A new A-type granitoid occurrence in southernmost Fennoscandia: geochemistry, age and origin of rapakivi-type quartz monzonite from the Pietkowo IG1 borehole, NE Poland

Rapakivi-type quartz monzonite and the underlying dark-grey granodiorite from the Pietkowo IG1 borehole, in the Polish part of southernmost Fennoscandia have been investigated using whole-rock geochemistry, Sm–Nd isotope geochemistry and U–Pb zircon dating. The quartz monzonite was emplaced at 1495–1491 Ma, although slightly older zircon cores (antecrysts) of 1513 Ma imply a two-stage crystallization. The geochemical similarities with Mazury Complex granitoids, their metaluminous and alkali-calcic nature, elevated contents of F, Ga and high-field-strength-elements (HFSE), indicate that the Pietkowo IG1 rapakivi-type quartz monzonite is an ‘A-type’ granitoid. The presence of magnetite and titanite indicates crystallization under oxidizing conditions. The rock is classified as A2 sub-type, and the Nb/Y ratio implies a within-plate setting. The dark-grey granodiorite, dated to 1813 Ma, has a calc-alkaline character, typical of a volcanic-arc environment. Initial whole rock εNd values range between -2.9 and -3.3 for the rapakivi-type quartz monzonite and from -1.0 to + 1.1 for the dark-grey granodiorite. We suggest that the A-type Pietkowo IG1 rapakivi-type quartz monzonite was generated from the dark-grey granodiorite via partial melting at middle to lower crustal levels. The most plausible ascent route for the quartz monzonite was via lithospheric-scale weakness zones, between the eastern margin of the Mazowsze Domain and Belarus-Podlasie Granulite Belt, i.e., the Białystok fault. Therefore, the Pietkowo IG1 rapakivi-type quartz monzonite is a representative of the Mesoproterozoic A-type granitoid occurrence in southernmost Fennoscandia.


Introduction
A-type granites, originally distinguished by Loiselle and Wones (1979), were firstly defined as anhydrous felsic rocks with high contents of alkalis and abundant HFSE (e.g. Frost et al. 2001;Bonin 2007). Chemically A-type granites can be classified as ferroan, calc-alkaline to alkaline-calcic granitoids (Frost et al. 2001). They are inferred to occur in stable continental terranes or rift zones (Loiselle and Wones 1979; 1 3 of numerous petrogenetic studies. An overview has been presented by . Rapakivi granites, defined as A-type granites nowadays, form a few major exposed batholiths including the most prominent bodies of the Salmi in Russian Karelia (Fig. 1A), Riga in western Latvia (Fig. 1A) and the most classical Wiborg batholith in Finland (Fig. 1A), as well as many minor intrusions (Andersson 1997) emplaced within heterogeneous Proterozoic crust of the Baltic Shield. These types of igneous bodies have also been geophysically detected underneath platform sediments covering the southern part of the Fennoscandian block, whereas most of them have been drilled (Bogdanova et al. 2006(Bogdanova et al. , 2015. A significant manifestation of AMCG magmatism is present also within the crystalline basement of northeastern Poland, near the SW margin of the East European Craton (EEC; Fig. 1A, B), constituting a complex of intrusions located latitudinally along the border between Poland, Belarus and Lithuania and known in the region as the Mazury Complex (MC). This complex is well documented by numerous drillings, therefore all AMCG members have been confirmed (Bagiński et al. 2001;Dörr et al. 2002;Skridlaite et al. 2003;Gawęda et al. 2009;Duchesne et al. 2010;Wiszniewska and Krzemińska 2021). The MC is commonly listed among other prominent examples of rapakivitype granitoid and anorthosite massif occurrences Ashwal 2010;Salminen et al. 2021). Granitoids of the MC (e.g. from the Boksze 1, Krasnopol 6, Filipów 1, Łopuchowo IG1 boreholes; Fig. 1B) show features characteristic for A-type granites (Collins et al. 1982;Clemens et al. 1986;Whalen et al. 1987;Creaser et al. 1991;Frost and Frost 1997).
Within the Polish crystalline basement, over 170 kmsouth of the MC, another granitoid occurrence at a depth of ~ 1 km has been recognized. The intrusion was first defined by regional magnetic and gravity surveys ( Fig. S1; Kubicki and Ryka 1982) and drilled by the Pietkowo IG1 borehole in 1976 (Fig. 1B). The lower part of the Pietkowo IG1 profile is composed of the dark-grey granitoid , whereas, in the upper part of the drilling granitoids ( Fig. 2) with a characteristic porphyritic (rapakivi-type) texture composed of larger K-feldspar phenocrysts were found (Fig. 3E, F). This upper intrusive granitoid phase has not previously been described, but it seems to be similar to granitoids from the MC, where this texture was commonly referred to as rapakivi or rapakivi-like (Ryka and Podemski 1998;Bagiński et al. 2001).
In this contribution, we report sensitive high resolution ion microprobe (SHRIMP) U-Pb zircon ages, whole-rock geochemistry and Sm-Nd isotopic compositions for the Pietkowo IG1 igneous body. The newly obtained data are discussed together with granitoid data selected from the Mazury AMCG suite, and compared to features of classical rapakivi batholiths collected from previous studies in order to assess a genetic link between Mesoproterozoic AMCG suites with A-type or 'anorogenic' granites, emplaced within the composite and heterogeneous Proterozoic crust of Fennoscandia during a few distinct pulses of ~ 1.6-1.4 Ga.

Geological setting
The EEC comprises three protocontinents: Fennoscandia, Sarmatia and Volgo-Uralia, which experienced distinct tectonic and metamorphic evolutions until their final collision at ca. 1.8 Ga (Bogdanova et al. 2015;Salminen et al. 2021). Concurrently, significant crustal growth of Fennoscandia took place during Paleoproterozoic subduction-collision episodes of the Svecofennian orogeny (Bogdanova et al. 2006(Bogdanova et al. , 2015. The accretion of island arcs and microcontinents led to the formation of several tectonic units with igneous ages generally decreasing towards south-southwest from 1.86 to 1.84 and 1.84-1.81 Ga to 1.81-1.76 Ga. The crystalline basement of NE Poland represents a hidden, under the Phanerozoic sedimentary strata, part of the Fennoscandian craton, located south of its exposed part in the Baltic Shield. The major tectonic units in the basement of NE Poland are the Mazowsze (MD), Dobrzyń (DD) and Pomorze-Blekinge Belt (PB) domains (Fig. 1A, B; Krzemińska et al. 2017), which extend to the SW margin of the EEC defined as the Teisseyre-Tornquist Zone (TTZ; Fig. 1A, B; Dadlez et al. 2005;Narkiewicz et al. 2015).
At ca. 1525-1500 Ma, the area of northeastern Poland was affected by intensive bimodal and multi-stage magmatism consisting of several smaller magmatic bodies (Lorenc and Wiszniewska 1999) together constituting the E-W oriented belt of the MC (Fig. 1A, B), dominated by granitoids of leucogranite to granodiorite and monzodiorite composition (Bagiński et al. 2001;Skridlaite et al. 2003;Wiszniewska et al. 2007;Duchesne et al. 2010). MC granitoids show features characteristic of A-type granites (Collins et al. 1982;Clemens et al. 1986;Whalen et al. 1987;Creaser et al. 1991;Frost and Frost 1997), i.e., high potassium content and extreme enrichment in iron, resulting in high K/Na and Fe/Mg ratios, notable low H 2 O content, high Ga, HFSE and rare earth element (REE) abundances, low Al, Mg, Ca, Sr, Ba and Cr concentrations, as well as the presence of the rapakivi(-like) texture (Bagiński et al. 2001;Gawęda et al. 2009;Duchesne et al. 2010). Other significant components of the MC are anorthositic-gabbroitic-noritic intrusions of the Kętrzyn, Suwałki (SAM; Fig. S1) and Sejny massifs . Thus, the MC is a component of the AMCG suite (Emslie 1991;. The newest U-Pb zircon SHRIMP ages indicate that rapakivi-type granitoids of the MC were intruded in Fig. 1 A Major Paleoproterozoic tectonic domains of Fennoscandia (modified after Bogdanova et al. 2015). The yellow rectangle shows the area presented in Fig. 1B; B Geological map of the crystalline basement of NE Poland and surrounding area (modified after Bogdanova et al. 2015). The yellow rectangle shows the area presented in Fig. S1   .
The new case of the rapakivi-type granitoid intrusion, drilled only by the Pietkowo IG1 borehole, is located some 170 km south of the MC and intrudes the older crystalline rocks of the MD (Fig. 1A, B). The MD generally consists of metamorphosed greywackes and shales, with intercalations of volcanogenic material. At 1830-1800 Ma metasediments were affected by bimodal magmatism examined in, for example, the Łomża IG1, Okuniew IG1, Jastrzębna IG, Rajsk IG1, Rajsk IG3 and Pietkowo IG1 boreholes ( Fig. 1B; Krzemińska et al. 2005Krzemińska et al. , 2007Williams et al. 2009). Therefore, they represent a classical Svecofennian sequence of low to medium grade immature metasediments, volcanogenic amphibolites and later granitoids, but slightly younger (Williams et al. 2009) than those in Scandinavia (Korja et al. 2006).
The Pietkowo IG1 borehole reaches 1340 m b.g.l. Based on lithology, it can be subdivided into three parts (Fig. 2) described below. (1) The sedimentary cover (0-920 m) is dominated by sandstones, shales and mudstones deposited in the Ediacaran to early Cambrian and in the early Triassic. The Cretaceous is composed mostly of carbonates of chalk-type facies, whereas Cainozoic strata are characterized by the presence of unconsolidated, clastic sediments (Poprawa 2019). (2) In the middle part of the profile pinkish-grey to reddish-grey porphyritic (rapakivi-type) granitoid occurs (920-1303 m; Fig. 3A-C, E, F). Its rapakivi-type texture is very similar to that observed in the MC. (3) In the last 37 m of the drill core (1303-1340 m) dark-grey medium-grained granitoids occur (Fig. 3D). They were dated to 1818 ± 15 Ma and interpreted as a representative of 1830-1800 Ma granitoids intruding the metasediments of the Svecofennian basin ). The middle part of the Pietkowo IG1 drill-section, including rapakivi-type granitoids, is the main focus of this study.

Sampling
Representative samples of the rapakivi-type granitoid and the dark-grey granitoid (Table 1) were collected from the Pietkowo IG1 drill core in the Polish Geological Institute-National Research Institute storehouse in Szurpiły. Samples of the rapakivi-type granitoid with different mineral proportions were chosen. Locations of samples for mineral chemistry, whole-rock geochemistry, zircon U-Pb SHRIMP dating and Sm-Nd isotope analysis are shown in Fig. 2.

Whole-rock geochemistry
Samples selected for whole-rock geochemical analyses (Table 1) were coarsely crushed by a hammer and pulverized in a corundum planetary ball-mill. Powders were subjected to a lithium borate fusion. Major elements contents were measured by means of Spectro Ciros Vision inductively coupled plasma -emission spectrometer (ICP-ES), trace elements were measured by PerkinElmer ELAN 6000 Fig. 3 Macrophotographs of rocks from the Pietkowo IG1 borehole: A pinkish-red quartz monzonite, depth 1041 m, sample P-1041 for U-Pb dating; B granite with visible porphyrocrysts of pink K-feldspar forming a rapakivi-like texture, depth 1138 m, sample P-1138 for U-Pb dating and Sm-Nd isotopes analysis; C light-grey granite with single porphyroclasts of pinkish K-feldspar, depth 1303 m, sample P-1303a for Sm-Nd isotopes analysis; D fine-grained grey granodiorite of the Paleoproterozoic age, depth 1305 m, sample P-1305 for Sm-Nd isotopes analysis; E fragment of the Pietkowo borehole with a clearly visible rapakivi-like texture, porphyrocrysts of pinkish K-feldspar with thin oligoclase rim, depth 1300 m; F clear change in colour of K-feldspars with depth, from red in the upper part to light pink in the lower part, with a simultaneous decrease in the porphyritic feldspar content down the profile, samples from depths: 1138 m (P-1138 sample), 1186 m (P-1186 sample), 1257 m (P-1257 sample), 1305 m (P-1305 sample) one by one from the top or ELAN 9000 inductively coupled plasma -mass spectrometers (ICP-MS), and F content was measured by specific ion electrode. Detection limits for each element are listed in Table 2. All analytical data were calculated on an anhydrous basis.

Sm-Nd isotope geochemistry
Samples for Nd isotopic analyses (Table 1) were ground to a fine powder with an agate mortar and pestle. Approximately 4 mg of sample powder were spiked with a mixed 149 Sm/ 150 Nd spike and dissolved with mixed HF-HNO 3 (4:1). Separation of Nd and Sm was achieved on 2 ml columns packed with Eichrom Ln resin. Details of the analytical procedure are described in Dopieralska (2003). Nd and Sm (loaded as phosphate) were measured in a Re double filament configuration. Nd was analyzed in dynamic collection mode and Sm was measured in static mode on a Finnigan MAT 261 multi-collector thermal ionization mass spectrometer. Repeated measurements of the AMES standard were conducted. Nd isotope data are reported in the standard epsilon notation (ε) calculated using 143 Nd/ 144 Nd = 0.512638 and 147 Sm/ 144 Nd = 0.1967 for present-day (0) chondritic uniform reservoir (CHUR (0) ; Jacobsen and Wasserburg 1980). All ε Nd values are recalculated according to the measured 147 Sm/ 144 Nd ratios for the time of intrusion (t).

U-Pb zircon geochronology
Samples for geochronological investigation were taken from the rapakivi-type granitoid from depths of 1041 m, 1138 mand 1257 m and from the dark-grey granitoid from a depth of 1317 m ( Table 1). The typical procedure for zircon separation was applied. It include a sequence of steps: crushing, sieving and standard magnetic and density discrimination procedures to final hand-picking under a binocular. Extracted zircon grains were then mounted in epoxy resin together with crystals of Temora 2 and 91500 standards and polished until quasi-central sections were reached. The internal structure of the zircon grains, such as the pattern of zoning, internal domains and alteration were characterized utilizing the cathodoluminescence (CL) detector on a Hitachi SU3500 scanning electron microscope (SEM-CL). The mount surface was evaporatively coated with 10 nm Au of high purity. The U-Pb isotopic dates of selected spots on individual zircon grains were determined using the SHRIMP IIe/MC ion microprobe at the Polish Geological Institute-National Research Institute in Warsaw, Poland according to the general methodology described by Williams (1998). SHRIMP analyses were conducted using an 16 O − primary beam. Prior to each analysis, the surface of the analysis site was precleaned by rastering of the primary beam for 1.5-2 min, to reduce or eliminate surface common Pb. The sputtered area used for analysis was ca. 20-25 µm in diameter. The mass resolution was 5400 M/ΔM (at 10% peak height). During two analytical sessions on Pietkowo IG1 zircons, the count rates of nine masses were sequentially measured over 6 scans. The raw data were reduced using the SQUID Excel Macro of Ludwig (2009). The zircon U-Pb ratios were normalized relative to the Temora 2 reference zircon equivalent to 206 Pb*/ 238 U = 0.06683 and age of 416.8 Ma (Black et al. 2003). The common Pb was estimated from 204 Pb counts. Analytical uncertainties for two sessions are given in the footnotes of Table S6 in the electronic supplementary material (ESM2). Errors given on individual analyses are  based on counting statistics and are at the 1 sigma. Errors for pooled analyses are at 2 sigma. The ages and errors of intercepts of the best-fit line with concordia were calculated using the Isoplot program (Ludwig 2003). The mean square of weighted deviates (MSWD) and probability of fit values are given in the text and on the concordia diagrams. Throughout two analytical sessions, Temora 2 zircons were analyzed every three sample spots provided mean 206 Pb/ 238 U ages of 416.7 ± 2.9 Ma (n = 15) and 416.8 ± 1.9 Ma (n = 20), accurate to reference values ( 206 Pb/ 238 U age of 416.78 ± 0.33 Ma) of Black et al. (2004) obtained by thermal ionization mass spectrometry (TIMS). As a comparison, the U-Th-Pb results previously obtained from one dark-grey granitoid sample, depth 1317 m ), were also attached. This sample was only briefly presented in the form of an abstract without analytical data. This zircon sample (depth 1317 m) was analyzed on SHRIMP II ion microprobe at the Australian National University in Canberra, Australia based on techniques described by Williams (1998). In the present contribution the data were re-calculated again using Isoplot program (Ludwig 2003).

Rapakivi-type granitoid
The rapakivi-type granitoid shows a porphyritic non-oriented texture with feldspar megacrysts (~ 2-3 cm) embedded in a finer-grained groundmass. A few ovoidal megacrysts are partially mantled by a thin shell of creamy plagioclase, however, most of them do not develop the plagioclase mantles (Fig. 3E, F). The rapakivi-type granitoid does not show a uniform phase composition through the Pietkowo IG1 profile.
There is a clear change in color of alkali feldspars with depth ( Fig. 3F), from red in the upper part of the profile (P-950, P-1041, P-1119, P-1138, P-1186 samples) to light pink in its lower part (P-1208, P-1257, P-1303a samples). Samples from the upper part of the profile show a relatively high content of alkali feldspar (30-40 vol%), with quartz content of 20-30 vol% and plagioclase of 35 vol%. Phenocrysts of red alkali feldspar show compositions from Or 88 to Or 97 with an Ab content up to 12 mol% (Table S1; Fig. S2A). The concentration of Ba in alkali feldspar is low (0.3-0.6 wt%; Cs 0.6-1.1 ; Fig. S2C). Alkali feldspar contains perthitic exsolutions, which show a widespread composition of An 3-27 with an Or content up to 6.30 mol% (Table S2; Fig. S2A). The plagioclase is oligoclase, with an An content between 17 and 28 mol% (Table S2; Fig. S2A). Plagioclase grains show slight oscillatory zoning, with more calcic cores (An 28 ) and sodic rims (An 22-25 ). Iron is usually responsible for the red color of alkali feldspars, but the Fe content is low and does not exceed 0.16 wt% FeO (Fig. S2B).
Samples from the lower part, compared to granitoid samples from the upper part, are characterized by a definitely lower content of alkali feldspar (20-30 vol%), with, however, a very similar composition of Or 93-96 mol% and Ab 4-8 mol%. Moreover, these samples have a high content of plagioclase (ca. 40 vol%) and quartz (25-35 vol%). Plagioclase grains display a diverse composition, from oligoclase to andesine, with An content between 19 and 44 mol% (Table S2; Fig. S2A), with a tendency to a more calcic core (An = 27-44 mol%) and sodic rim (An = 19-26 mol%). Down the profile the FeO content in plagioclase decreases and in the P-1303a sample does not exceed 0.13 wt%.
F-rich biotite (mostly 2.02-3.01 wt% F) is the only mafic mineral with a constant content through the profile of the rapakivi-type granitoid (ca. 5 vol%). It is classified as phlogopite (Table S3; Fig. S2D) and displays very limited Fe/  (Table S4). Titanite probably does not contain a significant H 2 O content, as suggested by EPMA microanalyses with totals near 100 wt%. The rapakivi-type granitoid is rich in coarse interstitial magnetite grains of amoeboid shape. The content of Ti is usually below the detection limit, whereas Cr and V concentrations do not exceed 0.04 wt% and 0.26 wt%, respectively (Table S5). Abundant apatite and zircon, as well as epidote and allanite, are present as accessory minerals.

Dark-grey granitoid
The dark-grey granitoid is moderately deformed, with an oriented fabric at the bottom part of the drilled sequence. It is macroscopically uniform -equigranular, medium-grained and felsic, with occasional larger grains of plagioclase ( Fig. 3D) or alkali feldspar. The dark-grey granitoid has a constant mineral composition with ca. 30 vol% of quartz, 15 vol% of alkali feldspar and ca. 25 vol% of plagioclase. Biotite is abundant (ca. 15 vol%), definitely more common than in the rapakivi-type granitoid. The rock contains also small amounts of amphibole (hornblende; Krzemińska et al. 2007). Accessory minerals include titanite, apatite, zircon and Fe-Ti oxides. Alkali feldspar, with a composition similar to this from the rapakivi-type granitoid (Or 88 to Or 97 ; Table S1, Fig. S2A, C), contains 0.46-1.30 wt% BaO (Cs 0.8-2.4 ).
Magnetite is slightly enriched in Cr (up to 0.28 wt%), V (up to 0.36 wt%) and Ti (up to 0.30 wt%; Table S5). Some magnetite grains mantled large titanite.

Geochemistry
Preliminary data for the chemical composition of the darkgrey granitoid from the Pietkowo IG1 borehole were published by Krzemińska et al. (2007), however, no whole-rock chemical analyses were performed for the rapakivi-type granitoid. New whole-rock geochemical analyses for both rock types are shown in Table 2.
The rapakivi-type granitoid, with a high alkali sum of 7.8-9.5 wt% (Na 2 O + K 2 O) at SiO 2 contents of 63.0-68.7 wt% (Table 2; Fig. 5E), is quartz monzonite according to the total alkali-silica (TAS) diagram of Middlemost (1994). MgO and total FeO (FeO t ) contents are 0.80-1.29 wt% and 3.35-5.79 wt%, respectively (Table 2; Fig. 5A, B), whereas the Mg# (Mg/(Mg + Fe 2+ )) values are within the range of 0.13-0.19. The rapakivi-type quartz monzonite is metaluminous, with Aluminous Saturation Index (A/CNK = molar ratio of Al 2 O 3 /(CaO + Na 2 O + K 2 O)) ranging from 0.92 to 0.98 (Fig. 4A). Following the Frost et al. classification (2001), most samples are ferroan and magnesian and alkalicalcic to calc-alkalic (Fig. 4B, C). Slightly different wholerock chemical composition shows sample P-1303a -with higher FeO t and CaO contents it is calcic. This sample has a lower alkali content (5.79 wt%) and on the TAS diagram plots in the granodiorite field. The F contents in the rapakivi-type quartz monzonite range from 2630 to 2730 ppm (Table 2). On major element Harker diagrams (Fig. 5) the rapakivi-type quartz monzonite forms common trends with other granitoids of the MC, but have much higher silica contents. For most major elements, there is a clear link between the content of individual elements and the content of SiO 2 . The reverse relationship between SiO 2 and Fe, Mg, Ti and P (Fig. 5A, B, D, F) may indicate the liquid line of descent trend. Trace elements from the rapakivi-type quartz monzonite show negative correlation for Nb, Y, Zr, V (Fig. 6A, D, E, F) and Th and La (not shown) against SiO 2 . The quartz monzonite exhibits relative depletions in Sr (313-414 ppm), Zr (372-1048 ppm) and V (37-71 ppm) compared to MC granitoids. Noteworthy, all these trends are disturbed by the P-1303a sample with lower Nb and Y and higher Nd, Zr, La, Th and V contents.
Chondrite-normalized REE patterns (Boynton 1984) for both the rapakivi-type quartz monzonite and the dark-grey granodiorite, as well as a field with value ranges for MC granitoids, are shown in Fig. 7A. The REE patterns for the rapakivi-type quartz monzonite are similar, showing a uniform REE distribution, except for sample P-1303a, which has a significantly higher REE content (1839 ppm) than other samples (∑REE = 686-1015 ppm). The majority of samples exhibit steep patterns for light rare earth elements (LREE) and moderately steep to almost flat for heavy rare earth elements (HREE), showing well-defined fractionation trends for LREE with (La/Sm) N = 2.4-5.9, and moderately trends for HREE with (Eu/Yb) N = 1.9-2.8 ((La/Yb) N = 12.2-36.0). All samples show negative Eu/Eu* anomalies (0.58-0.67). Sample P-1303a exhibits a different fractionation trend with (La/Yb) N = 126.7 and (La/Sm) N = 16.2, and simultaneously, a flat HREE pattern. In general, REE patterns for the Pietkowo IG1 rapakivi-type quartz monzonite are comparable to the MC granitoid patterns.
The trace element patterns of both rock types are presented on the primitive mantle-normalized (Sun and McDonough 1989) multi-element diagram (Fig. 7B). Trace element signatures confirm the homogenous nature for both rock types (except the P-1303a sample). All samples are enriched, to varying degrees, in large-ion lithophile elements (LILE) and in HFSE compared to the primitive mantle. They display patterns with pronounced negative anomalies for Nb, Sr, P and weaker negative anomalies for Ti and Zr in the case of the dark-grey granodiorite. These negative anomalies reflect the fractionation of plagioclase, apatite, and Fe-Ti oxides during earlier stages of magma evolution.

General remarks
Zircons were selected from the rapakivi-type quartz monzonite samples from depths of 1041 ( Fig. 3A; P-1041 sample), 1138 (Fig. 3B, F; P-1138 sample) and 1257 ( Fig. 3F; P-1257 sample) m. The set of grains consists of large euhedral grains with concentric zonation, where cores and rims are distinguished based on distinct brightness in the CL imaging ( Fig. S3A-F). Inherited cores or metamorphic overgrowths are absent. Most likely, this type of zonation documents prolonged and, in places, disturbed magmatic crystallization of a granitic rock.

Pietkowo IG1; 1257 m
Zircon grains from sample P-1257, chosen for the ion microprobe age determination, in places show microcracks previously not observed in the CL imaging. Grains are prismatic with a typical magmatic zonation and some structural perturbations within the central part of grains (Fig. S3E, F). U and Th concentrations range between 39-247 ppm and 28-280 ppm, respectively, giving the Th/U ratio of 0.47-1.46 (Fig. 9A, B). Thirty-six measurements on 33 zircon grains within cores and outer parts were performed. Twelve analyses, with discordance > 5%, were excluded from the dataset, giving twenty-four analyses for further interpretation (Table S6). The single spot 207 Pb/ 206 Pb ages of that group reflect a wide range between 1542.5 ± 18 Ma (+ 2% disc.) and 1437 ± 24 (+ 3% disc). The most consistent group, representing the outer fragments of grains (n = 11), yielded a concordia age of 1491 ± 5 Ma with MSWD = 0.64 (Fig. 8C). This is interpreted as close to the emplacement age of the quartz monzonite. The limited number of results from the cores of larger grains provided a concordia age at 1513 ± 7 Ma (MSWD = 0.74; Fig. 8D).

Pietkowo IG1; 1317 m
The set of zircon grains from the dark-grey granodiorite, depth 1317 m, are euhedral prisms with length ca. 180-250 μm. The sample consists of simple melt-precipitated grains. The absence of inherited cores or metamorphic overgrowths was confirmed by the SEM-CL imaging (Fig. S3G, H). The zircon grains from this sample were analyzed in 2005 and described by Krzemińska et al. (2007). The analytical data have been recalculated. U contents range from 166 to 701 ppm and Th from 107 to 397 ppm. The Th/U ratio is in the range of 0.43-1.05 (Fig. 9A, B) and is typical of magmatic zircons. Single spot 207 Pb/ 206 Pb ages (n = 8) ranged from 1827 ± 16 Ma to 1732 ± 30 Ma. The inset shows two results differing slightly from the main group, suggesting a younger population (Fig. 8E), although other parameters such as Th/U ratio and contents of Th, U, Pb do not distinguish these zircons. Five from eight analyses define the concordia age of 1813 ± 11 Ma (MSWD = 0.34; Fig. 8F), which reflects the time of zircon magmatic protolith crystallization. This age is consistent with a previously published result of 1818 ± 15 Ma. The omitted younger zircons do not form a significant group; however the age of these grains corresponds to the activity (at 1758 ± 15 Ma), which has been much better documented in the Mid-Lithuanian Domain (MLD; Fig. 1A

Sm-Nd isotopes
Samples of the Mesoproterozoic rapakivi-type quartz monzonite and the Late Paleoproterozoic dark-grey granodiorite were analyzed for the Sm and Nd isotope composition (Table 3). These two groups have distinct Nd and Sm concentrations. The rapakivi-type quartz monzonite has higher amounts of Nd, ranging from 118.15 ppm to 266.68 ppm and Sm, from 22.01 ppm to 37.77 ppm, resulting in 147 Sm/ 144 Nd ratios between 0.0856 and 0.1126. Present-day ε Nd values range between -19.35 and -24.15. The initial ε Nd values show a narrow range between -2.95 and -3.31 (Fig. 10). Corresponding T DM ages, following the model of DePaolo (1981), fall between 2.07 and 2.25 Ga and calculated chondritic uniform reservoir model ages (T CHUR ) fall between 1.70 and 1.80 Ga (Table 3). In the case of the dark-grey granodiorite the measured Nd and Sm concentrations and isotope values are much more uniform. Nd and Sm contents are 80.1-83.1 ppm and 13.2-14.5 ppm, respectively, resulting in 147 Sm/ 144 Nd ratios of 0.0997 and 0.1052. Present-day ε Nd Fig. 6 Selected variation diagrams of trace element compositions against silica for whole-rock samples of the rapakivi-type quartz monzonite and the dark-grey granodiorite. Data for MC granitoids after Duchesne et al. (2010), for the Salmi massif after Sharkov (2010) and for the Ahvenisto massif after Heinonen et al. (2010b). Same symbols as in Fig. 4 have values of -21.42 and -22.26. The initial ε Nd show nearchondritic values of -0.99 and 1.14 ( Fig. 10). Corresponding T DM model ages, following the model of DePaolo (1981), were calculated as 2.14 and 2.31 Ga and T CHUR model ages gave values of 1.72 and 1.90 Ga. The isotope characteristics do not show any obvious correlation between Nd isotope values and SiO 2 content (Fig. 6C), but the higher Sm-Nd isotope composition of the Mesoproterozoic rapakivi-type quartz monzonite samples points to their high values of La and in consequence strong enrichment in LREE and the sum of REE (Table 2).

Classification
Although Mesoproterozoic granitoids of the MC, known from deep boreholes in the north easternmost basement of Poland, do not show all features of the classical rapakivi texture, they were, however, placed on the 'Global map and list of rapakivi granite-gabbro-anorthosite complexes known by 1993' published by Mineralogy and Petrology (Rämö and Haapala Fig. 7 A C1 chondritenormalized (Boynton 1984) rare-earth element patterns and; B primitive mantle-normalized (Sun and McDonough 1989) trace element patterns for the rapakivi-type quartz monzonite and the dark-grey granodiorite Fig. 8 Wetherill plots for selected analyses with defined concordia ages for zircon grains separated from Pietkowo IG1 rapakivitype quartz monzonite; A zircon grains from P-1041 sample, depth 1041 m; B zircon grains from P-1138 sample, depth 1138 m; C zircon grains from P-1257 sample, depth 1257 m; D older zircon grains from P-1257 sample, depth 1257 m. Plots for analyses of zircon grains separated from Pietkowo IG1 dark-grey granodiorite; E 207 Pb/ 206 Pb age projection for all collected analyses of zircon grains from P-1317 sample, depth 1317 m; F concordia age (recalculated) for selected analyses of zircon grains from P-1317 sample, depth 1317 m 1 3 1995). Most of presented therein Fennoscandian cases (11/13) were related to easily accessible areas of the Baltic Shield. Over the past three decades the list has undoubtedly been expanded (cf. Salminen et al. 2021), but does not yet include the Pietkowo IG1 quartz monzonite from the hidden part of Fennoscandia, which is characterized by the presence of texture resembling this of rapakivi-type granites (Fig. 3E, F). To determine potential analogues, the whole-rock compositional data of the Pietkowo IG1 rapakivi-type quartz monzonite were compared to granitoids from the MC (i.e. Bartoszyce, Gołdap, Filipów, Klewno and Kętrzyn boreholes; Fig. 1B; Duchesne et al. 2010) and two classical rapakivi A-type granite batholiths i.e., the Salmi in Russian Karelia and the Ahvenisto (satellite of the Wiborg massif) in S Finland (Fig. 1A).
The Mesoproterozoic Pietkowo IG1 quartz monzonite displays unequivocal features of A-type granites (cf. Collins et al. 1982;Whalen et al. 1987;Eby 1992;King et al. 1997;Frost et al. 2001). It has high contents of incompatible elements of the HFSE group, e.g., Nb, Zr, Y, Th (Table 2; Fig. 6A, D, E), plotting within the range of A-type granites in the FeO t + MgO versus Zr + Nb + Ce + Y and Zr versus 10000 × Ga/Al of Whalen et al. (1987) diagrams (Fig. 11A, B), together with granitoids of the Salmi and Ahvenisto (Heinonen et al. 2010b;Sharkov 2010) used as the most representative data for A-type rapakivi batholiths. On the Nb-Y-Ce diagram (Eby 1992) the Pietkowo rapakivi-type quartz monzonite, together with Salmi and Ahvenisto granitoids, plots in the A 2 field (Fig. 11C). The Pietkowo IG1 samples are classified as metaluminous but close to the peraluminous border, with an alkali-calcic nature, which corresponds to the main trend of the compositions known from the Salmi, Ahvenisto, and MC granitoids (Fig. 4A, C). Only the Fe and Mg contents show some differences. Instead of the unequivocally ferroan characteristics of the Salmi and Ahvenisto, the Pietkowo IG1 quartz monzonite displays a transitional nature, plotting on the border between ferroan and magnesian type, which coincides with a part of the MC data (Fig. 4B).
In terms of tectonic setting the high Nb and Y concentrations of the Pietkowo IG1 quartz monzonite indicate a typical within-plate granite (WPG) geochemical signature (Pearce et al. 1984), where they overlap with available data from the intraplate MC, Salmi and Ahvenisto batholiths, and fall into the overall 'post-collisional' field (Fig. 11D).
The A-type granites of the Laurentia-Baltica cratons have been commonly subdivided into three groups: ilmenite, magnetite and two-mica (peraluminous) granites (cf. Ishihara 1977;Anderson and Morrison 2005;Dall'Agnol and de Oliveira 2007). The Pietkowo IG1 quartz monzonite belongs to the typical magnetite-series, i.e., the Fe/(Fe + Mg) ratios in the biotite are low, ranging from 0.44 to 0.47 (Table S3) and the whole-rock ratio of FeO t /(FeO t + MgO) is between 0.76 and 0.84 (Table 2; Fig. 11E; cf. Dall'Agnol and de Oliveira 2007). The observed slight negative Eu anomaly suggests oxidizing Fig. 9 The age and Th-U composition of individual zircons from Pietkowo rocks: A Pb-Pb age versus Th/U diagram; B Th versus U diagram for all zircons, showing a predominance of zircons with magmatic origin; C Th versus Pb diagram defining zircon from A-, Sand I-type granites after Wang et al. (2012). Note that Pietkowo IG1 and MC granitoid zircons are shifted toward values of S-type granites, which may be caused by the accuracy of the Pb determinations depending on the method -secondary ion mass spectrometry (SIMS) for Pietkowo IG1 and MC zircons and laser ablation-inductively coupled plasma-mass spectrometry (LA-ICP-MS) for zircons from Wang et al. (2012) conditions of crystallization (Dall'Agnol et al. 2005) rather than the lack of earlier feldspar fractionation. Noteworthy, the ubiquitous occurrence of magnetite and titanite indicates that the Pietkowo IG1 quartz monzonite has an oxidized character as do other magnetite-series granites (Wones 1989;Rajesh 2000;Rämö et al. 2002;Dall'Agnol and de Oliveira 2007), as increases in fO 2 favor titanite stability (Price et al. 1999). Thus, the rapakivi-type quartz monzonite, most likely, crystallized near or slightly above the Ni-NiO (NNO) buffer (Rajesh 2000). The oxidized nature is also shown on the diagram of Dall'Agnol and de Oliveira (2007), where the Pietkowo IG1 quartz monzonite contrasts with reduced A-type granites of the Salmi and Ahvenisto batholiths. The same oxidized character was previously reported for MC granitoids (Duchesne et al. 2010). However, in the case of the MC it was concluded that two different sources, with different H 2 O content, provided parental magmas.
In order to characterize zircons from the Pietkowo IG1 Mesoproterozoic quartz monzonite the new data have been compiled with trace elements data reported by previous workers (Dörr et al. 2002;Wiszniewska and Krzemińska 2021). The analyzed zircons from Pietkowo IG1 quartz monzonite samples exhibit Th/U ratios similar to those from MC granitoids (Fig. 9A, B). In contrast, total U and Th trace element contents tend to be higher in zircons from the Late Paleoproterozoic dark-grey granodiorite sample (Fig. 9B). The relations between Pb against Th concentrations in zircons remain similar (Fig. 9C), giving a consistent group of plots. Systematically, the data from the Pietkowo IG1 quartz monzonite and MC granitoids differ from the range of the A-type classification field, defined by Wang et al. (2012). This case however, points more likely to the crustal signature of the melt but not the S-type character of the granite host rock (Fig. 9C).

Petrogenesis
Origins proposed for A-type granites (both oxidized and reduced) essentially are associated with crustal anatexis promoted by magmatic underplating Dall'Agnol et al. 1999a, 2005. Preferred sources vary from melt-depleted granulite (Collins et al. 1982;Clemens et al. 1986;Whalen et al. 1987), granodiorite-tonalite-quartz diorite (Creaser et al. 1991;Emslie 1991;King et al. 1997;Patiño Douce 1997;Dall'Agnol et al. 1999a) to underplated tholeiitic basalts and their differentiates (Frost and Frost 1997;Frost et al. 1999). Nevertheless, fractional crystallization from alkaline basalts (Eby 1992) or other mantlederived magmas (Bonin 2007) has also been proposed for the origin of A-type granites. Thus, it is obvious that the A-type granitoid group may contain felsic rocks of a variety of compositions, which depend on several factors, including the source nature, the pressure of melting, fO 2 conditions, and water content related to the composition of the magma source or sources depending also on changes in conditions (Dall'Agnol and de Oliveira 2007; Duchesne et al. 2010).
Nevertheless, the oxidized nature of the Pietkowo IG1 quartz monzonite argue against a tholeiitic source since partial melting of basalts and their differentiates would produce rather reduced magmas (Frost and Frost 1997). A La/Y versus La diagram (not shown) suggests an overall partial melting as the main mechanism of A-type magma formation. Therefore, the partial melting of crustal rocks is the preferred genetic model for the A-type Pietkowo IG1 quartz monzonite.
Most authors point towards a lower crustal source for oxidized A-type granites (Clemens et al. 1986;Creaser et al. 1991;Landenberger and Collins 1996;Anderson and Morrison 2005;Dall'Agnol and de Oliveira 2007). However, the generation  11F). Similar melting conditions were proposed by Creaser et al. (1991), who modelled the melt formation at 600-800 MPa -characteristic of middle to lower crust. This is consistent with experimental studies conducted by Patiño Douce and Beard (1995), who concluded that, in oxidizing conditions, melts generated by dehydration melting at lower pressures (≤ 4 kbar) should be enriched in Al2O3 compared to those melts formed at more elevated pressures. This is in contrast to alumina behavior in reduced A-type granite (Patiño Douce 1997). The Pietkowo IG1 quartz monzonite contains 13.8-15.9 wt.% Al2O3, while in most A-type granites alumina contents range from 11 to 14 wt.% Al2O3 (cf. Eby 1990;King et al. 1997;Dall'Agnol and de Oliveira 2007). Note that MC granitoids exhibit Al2O3 concentrations of 13.9-17.7 wt.% (Duchesne et al. 2010). Oxidized A-type granites are considered to crystallize from magmas with appreciable water contents. Dall'Agnol and de Oliveira (2007) inferred H 2 O content on ≥ 4 wt%, whereas the experimental studies of Clemens et al. (1986) and Dall'Agnol et al. (1999b) gave 2.4-4.3 and 4.5-6.5 wt% H 2 O in the melt, respectively.
Moreover, A-type granitic magmas are usually regarded as evolving at elevated temperatures (e.g. Collins et al. 1982;Clemens et al. 1986;Creaser et al. 1991;King et al. 1997;Dall'Agnol et al. 1999b). The zircon saturation temperature > 840 °C calculated from the whole-rock composition of the Pietkowo IG1 rapakivi-type quartz monzonite may support this tendency (Table 2), however this temperature rather indicates a potential condition for initiation of crystallization.
This study deals with rapakivi texture rocks, which are a special subgroup of A-type granites (Haapala and Rämö 1992). The common alkali feldspar megacrysts, which occur in Pietkowo IG1 quartz monzonite, are difficult to interpret unambiguously. In very general terms, the rapakivi texture was referred to in connection with magma mixing (Słaby et al. 2002;Heinonen et al. 2017) or as an effect of decompression and undercooling during magma ascent and two stage crystallization (Heinonen et al. 2017). In most cases, formation of the rapakivi texture was dominated by changes in the intensive parameters (P-T) of the magmatic system during ascent of crystal saturated magma from mid crustal levels to superficial chambers (Eklund and Shebanov 1999;Heinonen et al. 2017).
One of the features of rapakivi texture formed during decompression should be a small compositional change between the first and second generations of feldspars (Bladh 1980), and zircon and mafic silicates in different textural positions (Eklund and Shebanov 1999). The zircon data from the Pietkowo IG1 rapakivi may suggest complex crystallization representing an early stage of slow crystallization in deep magma chambers (antecrysts with a concordant age of 1513 ± 7 Ma) and, second, with much smaller, anhedral Fig. 10 ε Nd evolution diagrams for the rapakivi-type quartz monzonite and the dark-grey granodiorite. The dark-grey granodiorite in relation to evolution trends for OJB (Oskarshamn-Jönköping Belt) and TIB-1 (Transscandinavian Igneous Belt). The Mesoproterozoic rapakivi-type quartz monzonite in comparison to Kościerzyna, Malbork and MC granitoids. Sources of data: OJB and TIB-1 rocks fields after Appelquist et al. (2011), MC granitoids after Duchesne et al. (2010); Kościerzyna and Malbork granitoids after Krzemińska et al. (2017). Depleted mantle curve from DePaolo (1981) crystals or rims that crystallized at the final intrusion level at 1495-1491 Ma. A two-stage magmatic evolution was recently documented by a zircon study from the Wiborg rapakivi batholith (Heinonen et al. 2017), and by zircons from the MC AMCG suite .
In most cases, the isotopic composition of rapakivi granites is compatible with a lower crustal, early Proterozoic (and/or Archean) protolith (Rämö and Happala 1995). In terms of Nd isotopes, the Pietkowo IG1 quartz monzonite T DM ages of 2.07-2.25 Ga (Table 3) are, in general, similar to those of the Late Paleoproterozoic dark-grey granodiorite (T DM = 2.14-2.31 Ga). Moreover, the quartz monzonite falls within the upper (more radiogenic) part of the evolution field of the dark-grey granodiorite, which indicates that the A-type quartz monzonite has been generated through melting of the dark-grey granodiorite with a little or no input of mantle-derived magmas.
Melting of the dark-grey granodiorite is also suggested by the Y/Nb ratio, which, due to melting, undergoes little change from the calc-alkaline source rock (Y/Nb ratio Fig. 11 Geochemical classification of the dark-grey granodiorite and the rapakivi-type quartz monzonite together with a comparison with MC granitoids (Duchesne et al. 2010), Salmi granitoids (Sharkov 2010) and Ahvenisto granitoids (Heinonen et al. 2010b): A, B FeO t /MgO versus Zr + Nb + Ce + Y and Zr versus 10000 × Ga/Al diagrams defining I, M, S and A-type granitoids, from Whalen et al. (1987); C diagram defining the A 1 and A 2 subtypes of the A-type granites using Nb-Y-Ce after Eby (1992); D tectonic discrimination diagram using Nb versus Y after Pearce et al. (1984): WPG -within-plate granites, VAG -volcanic arc granites, syn-COLG -syncollisional granites, ORGoceanic ridge granites, post-COLG -post-collisional granites; E diagram defining calc-alkaline and A-type granites with reduced and oxidized subtypes fields, from Dall'Agnol and de Oliveira (2007); F Al 2 O 3 / (FeO t + MgO + TiO 2 ) versus Al 2 O 3 + FeO t + MgO + TiO 2 diagram defining the fields of the low pressure (P ≤ 500 MPa) and high pressure (P = 1.2-1.5 GPa) of the melt generation, from Patiño Douce (1999) of 1.5 for the Paleoproterozoic dark-grey granodiorite) to derived melt (Y/Nb = 1.6-1.8 for the Mesoproterozoic rapakivi-type quartz monzonite) fingerprinting the source (Table 2; Eby 1990). The rapakivi-type quartz monzonite Y/Nb ratios of 1.6-1.8 and Yb/Ta ratios of 2.2-3.1 are characteristic of crustal values (Eby 1990). Also, the lack of an obvious correlation between Nd isotopic values and SiO 2 content suggests a limited role for assimilation/contamination, while the oxidized affinity of the rapakivi-type quartz monzonite is difficult to reconcile with the contribution of metasedimentary wall rocks (Dall'Agnol et al. 2005;Jiang et al. 2011).
An origin of the Pietkowo rapakivi-type quartz monzonite by melting of the dark-grey granodiorite is also supported by the relatively high content of F (2630-2730 ppm) in the quartz monzonite melt, as during melting of the granodiorite source the breakdown of phlogopite and amphibole would provide F to the melt. Higher F contents of 2570-3650 ppm in granodiorite are most likely caused by F bound in the residual phases i.e., apatite and titanite (Creaser et al. 1991) and abundant phlogopite. Moreover, the presence of titanite, without fluorite in the rapakivi-type quartz monzonite, suggests that A-type melt contained < 1 wt% F (Price et al. 1999). Nevertheless, F concentrations of < 1 wt% are sufficient to promote high HFSE contents, observed in the Pietkowo quartz monzonite, through complexing effects (Creaser et al. 1991). The presence of volatiles, such as F, results in lowering magma viscosity and could be responsible for the ascent of the granite magma through the crust (Clemens et al. 1986;Creaser et al. 1991), and ongoing formation of minerals, both in the deep-seated magma chamber and at the final level of emplacement.
Therefore, we suggest that the rapakivi-type quartz monzonite was probably formed by crustal partial melting of the Late Paleoproterozoic dark-grey calc-alkalic granodiorite, giving A 2 -type granite magma, which subsequently crystallized during a two-step crystallization process. This accords with Anderson (1983), who proposed that crustal sources for this kind of A-type rock can vary from quartz diorite to granodiorite.

Regional context
The Proterozoic part of Fennoscandia was formed during the Svecofennian orogenic and post Svecofennian phases (Krzemińska et al. 2017;Skridlaite et al. 2021), ca. 300 Ma before the emplacement of A-type granitoid bodies; hence the term anorogenic (Condie 1991;Bonin 2007) can refer also to the Pietkowo IG1 quartz monzonite intrusion emplaced at 1495-1491 Ma.
Considering the time of emplacement (Fig. 12), the Pietkowo IG1 quartz monzonite (1495-1491 Ma) is coeval with a few A-type granitoid bodies (i.e. Malbork IG1 (1499 Ma) and Kościerzyna IG1 (1499-1502 Ma)) in the vicinity of the Baltic Sea ( Fig. 1B; Krzemińska et al. 2017 and slightly younger than 1525-1499 Ma A-type rocks of the MC (Dörr et al. 2002;Wiszniewska and Krzemińska 2021), as well as the prominent (1585 Ma) Riga batholith (Rämö et al. 1996) with its part in Gotland (Sundblad et al. 2021). Numerous small intrusive bodies and large batholiths of A-type granite composition are   (Fig. 12), exhibits generally negative initial ε Nd values, suggesting crustal contributions in the sources, whereas the large variation in their initial ε Nd values (Fig. 12) implies some differences in the initial Sm/Nd ratio and Nd isotope composition, reflecting features of their local crustal sources, regardless of the time of the intrusion emplacement. The relatively young complex is the easternmost Salmi massif in Russian Karelia (ca. 1530-1540 Ma; Table 4; Amelin et al. 1997) which has initial ε Nd values from -7.0 to -8.3 ( Fig. 12; Neymark et al. 1994), whereas the older Riga rapakivi pluton (ca. 1585 Ma; Table 4; Rämö et al. 1996) has initial εNd values from + 0.3 to -4.8 ( Fig. 12; Rämö et al. 1996). The same situations are observed in Sweden (e.g. the Rödön and Nordingrå massifs). The reason for this age distribution is unclear, but the belt-like geometry argues for a relationship to large-scale tectonic processes.
Most of AMCG suites are connected with previous deepseated fault zones for their emplacement. Duchesne et al. (1999) argued that several anorthosite complexes, and the associated A-type granitoids, are commonly tied to former lithospheric-scale weakness zones, which may have favored their emplacement at higher crustal levels (cf. Dörr et al. 2002;Skridlaite et al. 2007). In the area of the southwestern EEC, the terrane boundaries, formed due to the Paleoproterozoic accretion of Fennoscandia, are suspected of being responsible for the magma uprising in the Mesoproterozoic.
A re-activation of transcurrent shear zones within uplifts and swells in a cratonic continental setting (Bonin 2007) remains one of typical tectonic context of A-type granite occurrences.
The major A-type rapakivi granitoids of the Finnish province, including the Salmi rapakivi intrusion in Russian Karelia, are associated with massif-type anorthosite. The MC (NE Poland) is also linked with at least three anorthosite massifs, forming a range of AMCG components (Dörr et al. 2002). The Paleoproterozoic collisionsubduction episodes of the Svecofennian orogeny resulted in underthrusting of the lower crust to depths of ca. 40 km (Grad et al. 2009). Later upwelling of the asthenosphere could have caused the melting of the lower crust and mafic magmatism, represented by anorthosites of adjacent intrusion, which in turn could provide heat for generating the more felsic magma in the shallower crust. Thus, we suggest that the most plausible route for the Pietkowo IG1 rapakivi-type quartz monzonite ascent was the boundary between two crustal domains -the Mazowsze Domain and Belarus-Podlasie Granulite Belt pointed by the Białystok fault ( Fig. 1B; cf. Krzemińska et al. 2017). The same fault zone could also have been responsible for the formation of the ~ 1.5 Ga Grodno Massif (Taran 2005), which lies on the NE extension of the Białystok fault, only 120 km to NE from the Pietkowo IG1 borehole. The positive magnetic and gravity anomalies recognized close to the Pietkowo IG1 intrusion may reflect the presence of the mafic component (e.g. anorthosites and gabbros) undrilled SIMS analyses performed on: a SHRIMP IIe/MC at the PGI-NRI (Warsaw, Poland) b Cameca IMS1270/1280 SIMS instrument of the Nordic high-resolution ion-microprobe facility (NORD-SIM) at the Swedish Museum of Natural History (Stockholm, Sweden) so far ( Fig. S1; Krzemińska et al. 2017) confirming the bimodal nature of this magmatism. Hence, the Mesoproterozoic rapakivi-type quartz monzonite of the Pietkowo IG1 borehole can be a component of the AMCG association in southernmost Fennoscandia. Demonstration of another massif from the unexposed area (Pietkowo IG1) supplements our state of knowledge about the specificity of rapakivi magmatism in Fennoscandia.

Conclusions
The study of the Pietkowo IG1 intrusion discovered within the hidden Late Paleoproterozoic part of the EEC documents (i) another occurrence of a Mesoproterozoic A-type granitoid of quartz monzonite composition with specific rapakivitype texture, classified as weakly metaluminous, transient ferroan/magnesian and alkali-calcic magmatism, with elevated content of alkalis (K 2 O > Na 2 O). The high FeO t /MgO ratio and elevated HFSE contents are compatible with other A-type granites, including examples from the Salmi (Russian Karelia) and Ahvenisto (S Finland) rapakivi batholiths. Pietkowo IG1quartz monzonite show features of A 2 -type granite and belong to the magnetite-series. Pietkowo IG1 melt had to be generated under oxidizing conditions, as for the melts of MC granitoids. (ii) The Sm-Nd isotopic composition of the Pietkowo IG1 quartz monzonite is compatible with a lower crustal, early Proterozoic protolith (T DM ages of 2.07-2.25 Ga) as is the case with a number of other rapakivi massifs (cf.  in Fennoscandia. (iii) The concordant age of the Pietkowo IG1 quartz monzonite indicates its emplacement at 1495-1491 Ma, although slightly older zircon cores (antecrysts) of 1513 ± 7 Ma imply a two-stage crystallization for the quartz monzonite. (iv) The Pietkowo IG1 rapakivi-type quartz monzonite is an example of, so far, the southernmost Mesoproterozoic massif of A-type affinity, belonging to the AMCG suites of Fennoscandia. (vi) It was connected with former lithospheric-scale weakness zones, between the east margin of the Mazowsze Domain and Belarus-Podlasie Granulite Belt pointed to by the Białystok fault.