the Codru NS cogenetic basalts and subordinate andesites also occur (Nicolae et al. 2014).
Such petrographic differences were also found between the Permian felsic volcanic rocks of southern Transdanubia and the samples of this study. In the Western Mecsek Mts and M ariak em end-B ata BR, crystal-rich (40-45 vol%) ignimbrites occur that contain hematitized biotite and strongly altered pyroxene as mafic components (Szemer edi et al. 2016(Szemer edi et al. , 2020. At the northern foreland of the Vill any Mts similar (biotite and pyroxene-bearing) ignimbrites with accessory garnet are present and they are accompanied by subordinate felsic lavas (Szemer edi et al. 2017). flattened (qz, fsp) À À thin bands (ser) À Fiammes flattened (qz, fsp) flattened (qz, fsp) À irregular (ser) À Broken phenocrystals þþ þ À þþþ þ Lithics À À À þ þ À Non-volcanic lithics À À À þ þ À Coated particles À À þ þ À À Figure 9. The relative timescale of the most significant processes in textural development of the Permian felsic volcanic rocks. Each process is marked by its representative lithofacies (modified after Lofgren 1971;Swanson et al. 1989;Stevenson et al. 1994;Orth and McPhie 2003;Breitkreuz 2015) The mentioned petrographic differences are consistent with the slighter geochemical and geochronological distinctions revealed by our previous studies (Szemer edi et al. 2020). According to the immobile element-based rock classification (Zr/TiO 2 vs. Nb/Y; Winchester and Floyd 1977), felsic volcanic rocks in SE Hungary are predominantly rhyolites (samples of this study), while felsic volcanic rocks from southern Transdanubia and the Apuseni Mts (Nicolae et al. 2014) are rhyodacites-dacites. The immobile element (high field strength elements, rare earth elements) patterns are rather uniform for all Permian volcanic rocks of the Tisza MU; however, the highest values are shown by the samples of SE Hungary in both light and heavy rare earth elements (Szemer edi et al. 2020). Regarding the geochronological results (zircon U-Pb ages), the samples of this study are slightly younger (259.5 ± 2.6 Ma from BATR/1 and BATR/2 samples, T otkoml os-K-3 borehole) than all the other Permian felsic volcanic rocks of the Tisza MU, which range between 263.4 ± 2.7 and 266.8 ± 2.7 Ma (Szemer edi et al. 2020).

Emplacement of the Permian felsic volcanic rocks in SE Hungary within the Permian volcanic system of the Tisza Mega-unit
The new results suggest that the Permian felsic volcanic rocks in SE Hungary (Battonya, Biharugra, and T otkoml os areas) might represent the youngest and most evolved, crystal-poor rhyolitic magmas of a large-volume silicic (crystal-rich rhyodacitic-dacitic) volcanism with slighter geochemical, geochronological, and remarkable petrographic differences compared to other Permian felsic volcanic rocks in the Tisza MU. Based on the Alpine evolution of the Tisza MU, the B ek es-Codru Unit was correlated with the Codru NS (Apuseni Mts; Fig. 10); however, Permian felsic volcanic rocks in SE Hungary do not show any correlation with similar rock types (felsic ignimbrites) in any nappes of the Codru NS (based on Nicolae et al. 2014): neither the garnet-bearing crystal-rich samples of the Finiş Nappe (as was supposed by Szepesh azy 1979), nor the ignimbrites of the Dieva and Moma Nappes that are part of the bimodal volcanic suite (Nicolae et al. 2014). Such crystalpoor ignimbrites are unknown as yet from the Tisza Megaunit and might represent a petrographically and geochemically distinct, younger (∼259 Ma; Szemer edi et al. 2020) episode of the Permian volcanism in the Pannonian Basin. CONCLUSIONS 1. Permian felsic volcanic rocks in SE Hungary were previously described and interpreted in the archive reports of petroleum exploration predominantly as lavas ("Battonya quartz-porphyry"). We showed that they are predominantly welded or rheomorphic (Battonya area), rarely lava-like ignimbrites (T otkoml os-I borehole), and reworked pyroclastic/volcanogenic sedimentary rocks (T otkoml os and Biharugra areas). 2. Volcaniclastites from the Biharugra and the T otkoml os areas consist of various felsic volcanic and non-volcanic lithics and might suggest a multiple-phase Permian volcanic activity that was also documented from the nearby Apuseni Mts, Romania (Codru Nappe System; Nicolae et al. 2014). 3. Felsic volcanic rocks in SE Hungary belong to the Permian volcanic system of the Tisza Mega-unit; however, some significant petrographic differences (crystalpoorness, rare biotite, no pyroxene or garnet crystals)