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1. Introduction

Complex REE–Nb–Ta–Ti oxides (aeschynite-, euxenite-, and samarskite-group minerals) are uncommon but locally important accessory phases occurring typically in the NYF (niobium, yttrium, fluorine) family and REL–REE (rare-element and rare earths) class (as per the listed pegmatites of allanite-, euxenite-, and gadolinite-type by Černý and Ercit [1]). Aeschynite- and euxenite-group minerals have a general formula AB2O6 where the eight-fold coordinated A-site, a square antiprism, is occupied by Y, REE, Ca, U, Th, Fe, while the six-fold coordinated B-site has a typical octahedra to form double chains in a zigzag pattern along the b-axis [2] occupied by Ti, Nb, Ta. and W. Aeschynite-group minerals (AGMs) and euxenite-group minerals (EGMs) are orthorhombic, but the BO6 stacking octahedra is different, leading to the Pbnm space group in AGMs and to the Pbcn space group in EGMs. Historically, samarskite-group minerals have the general formula ABO4 and an α-PbO2 primitive structure [3,4]; Nb is dominant at the six-fold coordinated B-site, and the A-site is mostly occupied by REE, Ca, U, Fe2+, and Fe3+, although some studies placed Fe3+ in the B-site and Ti can occupy both sites [5]. The A-site in samarskite is occupied by REE, usually with a dominance of Y, but samarskite-(Yb) has also been reported [6].

Kjelmann [7] proposed a new nomenclature for samarskite-group minerals with a general formula ABC2O8. Recently, a new structural investigation of non-metamict samarskite-(Y) from Laacher See, Eifel volcanic region, Germany, revealed a unique cation-ordered niobate structure related to layered, double tungstenates ABW2O8 by Britvin et al. [8]. These authors refined the crystal structure of samarskite-(Y) as monoclinic P2/c and redefined the ideal formula to YFe3+Nb2O8. The nomenclature was approved by the Commission on New Minerals, Nomenclature and Classification, International Mineralogical Association (IMA-CNMNC) and is leading to the end-member formula of samarskite-(Y), based on an ordered formula, ABX2O8.

Yttrium-rare earths-oxide minerals typically contain elevated concentrations of U4+ and Th4+ and undergo self-radiation-induced structural damage leading to amorphization of formerly crystalline lattice. This crystalline-to-amorphous transition (metamictization) is followed by substantial changes of physical properties [9,10]. Such metamict phases are very prone to hydrothermal alteration, which commonly leads to substantial changes in the chemical composition of affected domains [11,12,13,14,15].

The Arvogno pegmatite dikes (Figure 1) are unique within the tertiary alpine pegmatite field [16,17] showing marked geochemical and mineralogical NYF features. These pegmatites contain aeschynite-(Y), polycrase-(Y), and samarskite-(Y) associated with further typical NYF minerals such as Y-rich fluorite, Y-rich spessartine, allanite-group minerals, gadolinite-(Y), and xenotime-(Y). This mineral assemblage and the chemical composition of minerals suggest that the examined pegmatites are typical examples of the NYF family enriched in Nb, Y, and other REE and F, fitting very well the definition of the NYF family [18,19].

The crystal chemistry of these minerals was examined by means of EPMA analysis in the WDS (wavelength-dispersive spectrometry) mode, SEM (scanning electron microscope) in the EDS (energy-dispersive spectrometry) mode, and SCXRD (single-crystal X-ray diffraction). This study revealed that coexistent Y–Nb–Ti–Ta oxides from the Arvogno pegmatites are characterized by very low radiation damage [20,21,22] disregarding the rather high concentrations of U and Th, and it allowed to obtain the crystallographic determination by SCXRD at room temperature, as well as a Raman spectroscopy study for aeschynite-(Y), polycrase-(Y), and samarskite-(Y).

2. Geological Sketch

The tertiary, oligocenic, Alpine pegmatite field [16,17] is located in the Central Alps, within the SSB (Southern Steep Belt) of the Alpine nappes. It extends for ~100 km in an E–W direction and ~15 km in a N–S direction north of the Periadriatic Fault, from the Bergell massif to the east, and the Ossola valley to the west (Figure 1). The pegmatite field geographically overlaps the highest temperature domain of the Lepontine Barrovian metamorphic dome, and the zone of Alpine migmatization [23,24] indistinctly crosscutting the Alpine metamorphic nappes. The Centovalli line, an Alpine tectonic lineament considered a part of the Periadriatic Fault follows the E-striking depression of the Melezzo river, developed along the Vigezzo valley, from Trontano in the Ossola valley (Italy) to the west, to Intragna, in the Maggia valley (Switzerland), to the east [25]. Along the Melezzo River, Alpine nappes are vertical and locally stretched by a mylonitic deformation. These Pennine units were known as Antigorio, Pioda di Crana, Camughera, Moncucco, Isorno, Orselina, Bosco and Monte Rosa [26,27]. The main schistosity of Vigezzo and Centovalli valleys is characterized by a subhorizontal stretching lineation and dextral shear developed under amphibolite facies conditions. Many brittle structures, partly related to hydrothermal processes, also occur. They belong to mineralized faults, cataclasites, and fault breccias crosscutting the Pennine units of Vigezzo–Centovalli valleys [28] related to late-stage brittle deformation and hydrothermal processes that were active during late Alpine stage under variable P–T conditions.

3. Description of Pegmatite Dikes

Since the 1880s, the Vigezzo valley in the Central Alps, Italy, has been a classic Alpine-type locality for a number of Nb–Ti–Ta oxide minerals found in granitic pegmatites. The first alpine columbite was published by Strüver [29] from the pegmatites at Cravegna, Vigezzo valley. Zambonini [30,31] described in the pegmatites at Piano dei Lavonchi, Vigezzo valley, two new minerals, strüverite, renamed as a variety of Ta-rich rutile, and delorenzite, later redefined by De Pol and Minutti [32] as tanteuxenite-(Y). Roggiani [33] identified tapiolite at Piano dei Lavonchi and Albertini and Andersen [34] studied several Y–Nb–Ta–Ti oxides occurring at the “Bosco” pegmatite and described aeschynite-(Y), polycrase-(Y), and euxenite-(Y) in assemblage with gadolinite-(Y), monazite-(Ce), and xenotime-(Y).

The “Bosco” and “Fiume” dikes are located near the village of Arvogno, Vigezzo valley, were discovered and mined in the 1980s by local mineral collectors for rare REE–Nb–Ti–Ta oxides, phosphates, and silicate minerals [35]. The studied NYF pegmatites crosscut medium-grained two-mica orthogneiss, which belongs to the Pioda di Crana Lepontine nappe [36].

The “Fiume” pegmatite dike outcrops in the Melezzo River for ~20 meters in length, up to 1 meter in width and shows straight contacts with the orthogneiss. It is pervaded by a set of late-stage brittle fractures respect to the orthogneiss foliation, and developed from the hosting rock throughout the pegmatite. The internal structure of the pegmatite consists of a fine-grained border-wall unit composed of K-feldspar, plagioclase, and quartz, a medium-grained intermediate unit composed of perthite K-feldspar, flakes of silvery-green muscovite, dark-brown platy crystals of siderophyllite-annite, albite, and quartz. Black nodules or crystals of AGMs and EGMs, up to two centimeters in diameter, exhibit conchoidal fractures. Black magnetite grains occasionally occur within this portion of the dike and within the host orthogneiss. The coarse-grained core zone is composed of white perthite K-feldspar, smoky quartz, and lamellar albite, cleavelandite variety [16]. This unit contains several accessory minerals such as centimetric masses of orange yttrian–spessartine, massive pale-green and violet yttrian–fluorite. The core of the pegmatite hosts AGMs and EGMs, allanite-(Y), bismuthinite, monazite-(Ce), pyrophanite, titanite, uraninite, xenotime-(Y), and zircon as well. Secondary cavities in the core zone, formed after fluorite dissolution, are lined with albite, allanite-(Ce), microlite, pyrochlore, and rarely gadolinite-(Y), and late-stage minerals such as bavenite and milarite. The pegmatite also contains rare galena nodules associated with platy wulfenite crystals.

The “Bosco” pegmatite outcrops for 4–5 m and has 3–4 m in thickness. The dike has a decimetric coarse-grained border-wall zone composed of white K-feldspar, albite, brown quartz with rare accessory minerals including allanite-(Y), bismuthinite, magnetite, yttrian–spessartine, and thorian–monazite-(Ce). The hanging wall of the pegmatite in contact with the orthogneiss shows a lobate structure. The border zone, in the upper portion (upper end) of the dike, hosts albite, aeschynite-(Y), polycrase-(Y), xenotime-(Y) allanite-(Ce), yttrian–fluorapatite, zircon, and secondary cavities formed by the dissolution of yttrian–fluorite lined with gadolinite-(Y) and titanite [17]. The coarse-grained core zone is composed of euhedral pinkish to whitish perthite K-feldspar, brownish to colorless large masses of quartz and dark brown-black platy crystals of siderophyllite–annite, which host centimetric black granular masses of samarskite-(Y).

4. Analytical Methods and Terminology of REE 4.1. Wavelength-Dispersive Spectroscopy (WDS)

Chemical compositions of complex REE–Nb–Ta–Ti oxides were obtained from carbon-coated polished sections by means of an electron probe microanalyzer (EPMA) Cameca SX 100 (CAMECA, Gennevilliers Cedex, France) using the wavelength-dispersion mode (WDS). The following analytical conditions were applied: accelerating voltage 15 kV, beam diameter 5 μm, beam current 40 nA, and counting times 20 s for Nb, Ta, Ti, Ca, Y and 30–60 s for the other elements. The following standards and lines were used: Ti (Kα)—anatase (Hardargervida); Nb (Lα), Fe (Kα)—columbite-(Fe) (Ivigtut); Ta (Mα)—CrTa2O6; Mn (Kα)—Mn2SiO4; Ca (Kα)—wollastonite, W (Mβ)—CaWO4; Na (Kα)—albite (Amelia mine); P (Kα)—Ca5(PO4)3F; K, Al, Si (Kα)—sanidine (Eifel); Mg (Kα)—Mg2SiO4; As (Lα)—lammerite (Guanaco), Y (Lα)—YAG; Sn (Lα)—SnO2; U (Mβ)—U; Th (Mα)—CaTh(PO4)2; Sc (Kα)—ScVO4; Pb (Mα)—vanadinite (Mibladen); Zr (Lα)—ZrSiO4; La, Ce, Er, Yb (Lα); Pr, Nd, Sm, Gd, Dy, (Lβ)—La–Lu orthophosphates. Data were reduced using Correction for Quantitative Electron Probe Microanalysis [37]. Based on the counting statistics, the measurement error expressed as 2σ was approximately <1 rel. % for concentrations around 20 wt.% and ~8 rel. % for concentrations around 1 wt.%. An empirically determined correction factor was applied to the coincidence of Ce Mβ 2nd-order of Dy Mβ and 3rd-order Y Lβ with the F Kα line, CeLγ with the GdLα line, TbLβ with the ErLα line, SmLγ with the TmLα, and TbLβ2 with the YbLα line. In addition MgO, Al2O3, P2O5, K2O, PbO2, La2O3, and Pr2O3 resulted in below detection limits of EPMA (~0.05 wt.% ).

Empirical formulae of aeschynite-(Y) and polycrase-(Y) were calculated assuming the sum of all cations = 3 (Table 1). The empirical formula of samarskite-(Y) was calculated on the basis of a six-fold coordinated X-site = 2 (Table 2). Based on the charge balance and the structural investigation by Britvin et al. [8], Fe is considered as trivalent and Mn as divalent.

4.2. Single Crystal X-Ray Spectroscopy (SCXRD)

Unit-cell data (Table 3) were obtained using a single-crystal diffractomer Rigaku-Oxford Diffraction Supernova (Rigaku Europe SE, Ettlingen, Germany) with an X-ray microsource (spot = 120 μm, λ = Mo Kα, working conditions 50 kV and 0.8 mA) and equipped with a 200K Pilatus Dectris detector (DECTRIS Ltd, Baden-Daettwil, Switzerland). The measurements were performed using a 0–360° ϕ scan. The detector-to-sample distance was 68 mm. The unit-cell refinements were performed using CrysalisPro software (Version Crysalis_40_64.19a, Agilent Technologies Ltd., Santa Clara, CA, USA).

4.3. Raman Spectroscopy

The Raman spectra of complex REE–Nb–Ta–Ti oxides (Figure 2f) were obtained from a polished section by means of a Horiba Labram HR Evolution spectrometer. This dispersive, edge filter-based system was equipped with an Olympus BX 41 optical microscope, a diffraction grating with 600 grooves per millimeter, and a Peltier-cooled, Si-based charge-coupled device (CCD) detector. After careful tests with different lasers (473, 532, and 633 nm), the 633 nm He–Ne laser with a beam power of 10 mW at the sample surface was selected for spectra acquisition to minimize analytical artefacts. Raman signal was collected in the range of 100–4000 cm−1 with a 100× objective and the system being operated in the confocal mode, beam diameter was ~1 µm and the lateral resolution ~2 µm, but due to the strong luminescence, in the region above 2000 cm−1 only the region 100–1200 cm−1 was processed. No visual damage of the analyzed surface was observed at these conditions after the excitation. Wavenumber calibration was done using the Rayleigh line and low-pressure Ne-discharge lamp emissions. The wavenumber accuracy was ~0.5 cm−1, and the spectral resolution was 2 cm−1. Band fitting was done after appropriate background correction, assuming combined Lorentzian–Gaussian band shapes using the Voight function (PeakFit, Version 4.12, Systat Software Inc, San Jose, CA, USA).

4.4. Terminology of REE

According to the IUAPC (International Union for Pure and Applied Chemistry), the term rare-earth elements (REEs) includes lanthanoids (Ln), yttrium (Y), and scandium (Sc). Due to the substantially smaller ionic radius of Sc with respect to the rest of the group, it frequently enters different crystal-structural sites via different substitutions, and therefore, Sc is commonly not included as a REE in geological sciences, and neither in this paper. Due to the lanthanide contraction phenomenon, the REE are further divided into larger LREE (light Ln, La–Gd) and smaller HREE (heavy Ln, Tb–Lu). Actinides, including Th4+ and U4+ show similar behavior, respectively, having a 0.94 Å and 0.89 Å ionic radius.

5. Hand Samples and BSE Description

The samples of Y–Nb–Ti–Ta oxides collected at the “Bosco” dike were, respectively, named Bosco1, Bosco2, Bosco3, and Bosco4 to maintain the original hand specimen description by Albertini and Andersen [34], while that collected at the “Fiume” pegmatite was named Fiume1.

Bosco1 are tabular prismatic crystals and occur in the border-wall areas of the coarse-grained dike associated with white K-feldspar and brown-smoky quartz. Bosco2 forms centimetric black, shiny masses with conchoidal vitreous fractures and occur in the border-wall areas of the coarse-grained dike with white K-feldspar and brown-smoky quartz. Bosco3 forms pluricentimetric black masses with granular fractures and occur at the core-grained dike embedded in brownish, vitreous massive quartz. Bosco4 forms idiomorphic millimetric crystals with prismatic-di-pyramidal habitus and a typical barrel-shape morphology. The crystals are black in color, opaque, show granular fracture, and occur in the border zone of the coarse-grained dike with white K-feldspar, albite, brown-smoky quartz, in association with magnetite and gadolinite-(Y). Fiume1 forms millimetric, black, vitreous masses and have conchoid fractures, rimmed by a reddish halo which extends a few millimeters within the K-feldspar. It was found in the border zone of the pegmatite associated with K-feldspar, black vitreous quartz, and silvery flakes of muscovite.

The individual grains of Y–REE–Nb–Ta–Ti-oxide minerals typically show well-developed zoning in BSE images (Figure 3). The Bosco1 sample—aeschynite-(Y)—had a volumetrically dominant homogeneous core only locally with weak oscillatory zoning inside and regular oscillatory zoning on the rim (Figure 3a) caused by variations in Ti, U, and Ta/Nb. The Bosco2 sample—aeschynite-(Y)—was more heterogeneous with irregular coarse oscillatory zoning rather randomly distributed within the grain (Figure 3b). The Bosco3 sample—samarskite-(Y)—was only slightly zoned; rather, the homogeneous core with slight sectorial zoning evolved to weak oscillatory zoning (Figure 3c) controlled by variations in Ti and U. The Bosco4 sample—polycrase-(Y) + samarskite-(Y)—consisted of rather homogeneous polycrase with euhedral to subhedral elongated grains of samarskite (Figure 3d). In the detailed image (Figure 3e), both minerals have slight oscillatory or irregular zoning. The Fiume1 sample—polycrase-(Y)—exhibited regular parallel oscillatory zoning in the center, and in the outer parts of the grains, irregular fine oscillatory zoning was developed (Figure 3f). The zoning evident from the BSE images was caused by variations in Ti, Nb, Ta, U, Y, and Ln due to its very different Z.

6. Mineral Chemistry of Aeschynite-(Y), Polycrase-(Y), and Samarskite-(Y)

Yttrium–niobium–titanium–tantalum AB2O6 and ABX2O8 oxides from Arvogno pegmatites showed common characteristics: they were free from weathering. No secondary reaction phenomena were observed nor the presence of exsolutions or hydrothermal secondary reactions typical when intergrowth with accessory secondary minerals such as fersmite, pyrochlore, thorite, thorianite or vigezzite, as it elsewhere occurs in the Alpine Tertiary pegmatites [40,41] or in other NYF pegmatite fields [15,38,42,43,44]. The representative chemical compositions of the studied oxides are reported in Table 1 and Table 2. The analysis showed that AB2O6 phases have Y and Ti as dominant A- and B-site cations, respectively, and therefore, corresponded to polycrase-(Y) and/or aeschynite-(Y), which are undistinguishable from each other in chemical composition. The presence of both phases was unequivocally determined and identified under SCXRD. Samarskite group minerals have a general formula ABX2O8; they are represented by samarskite, ishikawaite, and calciosamarskite, respectively, Y, Fe, and Nb dominant A-, B-, and X-site cations [7,8]. At Arvogno, samarskite-(Y) was unequivocally identified under SCXRD; sample Bosco3 was samarskite-(Y), while Bosco4, which was also identified as samarskite-(Y), was intergrown with polycrase-(Y) as well. All samples were very depleted in LREE, particularly La–Nd, and also poor in Ca.

Bosco1 was aeschynite-(Y) and had the A-site mainly occupied by Y as the dominant REE which varied from 0.650 apfu (atoms per formula unit) to 0.710 apfu. Light rare-earths (Ce, Nd, Gd) varied from 0.034 to 0.056 apfu, HREE (Tb, Dy, Ho, Er, Tm, Yb, Lu) varied from 0.15 to 0.16, U/(U + Th) from 0.311 to 0.429 apfu, while Fe2+ from 0.028 to 0.046 apfu. The B-site had Ti dominant, which varied from 1.303 to 1.477 apfu, Nb from 0.322 to 0.375 apfu, Ta from 0.153 to 0.335, and W from 0.036 to 0.057 apfu. Bosco1 showed the highest Ti content among all the Arvogno AB2O6 oxides.

Bosco2 was aeschynite-(Y) in which the A-site had a Y dominant that varied from 0.567 to 0.701 apfu, LREE varied from 0.009 to 0.024, HREE from 0.139 to 0.203 apfu, U/(U + Th) from 0.640 to 0.771 apfu, and Fe2+ from 0.044 to 0.097 apfu. The B-site had Ti which varied from 1.120 to 1.261 apfu, Nb varied from 0.562 to 0.635 apfu, and Ta from 0.151 to 0.188 apfu, whereas W varied from 0.011 to 0.028 apfu.

Bosco3 was samarskite-(Y) where the X-site had Nb dominant which varied from 0.958 to 1.070 apfu, Ti varied from 0.251 to 0.388 apfu, Ta from 0.562 to 0.599 apfu, and W from 0.032 to 0.077 apfu. The A- and B-sites, respectively, had Y dominant that varied from 0.528 to 0.566 apfu, LREE from 0.027 to 0.034 apfu, HREE from 0.192 to 0.209 apfu, U/(U + Th) from 0.529 to 0.645 apfu, and Fe3+ varied from 0.638 to 0.691 apfu.

Bosco4 sample was characterized by the intergrowth of two phases: the dominant was polycrase-(Y), which was quite homogenous in composition; Y at the A-site varied from 0.598 to 0.615 apfu, LREE up to 0.031 apfu, HREE up to 0.175, U/(U + Th) from 0.606 to 0.631 apfu, and Fe2+ from 0.079 to 0.087 apfu. The six-folded octahedra B had Ti from 0.962 to 0.995 apfu, Nb from 0.512 to 0.536 apfu, and Ta up to 0.423 apfu. The subordinate phase was samarskite-(Y), which was quite heterogeneous in composition where the X-site had Nb dominant which varied from 0.895 to 1.128 apfu, Ti from 0.218 to 0.404 apfu, Ta from 0.469 to 0.783 apfu, and W from 0.036 to 0.081 apfu. The A-site had Y dominant that varied from 0.508 to 0.584 apfu, LREE up to 0.039 apfu, HREE varied from 0.179 to 0.195 apfu, U/(U + Th) from 0.498 to 0.673 apfu, and the B-site had Fe3+ that varied from 0.633 to 0.667 apfu.

Fiume1 was polycrase-(Y), and the A-site was mainly occupied by Y and varied from 0.546 to 0.638 apfu. The LREE varied from 0.016 to 0.031 apfu, HREE from 0.201 to 0.209, U/(U + Th) from 0.495 to 0.725 apfu, and Fe2+ from 0.064 to 0.089 apfu. The B-site had Ti which varied from 1.024 to 1.188 apfu, Nb from 0.449 to 0.636 apfu, Ta from 0.274 to 0.332 apfu, and W up to 0.009 apfu.

It is worth mentioning that Bosco3 and Bosco4 samarskite-(Y) was characterized by lower oxide analytical totals in the range of 97 wt.% with Fe3+ and Mn2+ showing significant vacancy at the B-site. When we looked at other samarskites worldwide, they were also partially vacant at this site—some more, some less [3,4,5,6,45]. The Fe and Mn oxidation states were determined in samarkites by bond valence calculation following Britvin et al. [8]. Taking into consideration that AGMs and EGMs have sensible iron contents, future Mossbauer spectra may discriminate and quantify the amounts of Fe3+ and Fe2+.

For comparison, Bonazzi and Menchetti [39] refined the crystal structure of a natural non-metamict aeschynite-(Y) and suggested a new structural formula A1−xB2CxO6 with an additional C-site. These authors assumed that W6+ enters the C-cavity, coupled with a corresponding vacancy in the A-site. The C-site is asymmetrically located within an eight-fold cavity, similar in shape to that occupied by A cations. The sample (VV Vigezzo) described and analyzed by these authors was collected at the “Bosco” dike. The empirical formula calculated with the structural formula obtained by the authors was very close to the Bosco1 analysis: (Y0.65Nd0.01Sm0.02Gd0.04Dy0.04Er0.02Yb0.02Th0.07U0.03Ca0.01Fe0.03)0.94(Ti1.41Nb0.36Ta0.22W0.01)2.00(W0.04)O5.79(OH)0.21

The chemical analysis reported by Bonazzi and Menchetti [39] highlights the deficient analytical total in respect to the data reported for Bosco1. Low total is related to elements not analyzed, such as Si, Tb, Ho, Tm, and Lu, that once added to the analytical total, would result in more than 99 wt.%.

7. Elemental Plots

The statistical approach developed by Ercit [13] allows to discriminate between (REE,U,Th)–(Nb,Ta,Ti) oxide species from REE-enriched granitic pegmatites. The studied samples fit very well the two regions of the Ercit plots. In the first region fall Bosco1, Bosco2, Bosco4, and Fiume1 samples related to the AB2O6 euxenite–aeschynite-group minerals (AGMs), and to the second region of the diagram fall Bosco3 and Bosco4, related to the ABX2O8 samarskite-group minerals (EGMs), as shown in Figure 2d.

The Ercit statistical diagram utilizes equations CV1 and CV2 calculated as follows: CV1 = 0.245Na + 0.106Ca − 0.077Fe* + 0.425Pb + 0.220Y + 0.280LREE + 0.137HREE + 0.100U* + 0.304Ti + 0.097Nb + 0.109Ta* − 12.81 (oxide wt.%); CV2 = 0.102Na − 0.113Ca − 0.371Fe* − 0.167Pb − 0.395Y − 0.280LREE − 0.265HREE − 0.182U* − 0.085Ti − 0.166Nb − 0.146Ta* + 17.29 (oxide wt.% ); where, *Fe = FeO + Fe2O3 + MnO; *U = UO2 + UO3 +U3O8 + ThO2, and Ta* = Ta2O5 + WO3.

The Ta (apfu) versus Nb (apfu) plot (Figure 4a) shows that the Bosco1 and Bosco2 samples have compositional variations in the Ta/Nb ratios and either form partial solid solutions with tantalaeschynite-(Y) [46] and with nioboaeschynite-(Y) [47]. Bosco4 and Fiume1 are polycrase-(Y) and fall within the center of the diagram and they are quite clearly chemically distinguishable each other based on different Ta contents. Bosco3 and Bosco4 (grey) are samarskite-(Y) and fall in the upper-right end of the plot characterized by the highest Nb/Ta enrichment.

The Ti (apfu) versus Ta + Nb (apfu) plot (Figure 4b) identifies two fields represented by AB2O6 (Y, REE, U, Th) and ABX2O8 (Nb, Ta, Ti) oxides all aligned along a sloping line. Bosco3 and Bosco4 samarskites have lower Ti content than Bosco1, Bosco2 aeschynite-(Y), and Bosco4 and Fiume1 polycrase-(Y). The Ta + Nb content results were significantly higher for samarskites than aeschynites.

The Ti (apfu) versus Ca (apfu) plot (Figure 4c) shows Ca content was slightly higher for Bosco4 polycrase-(Y) in respect to Bosco1, Bosco2, and Fiume1. Bosco3 and Bosco4 samarskite-(Y) also showed the lowest Ti content. The Ti (apfu) versus U + Th (apfu) plot (Figure 4d) evidenced the variability of U + Th contents either for AGMs and EGMs from Arvogno.

The behavior of Y + Sc + REE (apfu) versus Ti (apfu) (Figure 4e) showed substantially equivalent contents of Y + Sc + REE for samarskite-(Y), aeschynite-(Y), and polycrase-(Y). Similar behavior was evidenced for U + Th (apfu) versus Y + Sc + REE (apfu) diagram (Figure 4f) as well where Bosco4 and Bosco3 samarskite-(Y) had sensible lower U + Th content than aeschynite-(Y) and polycrase-(Y). The U + Th content for Arvogno only partially agreed with the data reported by Hanson et al. [42], which proposed a higher U + Th content in polycrase-(Y) with respect aeschynite-(Y).

Ta/Ta + Nb (apfu) versus U/U + Th (apfu) (Figure 2c) had Bosco2, Bosco4, and Fiume1 aeschynite-(Y), polycrase-(Y), and samarskite-(Y) with strongly variable Ta/Nb and U/Th contents in respect to Bosco4 polycrase-(Y), which showed substantially equivalent contents.

The Ternary plot (Y + Sc + REE)-Ca-(U + Th) showed Bosco4 polycrase falls with lower uranium and thorium, and slight enrichment in calcium content (Figure 2b,), while the Ti-Nb-Ta plot (Figure 2a) allows to well separate aeschynite-(Y) from samarskite-(Y) and quite well aeschynite-(Y) from polycrase-(Y).

8. REE Pattern and Fractionation Trends

Chondrite versus the normalized REE pattern [48] of AGMs and EGMs showed a strong depletion in the large LREE and enrichment in the medium and small HREE. The samarskite-(Y) pattern was the more enriched in HREE than polycrase-(Y), whereas the aeschynite-(Y) pattern was depleted in the heaviest REE with respect to polycrase-(Y), as shown in Figure 2e. The concentrations of La, Pr, and Eu were below the detection limit of EPMA.

A ratio of Nd/Yb was chosen to numerically characterize the degree of REE fractionation and the slope of the REE pattern. The highest slope (an average) showed samarskite-(Y) from Bosco3 equal to 0.22, Bosco4 to 0.27, then polycrase-(Y) from Fiume1 equal to 0.24, Bosco3 to 0.29, and Bosco4 to 0.35. Aeschynite-(Y) from Bosco1 equaled 0.76, while Bosco2 had a similar pattern for HREE as Bosco1, but in contrast to other samples, it was impoverished in LREE (Figure 2e) and it means that the Nd/Yb ratio was only at 0.18. All analyzed samples showed an M-type tetrad effect strongly evolved on T3 and T4 (Figure 2e). The tetrad effect is usually best developed in the first and third tetrad T1,3 [49], but some HREE-enriched systems can develop evolved tetrad effects on T3 and T4 as described by Škoda et al. [44]. The M-type tetrad effect was reported for evolved Li–F granites, fractionated pegmatites, and their associated minerals [49,50,51,52,53,54,55], as well as minerals crystallized from felsic magma-derived fluids [54,55,56,57] and is attributed to a distribution of REE among magmatic/solid and fluid phases. It is also frequently linked to the F-rich environment, but the sole role of F is questioned by Škoda et al. [44]. The presence of the tetrad effect complicates the interpretation of the REE fractionation as well as the role of crystallographic constrains controlling the entrance of REE into the structure and vice versa. The degree of Ta–Nb fractionation in Bosco1 aeschynite-(Y), expressed as Ta/(Nb + Ta) that decreases with increasing U–Th fractionation, expressed by U/(U + Th), whereas samarskite-(Y) and polycrase-(Y) showed a rather negative trend or no trend, respectively (Figure 2c). This behavior is controlled by crystallographic constrains or by coeval crystallization of U-, Th-, Ta-, and Nb-bearing accessory minerals, rather than by geochemical fractionation of the pegmatite. Similar fractionation behavior was observed in AGMs and EGMs from Třebíč pluton NYF pegmatites [38].

9. SCXRD Data

Although the samples investigated show sensible amounts of U + Th, they were all suitable for X-ray diffraction analysis. The cell data of the crystals studied are reported in Table 3 and include those for Bosco1, Bosco2, Bosco3, Bosco4, and Fiume1 samples. Complete intensity data were collected for all of them, but unfortunately, the crystal quality did not allow to obtain any structural data. The analysis of the systematic absences, given the quality of Bosco1 aeschynite-(Y) and Bosco4 polycrase-(Y) crystals, allowed for both to provide space groups Pbnm and Pcan. Fiume1 and Bosco2 samples did not allow the accurate determination of the space group, but according to the chemical compositions defined by Ti dominant content at the B-site, the cell parameters, respectively, corresponded to polycrase-(Y) and aeschynite-(Y), whereas the Bosco3 crystal provided the monoclinic cell of samarskite-(Y). In order to obtain information about the crystal chemistry of AGMs and EGMs, we compared our cell data of aeschynite-(Y) and polycrase-(Y) with those from Bonazzi and Menchetti [39] and Škoda and Novák [38], whereas the data on samarskite-(Y) were compared with those from Sugitani et al. [3,4], Simmons et al. [6], in addition to the very recent cell data obtained from crystal structures solved by Britvin et al. [8]. These data are reported in Table 3. If we compare the unit-cell volume of Bosco1 and Bosco2 aeschynite-(Y), we can observe that the Bosco1 volume is larger than Bosco2, likely because it had a higher Ti content, whereas, without structural information, it is more difficult to establish why Fiume1 had the higher cell volume of with respect to that of Bosco4, considering that these polycrase-(Y) have very similar chemical compositions.

Bosco3 samarskite-(Y) is the first crystal from pegmatites for which cell data were obtained by SCXRD technique at room temperature following the cell data of samarskite-(Y) occurring in sanidinites from Laacher See published by Britvin et al. [8]. Indeed, all previous crystallographic information reported in the literature provided cell data by powder X-ray diffraction obtained upon heating the crystals from 950 °C to 1110 °C in a reducing atmosphere [3,4,6].

10. Discussion

The compositions (REE,U,Th)–(Nb,Ta,Ti) AB2O6 oxide crystals from Arvogno ranged from aeschynite-(Y) (Bosco1, Bosco2) to polycrase-(Y) (Bosco4, Fiume1). The aeschynite-(Y) form individual crystals or aggregates, but polycrase-(Y) is usually intergrown with samarskite-(Y). In order to discriminate the compositional variations described in the phase diagrams, a number of charge balanced equations are proposed for AGMs and EGMs. They are related to the mutual exchange vectors of elements for eight-folded square antiprism A-site and six-folded octahedra B-site, and they can be summarized as follows:

Fe2+ + 2(Ta5++Nb 5+) ↔ Ca2+ + Ti4+ + W6+

Y3+ + HREE3+ Fe2+ + Nb 5+ ↔ U4+ + Ti4+ + Ta5+

As can be observed, the exchange vectors are strongly variable at A- and B-sites for polycrase-(Y) and aeschynite-(Y) and no general rule can be discerned. The Nb/Ta ratio was strongly variable in polycrase-(Y) and aeschynite-(Y) and the (U + Th) content was sensibly variable and relatively higher in aeschynite-(Y).

As far as Bosco3 and Bosco4 samarskite-(Y) is concerned, the trend was rather homogeneous and the exchange vectors considered can be represented and described by Britvin et al. [8] as follows:

Ca2+ +U4+ ↔ 2(Y, Ln)3+

U4+ + Ti4+ ↔ (Y, Ln)3+ + Nb5+

According to Ewing [58], both primary and secondary alteration could produce a deficiency of the A-type cations, but this is not the case for Arvogno aeschynite-(Y) and polycrase-(Y), which have high analytical totals. In addition, BSE images show no secondary mineral phases such as fersmite, pyrochlores, thorite or thorianite; these minerals are usually present when dissolution metasomatic or hydrothermal replacements occur. Low analytical totals measured for samarskites might reflect the possibility of incomplete occupancy (vacancies) in the B-site charge balanced by OH–, but for all samples, Raman spectroscopy (Figure 2f) showed luminescence on laser at 473 nm, 532 nm, and 633 nm in the “water” region, and therefore, it was not possible to detect the presence of OH– or H2O.

As described by Berman [59], the term “metamict” refers to the “non-crystalline pseudomorphs of material presumed to have been crystalline originally”. Mainly, radiation damage of the structure is the reason for a metamict state [9,58]. Owing to their significant concentrations in U and Th, the (Y–REE–U–Th)–(Nb–Ta–Ti) oxides usually experience strong structural damage resulting from the radioactive decay of actinides [10]. Although aeschynite-(Y), polycrase-(Y), and samarskite-(Y) from Arvogno showed sensible U + Th enrichments, no alpha decay of U and Th, which could cause volume expansion and damage to the crystal lattice of the mineral phases, which in turn may pass from a crystalline to an amorphous state, were observed. No secondary post-metamictization alterations were present as well [60]. If these alterations were present they would show hydration, Ca, and/or high-field strength element (HFSE) addition, in particular Si and Al, K, Ba or Sr, and result in a lowering of the analytical totals, but this is not the case for the Arvogno (Y–REE–U– Th)–(Nb–Ta–Ti) oxides. Behavior of HREE and LREE in AGMs and EGMs is generally distinct. Heavy rare-earths are most often located in EGMs, whereas LREEs are concentrated in AGMs [13]. This relation is likely controlled by crystallographic constraints, because the size of the A-site is larger in AGMs relative to EGMs [13,43]. However, aeschynite-(Y), polycrase-(Y), and samarskite-(Y) from Arvogno pegmatites have very low LREE contents and almost identical HREE patterns or even lowest in samarskite-(Y). These characters are similar in trend for (Y–REE–U–Th)–(Nb–Ta–Ti) oxide of Trout Creek Pass which exhibited very similar REE patterns [42].

Zoned patterns of Y–REE–U–Nb–Ta–Ti-oxide minerals from Arvogno pegmatites were not overprinted by later alteration processes and/or weathering as is typical in almost all pegmatites [38]. Hence, we examined in detail zoned patterns (Figure 3) which were studied in detail in other Nb–Ta–Ti-oxide minerals—mainly in columbite-group minerals [61,62]. Aeschynite-(Y) from Bosco1,2 had a simple zoned pattern with a rather homogeneous core and regular perfectly parallel oscillatory to irregular oscillatory zoning (Figure 3a,b). Polycrase-(Y) associated with samarskite-(Y) (Bosco4) was rather homogeneous as well as intergrowth samarskite-(Y). Oscillatory zoning in polycrase-(Y) from Fiume1 was similar to the aeschynite-(Y) in Bosco2. The zoned patterns of the examined aeschynite-(Y) and polycrase-(Y) were similar to those described in columbite-group minerals [61], although only aeschynite had the same crystal structure. Except for the sample Fiume1 (Figure 3f), they represent typical primary crystallization [61,62]. Irregular oscillatory zoning as overgrowings on polycrase-(Y) (Figure 3f) did not show any corrosive textures, so it was also very likely primary. The observed zoned patterns in both aeschynite- and euxenite-group minerals were very similar to columbite-group minerals and suggest that AB2O6 minerals record crystallization of host pegmatite in a very similar way via compositional zoning; however, due to the metamictization, zoned patterns were overprinted by alterations and metamictization.

The backscattered image of Bosco4 contained bright areas of samarskite-(Y) which developed at the rim and was an elongated and skeletal crystal towards the core of the polycrase-(Y). It is not clear if samarskite-(Y) represents relics replaced by polycrase-(Y) or an exsolution phase which in turn is stable at the temperature of crystallization of the “Bosco” dike. Bosco3 formed homogeneous pluricentimetric black masses with granular fracture at the core zone of the dike embedded in brownish, vitreous massive quartz. Capitani et al. [63] described that the crystal chemistry of samarskite-(Y) fits better the aeschynite structure than the columbite (or ixiolite) structure. Indeed, large ionic radius cations like Y and U can be better accommodated in the larger A-site found in polycrase-(Y)-type structures, which in turn is the polymorph of aeschynite-(Y).

11. Conclusions

Previous crystallographic data from the literature on samarskite from pegmatites [3,4,6] were always obtained by XRPD (X-ray powder diffraction) and this is the first study where cell data on samarskite-(Y) from pegmatites were obtained by SCXRD at room temperature. Low analytical totals measured for Bosco3 and Bosco4 samarskites showed vacancy at the Mn2+ and Fe3+ site and this could be charge balanced by the entrance of OH– in respect to O2−. According to Britvin et al. [8], the sum of Fe and Mn in the M group was less than 1.0 apfu indicating the possibility of incomplete occupancy (vacancies) in the M-site.

Raman spectroscopy was unable to identify water but FTIR (Fourier Transform Infrared Spectroscopy) and TGA (thermal gravimetric analysis) in the future could provide additional information for the presence of hydroxyl or water in samarskites. Taking into consideration that AGMs and EGMs have sensible iron contents, future Mossbauer spectra may discriminate and quantify the amounts of Fe3+ and Fe2+.

Yttrium–niobium–titanium–tantalum oxides from Arvogno have the ionic exchange Fe2+ + (Nb + Ta)5+ U4+ + Ti4+ ↔ (Y, Ln)3+ + Nb5+ (Y3++ REE3+) + Ti4+ which mainly regulates the compositional transition from ABX2O8 samarskite-(Y) to polycrase-(Y) and aeschynite-(Y) with an AB2O6 crystal structure. According to Britvin et al. [8], the thermal behavior of metamict samarskite-group minerals never result in the complete restoration of the original pre-metamict crystalline phase.

Skoda and Novak [38] described the ionic exchange mechanism of AB2O6 with U + Th, and Ca are involved as well and Arvogno samples have almost constant U + Th contents and Ca content is relatively high only in polycrase-(Y). Furthermore, the chemical variations of Bosco4 polycrase-(Y) and Fiume1 polycrase-(Y) are regulated by a further Ti and Y increase and by a Ta decrease at Nb almost constant, while the further transition to aeschynite-(Y) is regulated by an Nb decrease as well. Moreover, Bosco4 polycrase-(Y) differs from Fiume1 polycrase-(Y) because its more relevant Ca content. The Nb/Ta ratio was virtually constant in samarskite-(Y), while it may be variable in polycrase-(Y) and aeschynite-(Y) also at constant Ti contents.

The Raman spectra of polycrase-(Y), aeschynite-(Y), and samarskite-(Y) showed a certain degree of crystallinity (Figure 2f) which was significantly lower than in their synthetic analogues [64] or annealed samples [65,66].

Unaltered euxenite-group minerals contained very little Si and Ca and the absence of an aqueous fluid, and (Y–REE–U–Th)–(Nb–Ta–Ti) oxide minerals from Arvogno experienced no dissolution–precipitation reactions that led to the formation of nanoporosity or diffusion reactions, which usually allow the remobilization of U and strategic metals, like HFSE, at the scale of the pegmatite.

Brittle structures crosscutting the Vigezzo–Centovalli Valley are related to hydrothermal processes: they belong to mineralized faults, cataclasites, and were active during the late Alpine stage under variable P–T conditions, but at the earlier stage, they did not affect Arvogno pegmatites, resulting as a set of rigid fractures only affecting the pegmatites after their emplacement.

Previous studies [12] assumed different magmatic pulses occurred to emplace the pegmatite field of the Central Alps. As an example, the pegmatites that intruded the Codera and Bodengo areas (Figure 1) hosting rocks were dated at 28–25 m.y. or younger, around 20–22 m.y. [14]. Emplacement of these pegmatites could be related to the progressive regional metamorphic rejuvenation from east to west in the Central Alps, considering the progressive cooling of the thermal Lepontine Barrovian metamorphic dome [67].

It is worth mentioning that pegmatites of Arvogno have high contents of fluorite and they may crystallize at significantly lower temperatures [68] with respect to the crystallization temperatures of pegmatites within the Masino–Bregaglia intrusion (Br in Figure 1), where the emplacement temperatures of pegmatite dikes occurred at least at 550 °C [14].

Ta/Nb fractionation is generally well developed in Nb–Ta-oxide minerals from the REL–Li (rare-element–Li-bearing) pegmatites. The REL–REE (rare-element and rare-earth element) pegmatites of allanite-, euxenite-, and gadolinite-type from Arvogno reveal the activity of F does not affect Ta fractionation [69,70] and no Ta-bearing oxides were observed in these pegmatites.

The bulk composition, geochemistry, and structural geology data will be the subject of a forthcoming publication that will provide the conditions of emplacement for these unique NYF pegmatites in the Alpine chain and may give indications on crystallization processes which occur among aeschynite- (Y), polycrase-(Y), and samarskite-(Y) from Arvogno.

[Image omitted. See PDF.]

[Image omitted. See PDF.] statistical diagram is shown in (d) and the chondrite versus normalized REE pattern of aeschynite-(Y), polycrase-(Y), and samarskite-(Y) from Arvogno is shown in (e). For all plots, aeschynite-(Y) and polycrase-(Y) are plotted in white and samarskite-(Y) in grey. Raman spectra of aeschynite-(Y) from Bosco1, samarskite-(Y) from Bosco3, and polycrase-(Y) from Fiume1 are shown in (f)."]

[Image omitted. See PDF.]

[Image omitted. See PDF.]

SampleBosco1Bosco2
Analyses64/165/166/167/168/169/170/127/128/129/130/131/132/133/134/135/136/137/138/1
MineralA-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)A-(Y)
WO3 (wt.% )2.292.332.212.493.333.653.281.581.821.431.331.070.680.671.471.721.621.210.95
Nb2O511.611.512.012.413.413.712.720.421.021.220.221.822.221.920.921.020.421.722.0
Ta2O519.6219.8418.9216.0312.469.579.369.119.5810.6711.359.9010.0210.049.589.468.899.589.56
SiO20.100.120.110.120.110.140.120.130.150.110.140.130.120.110.130.130.130.130.13
TiO228.428.027.829.331.131.432.727.227.026.426.424.823.623.626.227.127.625.224.7
ThO24.834.795.915.704.777.645.893.303.143.403.412.502.983.013.463.173.072.822.98
UO22.372.372.733.203.444.224.527.686.136.196.679.5810.2410.396.346.227.468.899.01
Sc2O30.000.000.000.000.050.000.000.080.080.080.100.060.080.070.100.090.060.070.07
FeOtot0.820.840.880.850.710.800.550.860.880.930.901.311.831.880.900.860.861.111.47
Y2O321.120.720.321.122.320.221.821.221.820.720.518.316.916.920.721.221.218.818.2
Ce2O30.420.400.380.350.360.280.290.150.170.120.130.000.180.140.120.140.000.150.18
Nd2O30.851.040.760.710.550.610.490.160.170.190.300.320.310.360.250.000.150.210.29
Sm2O31.091.140.970.800.660.790.580.260.400.460.500.540.620.620.470.370.300.460.48
Gd2O32.332.482.322.201.992.001.881.541.831.972.102.312.282.381.991.841.591.962.10
Tb2O30.350.370.320.330.300.310.290.230.290.340.350.390.360.400.320.300.260.330.34
Dy2O32.232.282.202.152.182.242.132.042.212.522.522.932.912.802.312.142.022.452.68
Ho2O30.260.270.370.270.370.290.340.330.380.380.450.430.540.390.370.390.390.390.43
Er2O31.021.091.051.101.241.221.311.451.431.511.561.761.761.751.411.441.401.621.66
Tm2O30.470.490.460.410.400.350.380.390.380.410.450.460.440.440.370.400.400.420.43
Yb2O30.920.960.990.981.161.111.371.601.531.571.541.761.751.741.381.521.681.721.74
Lu2O30.160.090.150.050.080.010.050.090.140.130.150.050.100.120.100.140.150.110.14
CaO0.340.350.330.260.260.280.240.140.140.160.150.260.220.250.140.100.110.150.18
MnO0.000.000.000.000.000.000.000.000.060.060.000.000.130.160.000.060.000.000.10
F0.160.180.160.140.000.000.000.000.000.000.120.000.000.000.000.100.110.000.00
Total101.7101.6101.3101.0101.2100.9100.399.9100.7100.8101.3100.6100.2100.199.099.899.899.499.8
W6+ (apfu)0.0370.0370.0360.0400.0520.0570.0510.0250.0280.0220.0210.0170.0110.0110.0230.0270.0250.0200.015
Nb5+0.3220.3230.3380.3450.3610.3750.3450.5620.5730.5810.5580.6130.6330.6270.5810.5760.5620.6100.621
Ta5+0.3290.3350.3210.2680.2030.1570.1530.1510.1570.1760.1880.1670.1720.1730.1600.1560.1470.1620.162
Si4+0.0060.0070.0070.0070.0070.0090.0070.0080.0090.0070.0080.0080.0080.0070.0080.0080.0080.0080.008
Ti4+1.3191.3061.3031.3541.4031.4271.4771.2481.2231.2051.2111.1581.1201.1231.2151.2361.2611.1791.158
subtot.2.0132.0082.0052.0142.0262.0252.0331.9941.9901.9911.9861.9631.9441.9411.9872.0032.0021.9791.964
Th4+0.0680.0680.0840.0800.0650.1050.0800.0460.0430.0470.0470.0350.0430.0430.0490.0440.0430.0400.042
U4+0.0320.0330.0380.0440.0460.0570.0600.1040.0820.0840.0900.1330.1440.1460.0870.0840.1010.1230.125
Fe3+0.0420.0440.0460.0440.0350.0400.0280.0440.0450.0470.0460.0680.0970.0990.0460.0440.0440.0580.077
Sc3+0.0000.0000.0000.0000.0030.0000.0000.0040.0040.0040.0050.0030.0040.0040.0050.0050.0030.0040.004
Y3+0.6930.6840.6740.6900.7100.6500.6970.6870.7010.6700.6650.6040.5690.5690.6770.6860.6850.6220.606
Ce3+0.0090.0090.0080.0080.0080.0060.0060.0030.0040.0030.0030.0000.0040.0030.0030.0030.0000.0030.004
Nd3+0.0190.0230.0170.0160.0120.0130.0100.0040.0040.0040.0070.0070.0070.0080.0060.0000.0030.0050.007
Sm3+0.0230.0240.0210.0170.0140.0160.0120.0050.0080.0100.0110.0120.0130.0130.0100.0080.0060.0100.010
Gd3+0.0480.0510.0480.0450.0390.0400.0370.0310.0370.0400.0420.0480.0480.0500.0410.0370.0320.0400.043
Tb3+0.0070.0080.0070.0070.0060.0060.0060.0050.0060.0070.0070.0080.0080.0080.0070.0060.0050.0070.007
Dy3+0.0440.0460.0440.0430.0420.0440.0410.0400.0430.0490.0490.0590.0590.0570.0460.0420.0400.0490.054
Ho3+0.0050.0050.0070.0050.0070.0060.0060.0060.0070.0070.0090.0090.0110.0080.0070.0080.0080.0080.009
Er3+0.0200.0210.0200.0210.0230.0230.0250.0280.0270.0290.0300.0340.0350.0350.0270.0270.0270.0320.033
Tm3+0.0090.0090.0090.0080.0070.0070.0070.0070.0070.0080.0090.0090.0090.0090.0070.0080.0080.0080.008
Yb3+0.0170.0180.0190.0180.0210.0200.0250.0300.0280.0290.0290.0330.0340.0340.0260.0280.0310.0330.033
Lu3+0.0030.0020.0030.0010.0010.0000.0010.0020.0020.0020.0030.0010.0020.0020.0020.0030.0030.0020.003
Ca2+0.0220.0230.0220.0170.0160.0180.0150.0090.0090.0110.0100.0170.0150.0170.0090.0060.0070.0100.012
Mn2+0.0000.0000.0000.0000.0000.0000.0000.0000.0030.0030.0000.0000.0070.0080.0000.0030.0000.0000.005
subtot.1.0611.0671.0671.0631.0541.0501.0561.0561.0611.0541.0611.0801.1091.1141.0551.0421.0471.0531.082
F-0.0300.0340.0300.0270.0000.0000.0000.0000.0000.0000.0220.0000.0000.0000.0000.0200.0210.0000.000
O2-5.9845.9835.9885.9875.9976.0005.9986.0015.9975.9995.9885.9955.9985.9965.9995.9895.9906.0005.995
REE + Sc + Y0.870.870.850.850.870.810.850.830.860.840.850.810.790.780.840.840.830.810.80
U/(Th + U)0.320.330.310.350.410.350.430.690.660.640.660.790.770.770.640.660.700.750.75
Nd/Yb1.041.220.860.810.540.620.410.120.120.140.220.200.190.230.21 0.100.140.19
Ta/(Nb + Ta)0.500.510.490.440.360.300.310.210.220.230.250.210.210.220.220.210.210.210.21
CV16.406.306.076.366.866.637.025.535.675.455.534.814.294.265.245.485.564.824.65
CV2−2.95−2.92−2.78−2.78−2.95−2.53−2.63−2.86−3.21−3.09−3.12−2.88−2.80−2.78−2.74−2.87−2.81−2.61−2.78
Bosco2Bosco4Fiume1
#Analyses39/140/141/142/117/118/119/120/121/11/13/14/15/16/17/18/19/110/111/1
MineralA-(Y)A-(Y)A-(Y)A-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)P-(Y)
WO3 (wt.% )1.110.880.750.700.630.590.640.580.650.520.570.590.530.540.500.530.490.430.47
Nb2O521.722.122.222.218.017.817.318.318.421.722.119.320.018.918.515.215.020.015.2
Ta2O59.619.7610.049.8623.923.723.524.024.015.815.816.216.517.617.718.418.516.418.7
SiO20.120.120.130.120.110.120.140.120.130.130.140.120.120.110.120.120.120.140.13
TiO224.824.223.523.519.919.920.319.719.921.521.424.622.922.822.924.024.023.124.3
ThO22.932.863.043.063.003.023.252.772.883.773.722.952.533.513.633.593.583.613.48
UO28.819.5210.0810.144.905.295.374.354.673.793.886.206.706.726.909.068.986.019.42
Sc2O30.070.070.060.070.350.350.320.330.320.050.000.000.000.000.060.000.000.000.00
FeOtot1.381.501.831.891.451.591.511.581.561.661.660.801.261.381.451.181.161.271.21
Y2O318.718.016.816.817.417.317.217.817.818.418.419.217.617.117.215.915.817.615.8
Ce2O30.140.210.000.160.230.210.190.220.190.200.200.130.180.190.190.150.120.220.19
Nd2O30.290.250.340.320.450.480.500.420.460.420.450.160.360.470.400.370.410.410.37
Sm2O30.510.490.600.610.720.780.750.710.790.750.750.440.660.750.700.650.620.720.70
Gd2O32.072.072.352.322.001.992.012.041.922.222.271.982.352.262.232.172.192.252.27
Tb2O30.350.320.390.390.360.330.340.330.330.430.400.350.410.430.390.360.350.400.44
Dy2O32.582.642.912.892.202.192.252.242.212.722.732.743.022.952.852.782.722.973.00
Ho2O30.340.490.450.520.290.300.300.280.290.370.330.400.380.340.370.390.360.450.41
Er2O31.631.691.771.811.121.091.081.171.141.411.451.711.711.541.481.521.491.581.52
Tm2O30.410.430.380.440.610.570.580.600.590.500.520.570.580.570.550.550.550.540.57
Yb2O31.741.731.771.751.481.471.441.511.462.031.992.112.001.831.791.511.521.951.58
Lu2O30.130.150.140.140.300.320.310.270.310.230.260.250.230.220.210.160.170.260.16
CaO0.180.200.260.200.940.880.810.890.860.410.440.160.310.320.340.210.200.320.23
MnO0.120.070.160.100.360.330.270.300.300.220.230.060.120.160.170.090.130.140.10
F0.000.000.000.000.120.000.120.120.130.000.000.000.000.000.000.000.000.000.00
Total99.699.8100.0100.0100.9100.6100.5100.7101.399.299.7101.0100.4100.7100.798.998.5100.7100.2
W6+ (apfu)0.0180.0140.0120.0120.0110.0100.0110.0100.0110.0090.0090.0100.0090.0090.0080.0090.0080.0070.008
Nb5+0.6110.6270.6350.6350.5290.5250.5120.5380.5360.6270.6360.5450.5760.5470.5370.4520.4490.5720.447
Ta5+0.1630.1670.1730.1700.4220.4190.4170.4230.4210.2750.2740.2760.2860.3060.3080.3280.3320.2820.331
Si4+0.0080.0080.0080.0080.0070.0080.0090.0080.0080.0080.0090.0080.0070.0070.0070.0080.0080.0090.009
Ti4+1.1631.1441.1201.1200.9720.9740.9950.9620.9681.0331.0241.1551.0951.0981.1041.1881.1901.1011.188
subtot.1.9631.9601.9481.9451.9411.9361.9441.9411.9441.9521.9511.9941.9731.9671.9641.9851.9871.9711.983
Th4+0.0420.0410.0440.0440.0440.0450.0480.0410.0420.0550.0540.0420.0370.0510.0530.0540.0540.0520.051
U4+0.1220.1330.1420.1430.0710.0770.0780.0630.0670.0540.0550.0860.0950.0960.0980.1320.1320.0850.136
Fe2+0.0720.0790.0970.1000.0790.0870.0820.0860.0840.0890.0880.0420.0670.0740.0770.0650.0640.0670.066
Sc3+0.0040.0040.0030.0040.0200.0200.0180.0190.0180.0030.0000.0000.0000.0000.0030.0000.0000.0000.000
Y3+0.6200.6020.5670.5670.6010.5990.5980.6150.6090.6260.6220.6380.5950.5840.5850.5560.5540.5940.546
Ce3+0.0030.0050.0000.0040.0050.0050.0050.0050.0040.0050.0050.0030.0040.0040.0040.0040.0030.0050.004
Nd3+0.0060.0060.0080.0070.0100.0110.0120.0100.0110.0090.0100.0030.0080.0110.0090.0090.0100.0090.009
Sm3+0.0110.0110.0130.0130.0160.0170.0170.0160.0180.0160.0160.0100.0150.0160.0160.0150.0140.0160.016
Gd3+0.0430.0430.0490.0490.0430.0430.0430.0440.0410.0470.0480.0410.0500.0480.0470.0470.0480.0470.049
Tb3+0.0070.0070.0080.0080.0080.0070.0070.0070.0070.0090.0080.0070.0090.0090.0080.0080.0080.0080.009
Dy3+0.0520.0530.0590.0590.0460.0460.0470.0470.0460.0560.0560.0550.0620.0610.0590.0590.0580.0610.063
Ho3+0.0070.0100.0090.0110.0060.0060.0060.0060.0060.0080.0070.0080.0080.0070.0080.0080.0080.0090.008
Er3+0.0320.0330.0350.0360.0230.0220.0220.0240.0230.0280.0290.0340.0340.0310.0300.0310.0310.0310.031
Tm3+0.0080.0080.0080.0090.0120.0110.0120.0120.0120.0100.0100.0110.0110.0110.0110.0110.0110.0110.012
Yb3+0.0330.0330.0340.0340.0290.0290.0290.0300.0290.0400.0390.0400.0390.0360.0350.0300.0310.0380.031
Lu3+0.0020.0030.0030.0030.0060.0060.0060.0050.0060.0040.0050.0050.0040.0040.0040.0030.0030.0050.003
Ca2+0.0120.0130.0170.0130.0650.0610.0560.0620.0590.0280.0300.0110.0210.0220.0240.0150.0140.0220.016
Mn2+0.0060.0040.0090.0050.0200.0180.0150.0170.0160.0120.0130.0030.0070.0080.0090.0050.0070.0070.006
subtot.1.0811.0861.1051.1091.1031.1101.0991.1081.0961.0991.0941.0381.0661.0731.0791.0521.0501.0671.055
F−0.0000.0000.0000.0000.0230.0000.0250.0250.0260.0000.0000.0000.0000.0000.0000.0000.0000.0000.000
O2−5.9975.9986.0016.0015.9885.9965.9855.9915.9856.0025.9966.0016.0046.0005.9995.9975.9985.9965.995
REE + Sc + Y0.810.800.780.790.790.790.790.800.800.840.840.840.830.810.800.770.760.820.77
U/(Th + U)0.750.760.760.760.610.630.620.610.610.500.500.670.720.650.650.710.710.620.73
Nd/Yb0.190.160.210.200.340.360.390.310.350.230.250.080.210.290.250.280.300.240.26
Ta/(Nb + Ta)0.210.210.210.210.440.440.450.440.440.300.300.340.330.360.360.420.430.330.43
CV14.704.544.214.233.793.743.813.753.874.044.095.034.464.434.404.344.264.554.53
CV2−2.78−2.76−2.72−2.76−2.69−2.67−2.57−2.76−2.82−2.91−3.01−2.91−2.80−2.75−2.71−1.95−1.83−2.84−2.18

Note: A-(Y) = Aeschynite-(Y), P-(Y) = Polycrase-(Y); empirical formula was calculated on the basis of sum of all cations = 3.

Sample Bosco3 Bosco4
#Analyses 43/1 44/1 45/1 46/1 47/1 48/1 50/1 51/1 12/1 13/1 14/1 15/1 16/1 22/1 23/1 24/1 25/1
Mineral S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y) S-(Y)
WO3 (wt.%)3.323.373.431.611.451.491.591.643.143.663.501.941.633.343.621.931.82
Nb2O526.727.526.425.425.725.826.725.122.126.226.227.626.127.229.028.027.7
Ta2O525.024.425.125.424.324.925.325.432.125.825.820.827.324.421.420.422.7
SiO20.100.090.100.100.120.120.110.130.110.130.110.130.110.120.120.130.12
TiO23.843.953.945.216.026.034.736.113.233.783.606.404.793.844.035.995.26
ZrO20.510.510.540.490.500.540.310.610.480.570.480.500.390.490.490.520.40
ThO22.582.602.652.572.812.742.592.342.642.732.712.602.412.812.942.972.90
UO23.233.093.054.775.194.414.033.782.672.843.255.473.743.143.045.275.18
Sc2O30.780.780.710.630.580.670.730.660.920.860.820.560.950.690.700.610.69
FeOtot8.988.988.839.549.439.069.149.238.458.808.749.469.148.989.069.219.36
Y2O311.812.112.011.811.612.112.312.612.412.511.911.612.911.811.911.311.6
Ce2O30.140.170.170.000.130.170.140.000.160.170.170.130.000.180.170.180.00
Nd2O30.390.430.370.280.360.290.300.300.360.430.440.370.260.450.480.410.38
Sm2O30.740.670.690.620.610.650.600.650.740.740.740.650.540.770.760.680.66
Gd2O31.771.711.761.701.581.561.631.461.591.581.761.691.491.741.851.731.67
Tb2O30.390.420.410.410.380.390.360.390.390.320.430.380.310.400.400.400.42
Dy2O31.951.811.871.831.871.671.771.751.661.841.892.011.571.911.941.871.89
Ho2O30.260.220.210.230.240.210.220.190.200.280.220.300.240.200.240.260.17
Er2O30.880.940.880.920.890.840.820.890.750.800.900.980.800.950.860.930.93
Tm2O30.250.270.200.220.230.210.260.250.270.230.260.260.230.200.180.130.21
Yb2O31.751.781.731.791.781.751.851.811.551.641.711.831.641.751.791.721.78
Lu2O30.290.280.280.360.290.300.320.410.370.280.330.250.320.320.260.200.24
CaO0.190.200.180.110.120.090.230.140.120.160.190.160.260.170.200.160.17
MnO1.131.071.090.760.750.790.710.771.121.121.110.720.671.061.080.890.75
Total97.197.496.696.896.996.896.796.697.697.597.296.897.896.996.695.997.0
W6+ (apfu)0.0750.0750.0770.0360.0320.0330.0360.0360.0730.0820.0790.0420.0360.0750.0810.0420.040
Nb5+1.0511.0701.0380.9960.9900.9831.0410.9580.8951.0271.0401.0461.0031.0671.1281.0741.068
Ta5+0.5930.5700.5940.5990.5620.5700.5940.5830.7830.6090.6140.4760.6300.5760.5000.4690.528
Si4+0.0090.0080.0090.0080.0110.0100.0090.0110.0100.0110.0090.0110.0090.0110.0100.0110.010
Ti4+0.2510.2550.2580.3400.3850.3820.3070.3880.2180.2460.2370.4040.3060.2510.2600.3820.337
Zr4+0.0210.0210.0230.0200.0210.0220.0130.0250.0210.0240.0210.0200.0160.0210.0210.0220.017
subtot.2.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.0002.000
Mn2+0.0830.0780.0800.0560.0540.0560.0520.0550.0850.0820.0820.0510.0480.0780.0790.0640.054
Fe3+0.6530.6450.6420.6910.6700.6380.6590.6500.6330.6370.6400.6640.6480.6500.6500.6520.667
subtot.0.7360.7230.7220.7470.7250.6940.7110.7050.7180.7190.7220.7150.6960.7280.7280.7160.721
Th4+0.0510.0510.0530.0510.0540.0530.0510.0450.0540.0540.0540.0500.0460.0560.0570.0570.056
U4+0.0630.0590.0590.0920.0980.0830.0770.0710.0530.0550.0630.1020.0710.0610.0580.0990.098
Sc3+0.0590.0590.0540.0480.0430.0490.0550.0490.0720.0650.0630.0410.0700.0520.0530.0450.051
Y3+0.5490.5510.5570.5420.5280.5440.5660.5650.5940.5780.5550.5180.5840.5440.5460.5080.529
Ce3+0.0040.0050.0050.0000.0040.0050.0040.0000.0050.0050.0050.0040.0000.0060.0050.0050.000
Nd3+0.0120.0130.0120.0090.0110.0090.0090.0090.0120.0130.0140.0110.0080.0140.0150.0120.012
Sm3+0.0220.0200.0210.0180.0180.0190.0180.0190.0230.0220.0220.0190.0160.0230.0220.0200.020
Gd3+0.0510.0490.0510.0490.0450.0440.0470.0410.0470.0450.0510.0470.0420.0500.0530.0490.047
Tb3+0.0110.0120.0120.0120.0110.0110.0100.0110.0120.0090.0120.0110.0090.0110.0110.0110.012
Dy3+0.0550.0500.0530.0510.0510.0450.0490.0480.0480.0510.0530.0540.0430.0530.0540.0510.052
Ho3+0.0070.0060.0060.0060.0060.0060.0060.0050.0060.0080.0060.0080.0070.0050.0060.0070.005
Er3+0.0240.0250.0240.0250.0240.0220.0220.0240.0210.0220.0250.0260.0210.0260.0230.0250.025
Tm3+0.0070.0070.0050.0060.0060.0060.0070.0060.0080.0060.0070.0070.0060.0050.0050.0040.006
Yb3+0.0460.0470.0460.0470.0460.0450.0490.0470.0420.0430.0460.0470.0430.0460.0470.0450.046
Lu3+0.0080.0070.0070.0090.0070.0080.0080.0100.0100.0070.0090.0060.0080.0080.0070.0050.006
Ca2+0.0170.0180.0170.0110.0110.0080.0210.0120.0110.0150.0180.0140.0230.0160.0180.0150.015
subtot.0.9870.9800.9800.9760.9640.9551.0010.9621.0171.0001.0040.9650.9960.9770.9810.9570.980
O2−7.4877.4567.4557.4567.3847.3267.4497.3377.5197.4857.5037.3737.4137.4647.4687.3637.432
REE + Sc + Y0.860.850.850.820.800.810.850.830.900.880.870.800.860.840.850.790.81
U/(Th + U)0.550.540.530.640.640.610.600.610.500.500.540.670.600.520.500.630.64
Nd/Yb0.260.290.250.180.230.200.190.190.270.310.300.240.180.300.310.280.25
Ta/(Nb + Ta)0.360.350.360.380.360.370.360.380.470.370.370.310.390.350.310.300.33
CV1−2.14−2.07−2.12−2.00−1.79−1.71−1.93−1.69−2.01−2.01−2.10−1.74−1.81−2.13−2.15−1.95−1.95
CV2−3.47−3.55−3.37−3.37−3.32−3.25−3.43−3.33−3.40−3.57−3.47−3.36−3.54−3.46−3.50−3.12−3.40

Note: S-(Y) = Samarskite-(Y); samarskite formula was calculated on the basis of W + Nb + Ta + Si + Ti + Zr = 2.

Bosco1 Bosco2 Bosco3 Bosco4 Fiume1
aeschynite-(Y) aeschynite-(Y) samarskite-(Y) polycrase-(Y) polycrase-(Y)
a (Å)11.043(3)10.95(7)9.9851(7)14.736(6)14.82(3)
b (Å)7.477(2)7.40(5)5.6386(3)5.605(1)5.66(1)
c (Å)5.201(9)5.170(10)5.1737(3)5.184(2)5.22(1)
α (°)90.0090.0090.0090.0090.00
β (°)90.0090.0093.061(5)90.0090.00
γ (°)90.0090.0090.0090.0090.00
V. cell. (Å3)429.43(18)419(4)290.87(2)428.2 (3)438 (2)
space groupPbnmn.d.n.d.PcanPcan
* Skoda and Novak [38]** Sugitani et al. [3,4]*** Simmons et al. [6]**** Britvin et al. [8]***** Bonazzi and Menchetti [39]
polycrase-(Y)samarskite-(Y)samarskite-(Yb)samarskite-(Y)aeschynite-(Y)
a (Å)10.9935.6425.688(9)9.8020(8)11.031(3)
b (Å)7.5319.9149.915(2)5.6248(3)7.448(2)
c (Å)5.3465.2295.199(9)5.2073(4)5.188(1)
α (°)90.0090.0090.0090.0090.00
β (°)90.0093.843.16(10)93.406(4)90.00
γ (°)90.0090.0090.0090.0090.00
V. cell (Å3)442.6292.88292.76286.59 (4)426.2 (2)
space groupn.d.n.d.n.d.P2/cPnma

* XRPD, cell data obtained upon heating the crystal to 650 and 750 °C (sample poz5); ** XRPD, cell data obtained upon heating the crystal to 1200 °C (sample Kawabe, Fukushima); *** XRPD, cell data obtained upon heating the crystal to 1100 °C (sample Little Patsy, Colorado); **** SCXRD, cell data obtained at room temperature; ***** SCXRD, cell data obtained at room temperature (sample VV).

Author Contributions

A.G. and L.S. conceived and designed the multidisciplinary study; A.G. produced and managed the article structure, A.G., L.S., R.Š. and M.N. performed electron microprobe analysis; R.Š. and M.N. performed the Raman analysis; F.N. performed the SCXRD analysis and discussed the results; M.S. reorganized and performed all the tables and the diagrams; A.G., L.S., R.Š., F.N. and M.N. wrote and revised the paper, discussed the main conclusions; L.S. and G.P. were involved in funding acquisition.

Funding

This research was funded by Progetto di Ateneo 2014, University of Padova”, GRANT CDPA140255.

Acknowledgments

This study was supported by the “Progetto di Ateneo 2014, University of Padova”, GRANT CPDA140255: “Tertiary pegmatites of the Central Alps: mineralogy, geochemistry, structural characters, and crystallization ages”. Electron microprobe analyses were carried out at the Faculty of Science, Masaryk University, Brno and at the Electron Microprobe Laboratory of the CNR Institute of Geosciences and Earth Resources (IGG). Padova. R. Carampin is thanked for providing technical assistance. The authors thanks C. Albertini, who provided the samples utilized for the study. The authors also thank the editor and three anonymous referees who helped to improve the quality of the paper.

Conflicts of Interest

The authors declare no conflict of interest.

References

1. Černý, P.; Ercit, T.S. The classification of granitic pegmatites revisited. Can. Mineral. 2005, 43, 2005–2026.

2. Aleksandrov, V.B. The crystal structure of aeschynite. Akad. Nauk SSSR Doklady 1962, 142, 181–184, English translation in Acad. Sci. USSR Doklady Earth Sci. Sect. 1964, 142, 107–109.

3. Sugitani, Y.; Suzuki, Y.; Nagashima, K. Recovery of the original samarskite structure by heating in a reducing atmosphere. Am. Mineral. 1984, 69, 377–379.

4. Sugitani, Y.; Suzuki, Y.; Nagashima, K. Polymorphism of samarskite and its relationship to other structurally related Nb-Ta oxides with the αPbO2 structure. Am. Mineral. 1985, 70, 856–866.

5. Warner, J.K.; Ewing, R.K. Crystal chemistry of samarskite. Am. Mineral. 1993, 78, 419–424.

6. Simmons, W.B.; Hanson, S.L.; Falster, A.U. Samarskite-(Yb): A new species of the samarskite group from the Little Patsy pegmatite, Jefferson County, Colorado. Can. Mineral. 2006, 44, 1119–1125.

7. Kjellman, J. ABC2O8—a new look on the crystal chemistry and classification of samarskite group minerals. In Proceedings of the PEG2017, 8th International Symposium on Granitic Pegmatites, Kristiansand, Norway, 13–15 June 2017; Volume 2, pp. 64–67.

8. Britvin, S.N.; Pekov, I.V.; Krzhizhanovskaya, M.G.; Agakhanov, A.A.; Ternes, B.; Schüller, W.; Chukanov, N.V. Redefinition and crystal chemistry of samarskite-(Y), YFe3+Nb2O8: Cation-ordered niobate structurally related to layered double tungstates. Phys. Chem. Miner. 2019.

9. Ewing, R.C.; Chakoumakos, B.C.; Murakami, T.; Lumpkin, G.R. The metamict state. MRS Bull. 1987, 12, 58–66.

10. Ewing, R.C. The metamict state: 1993 the centennial. Nucl. Instrum. Methods Phys. Res. 1994, 91, 22–29.

11. Lumpkin, G.R.; Ewing, R.C. Geochemical alteration of pyrochlore group minerals: Microlite subgroup. Am. Mineral. 1992, 77, 179–188.

12. Lumpkin, G.R.; Ewing, R.C. Geochemical alteration of pyrochlore group minerals: Betafite subgroup. Am. Mineral. 1996, 81, 1237–1248.

13. Ercit, T.S. Identification and alteration trends of granitic-pegmatite-hosted (Y,REE,U,Th)-(Nb,Ta,Ti) oxide minerals: A statistical approach. Can. Mineral. 2005, 43, 1291–1303.

14. Ruschel, K.; Nasdala, L.; Rhede, D.; Wirth, R.; Lengauer, C.L.; Libowitzky, E. Chemical alteration patterns in metamict fergusonite. Eur. J. Mineral. 2010, 22, 425–433.

15. Duran, C.J.; Seydoux-Guillaume, A.M.; Bingen, B.; Gouy, S.; De Parseval, P.; Ingrin, J.; Guillaume, D. Fluid-mediated alteration of (Y, REE, U, Th)–(Nb, Ta, Ti) oxide minerals in granitic pegmatite from the Evje-Iveland district, southern Norway. Mineral. Petrol. 2016, 110, 581–599.

16. Guastoni, A. LCT (lithium, cesium, tantalum) and NYF (niobium, yttrium, fluorine) Pegmatites in the Central Alps. Exhumation History, Mineralogy and Geochemistry. Ph.D. Thesis, University of Padova, Padova, Italy, 2012; p. 145.

17. Guastoni, A.; Pennacchioni, G.; Pozzi, G.; Fioretti, A.M.; Walter, J.M. Tertiary pegmatite dikes of the Central Alps. Can. Mineral. 2014, 52, 191–219.

18. Černý, P.; Petr, Č.; London, D.; Novák, M. Granitic Pegmatites as Reflections of Their Sources. Elements 2012, 8, 289–294.

19. Simmons, W.B.; Pezzotta, F.; Shigley, G.E.; Beurlen, H. Granitic Pegmatites as Sources of Colored Gemstones. Elements 2012, 8, 281–287.

20. Lima de Faria, J. Identification of Metamict Minerals by X-ray Powder Photographs. In Junta deInvestigacoes do Ultramar, Estudos, Ensaios e Documentos; Encademação dos editors: Lisbon, Portugal, 1964; p. 112.

21. Komkov, A.I. Structure and composition of samarskite. Akad. Nauk SSSR Doklady 1965, 160, 693–696. (In Russian); Translated in Acad. Sci. USSR Doklady Earth Sci Sect. 1965, 160, 127–129

22. Johnsen, O.; Stahl, K.; Petersen, O.V.; Micheelsen, H.I. Structure refinement of natural non-metamict polycrase-(Y) from Zomba-Malosa complex, Malawi. Neues Jb. Miner. Monat. 1999, 1, 1–10.

23. Burri, T.; Berger, A. Tertiary migmatites in the Central Alps: Regional distribution, field relations, conditions of formation and tectonic implications. Schweiz. Mineral. Petrogr. Mitt. 2005, 83, 215–235.

24. Steck, A.; Hunziker, J. The Tertiary structural and thermal evolution of the Central Alps—compressional and extensional structures in an orogenic belt. Tectonophysics 1994, 238, 229–254.

25. Mancktelow, N.S. The Simplon Line: A major displacement zone in the western Lepontine Alps. Eclogae Geol. Helveticae 1985, 78, 73–96.

26. Knup, P. Geologie und Petrographie des Gebietes zwischen Centovalli- Valle Vigezzo und Onsernone. Schweiz. Mineral. Petrogr. Mitt. 1958, 38, 83–236.

27. Steck, A. Tectonics of the Simplon massif and Lepontine gneiss dome: Deformation structures due to collision between the underthrusting European plate and the Adriatic indenter. Swiss J. Geosci. 2008, 101, 515–546.

28. Surace, I.R. Evénements et deformations tardi-métamorphiques dans le segment Ossola-Ticino (Val Vigezzo-Centovalli, Italie-Suisse). Ph.D. Thesis, Université de Lausanne, Lausanne, Switzerland, 2004.

29. Strüver, G. Sulla columbite di Craveggia in Val Vigezzo. Rendiconti R. Accad. Naz. Lincei 1885, 1, 8.

30. Zambonini, F. Strüverite, un nuovo minerale. Accad. Sci. Fis. e Mat. (Soc. Naz. Sci. Lettere ed Arti Napoli) Rend. 1907, 13, 35–41.

31. Zambonini, F. Delorenzite, un nuovo minerale. Accad. Sci. Fis. e Mat. (Soc. Naz. Sci. Lettere ed Arti Napoli) Rend. 1908, 13, 35–51.

32. De Pol, C.; Vescovi Minutti, L. Ricerche roentgenografiche sulla tanteuxenite di Craveggia (delorenzite di Zambonini). Rend. Soc. Mineral. Ital. 1967, 22, 31–45.

33. Roggiani, A.G. Notizie mineralogiche su pegmatiti della valle ossolana. Tapiolite di Pian del Lavonchio in comune di Craveggia (Valle Vigezzo - Ossola). Rend. Soc. Ital. Mineral. Petrol. 1970, 26, 291–311.

34. Albertini, C.; Andersen, T. Non-metamict orthorhombic AB2O6 Y-Nb-Ta-Ti oxides from a pegmatite in Arvogno, Crana Valley (Toceno, Vigezzo Valley, Northern Italy). Rend. Soc. Ital. Mineral. Petrol. 1989, 43, 773–779.

35. Mattioli, V. Una nuova pegmatite in val di Crana. Riv. Mineral. Ital. 1986, 3, 101–106.

36. Bigioggero, B.; Boriani, A.; Colombo, A.; Ferrara, G.; Tunesi, A.; Tonarini, S. Età e caratteri petrochimici degli ortogneiss della zona Moncucco-Orselina nell’area ossolana. Rend. Soc. Ital. Mineral. Petrol. 1981, 38, 207–218.

37. Merlet, C. An Accurate Computer Correction Program for Quantitative Electron Probe Microanalysis. Microchim. Acta 1994, 114–115, 363–376.

38. Škoda, R.; Novák, M. YREE,Nb,Ta,Ti-oxide (AB2O6) minerals from REL–REE euxenite subtype pegmatites of the Třebíč Pluton, Czech Republic; substitutions and fractionation trends. Lithos 2007, 95, 43–57.

39. Bonazzi, P.; Menchetti, S. Crystal chemistry of aeschynite-(Y) from the Western Alps: Residual electron density on difference-Fourier map. Eur. J. Mineral. 1999, 11, 1043–1049.

40. Guastoni, A.; Diella, V.; Pezzotta, F. Vigezzite and associated oxides of Nb-Ta from emerald bearing pegmatites of the Vigezzo valley (Western Alps, Italy). Can. Mineral. 2008, 46, 783–797.

41. Guastoni, A.; Pozzi, G.; Secco, L.; Schiazza, M.; Pennacchioni, G.; Fioretti, A.; Nestola, F. Monazite-(Ce) and xenotime-(Y) from an LCT, NYF tertiary pegmatite field: Evidence from a regional study in the central Alps (Italy and Switzerland). Can. Mineral. 2016, 54, 863–877.

42. Hanson, S.L.; Simmons, W.B.; Webber, K.L.; Falster, A.U. Rare-earth-element mineralogy of granitic pegmatites in the Trout Creek Pass District, Chaffee County, Colorado. Can. Mineral. 1992, 30, 673–686.

43. Bonazzi, P.; Zoppi, M.; Dei, L. Metamict aeschynite-(Y) from the Evje-Iveland district (Norway) heat-induced recrystallization and dehydrogenation. Eur. J. Mineral. 2002, 14, 141–150.

44. Škoda, R.; Plášil, J.; Jonsson, E.; Čopjaková, R.; Langhof, J.; Galiová, M.V. Redefinition of thalénite-(Y) and discreditation of fluorthalénite-(Y): A re-investigation of type material from the Österby pegmatite, Dalarna, Sweden, and from additional localities. Mineral. Mag. 2015, 79, 965–983.

45. Hanson, S.L.; Simmons, W.B.; Falster, A.U.; Foord, E.E.; Lichte, F.E. Proposed nomenclature for samarskite-group minerals: New data on ishikawaite and calciosamarskite. Mineral. Mag. 1999, 63, 27–36.

46. Adusumilli, M.S.; Kieft, C.; Burke, E.A.J. Tantal-aeschynite, a new mineral of the aeschynite group from the Borborema region, north-eastern Brazil. Mineral. Mag. 1974, 39, 571–576.

47. Bermanec, V.; Tomašić, N.; Kniewald, G.; Back, M.E.; Zagler, G. Nioboaeschynite-(Y), a new member of the aeschynite group from the Bear Lake Diggings, Haliburton County, Ontario, Canada. Can. Mineral. 2008, 46, 395–402.

48. McDonough, W.F.; Sun, S. The composition of the Earth. Chem. Geol. 1995, 120, 223–253.

49. Irber, W. The lanthanide tetrad effect and its correlation with K/Rb, Eu/Eu*, Sr/Eu, Y/Ho, and Zr/Hf of evolving peraluminous granite suites. Geochim. Cosmochim. Acta 1999, 63, 489–508.

50. Dolejš, D.; Štemprok, M. Magmatic and hydrothermal evolution of Li-F granites: Cínovec and Krásno intrusions, Krušné hory batholith, Czech Republic. Bull. Czech Geol. Survey 2001, 76, 77–99.

51. Peretyazhko, I.S.; Savina, E.A. Tetrad effects in the rare earth element patterns of granitoid rocks as an indicator of fluoride-silicate liquid immiscibility in magmatic systems. J. Petrol. 2010, 18, 514–543.

52. Wu, C.; Liu, S.; Gu, L.; Zhang, Z.; Lei, R. Formation mechanism of the lanthanide tetrad effect for a topaz- and amazonite-bearing leucogranite pluton in eastern Xinjiang, NW China. J. Asian Earth Sci. 2011, 42, 903–916.

53. Cao, M.J.; Zhou, Q.; Qin, K.Z.; Tang, D.M.; Evans, N.J. The tetrad effect and geochemistry of apatite from the Altay Koktokay No. 3 pegmatite, Xinjiang, China: Implications for pegmatite petrogenesis. Min. Petrol. 2013, 107, 985–1005.

54. Čopjaková, R.; Škoda, R.; Vašinová Galiová, M.; Novák, M. Distributions of Y + REE and Sc in tourmaline and their implications for the melt evolution; examples from NYF pegmatites of the Třebíč Pluton, Moldanubian Zone, Czech Republic. J. Geosci. 2013, 58, 113–131.

55. Čopjaková, R.; Škoda, R.; Vašinová Galiová, M.; Novák, M. Scandium- and REE-rich tourmaline replaced by Sc-rich REE-bearing epidote-group minerals from the mixed (NYF+LCT) Kracovice pegmatite (Moldanubian Zone, Czech Republic). Am. Mineral. 2015, 100, 1434–1451.

56. Monecke, T.; Kempe, U.; Monecke, J.; Sala, M.; Wolf, D. Tetrad effect in rare earth element distribution patterns: A method of quantification with application to rock and mineral samples from granite-related rare metal deposits. Geochim. Cosmochim. Acta 2002, 66, 1185–1196.

57. Badanina, E.V.; Trumbull, R.B.; Dulski, P.; Wiedenbeck, M.; Veksler, I.V.; Syritso, L.M. The behavior of rare-earth and lithophile trace elements in rara-metal granites: A study of fluorite, melt inclusions and host rocks from the Khangilay complex, Transbaikalia, Russia. Can. Mineral. 2006, 44, 667–692.

58. Ewing, R.C. The crystal chemistry of complex niobium and tantalum oxides. IV. The metamict state: Discussion. Am. Mineral. 1975, 60, 728–733.

59. Berman, J. Identification of metamict minerals by X-ray diffraction. Am. Mineral. 1955, 40, 805–827.

60. Lumpkin, G.R.; Ewing, R.C. Geochemical alteration of pyrochlore group minerals: Pyrochlore subgroup. Am. Mineral. 1995, 80, 732–743.

61. Lahti, S.I. Zoning in columbite-tantalite crystals from the granitic pegmatites of the Eräjärvi area, southern Finland. Geochim. Cosmochim. Acta 1987, 51, 509–517.

62. Novák, M.; Chládek, S.; Uher, P.; Gadas, P. Complex magmatic and subsolidus compositional trends of columbite-tantalite in the beryl-columbite Šejby granitic pegmatite, Czech Republic: Role of crystal-structural constraints and associated minerals. J. Geosci. 2018, 63, 253–263.

63. Capitani, G.C.; Mugnaioli, E.; Guastoni, A. What is the actual structure of samarskite-(Y)? A TEM investigation of metamict samarskite from the garnet Codera dike pegmatite (Central Italian Alps). Am. Mineral. 2016, 101, 1679–1690.

64. Paschoal, C.W.A.; Moreira, R.L.; Fantini, C.; Pimenta, M.A.; Surendran, K.P.; Sebastian, M.T. Raman scattering study of RETiTaO6 dielectric ceramics. J. Eur. Cer. Soc. 2003, 23, 2661–2666.

65. Tomašić, N.; Gajović, A.; Bermanec, V.; Rajić, M. Recrystallization of metamict Nb–Ta–Ti–REE complex oxides: A coupled X-ray-diffraction and Raman spectroscopy study of aeschynite-(Y) and polycrase-(Y). Can. Mineral. 2004, 2, 1847–1857.

66. Tomašić, N.; Gajović, A.; Bermanec, V.; Linarić, M.R.; Su, D.; Škoda, R. Preservation of the samarskite structure in a metamict ABO4 mineral: A key to crystal structure identification. Eur. J. Mineral. 2010, 22, 435–442.

67. Romer, R.L.; Schärer, U.; Steck, A. Alpine and pre-Alpine magmatism in the root-zone of the western Central Alps. Contrib. Mineral. Petrol. 1996, 123, 138–158.

68. London, D. The application of experimental petrology to the genesis and evolution of granitic pegmatites. Can. Mineral. 1992, 30, 499–540.

69. Černý, P.; Ercit, T.S. Mineralogy of niobium and tantalium: Crystal chemical relationships, paragenesis aspects and their economic implications. In Lanthanides, Tantalum, and Niobium; Möller, P., Černý, P., Saupé, F., Eds.; Springer Verlag: Berlin/Heidelberg, Germany, 1989; pp. 27–79.

70. Linnen, R.L.; Keppler, H. Columbite solubility in granitic melts: Consequences for the enrichment and fractionation of Nb and Ta in the Earth’s crust. Contrib. Mineral. Petrol. 1997, 128, 213–227.

AuthorAffiliation

1Department of Geosciences, Padova University, Via Gradenigo 6, 35131-I Padova, Italy

2Department of Geological Sciences, Faculty of Science, Masaryk University, Kotlarska 2 CZ 611 37, Brno, Czech Republic

3DiSPuTer, Chieti-Pescara University, Via dei Vestini 31, 66100-I Chieti, Italy

*Author to whom correspondence should be addressed.

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© 2019. This work is licensed under https://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Details

Title
Non-Metamict Aeschynite-(Y), Polycrase-(Y), and Samarskite-(Y) in NYF Pegmatites from Arvogno, Vigezzo Valley (Central Alps, Italy)
Author
Guastoni, Alessandro; Secco, Luciano; Škoda, Radek; Nestola, Fabrizio; Schiazza, Mariangela; Novák, Milan; Pennacchioni, Giorgio
Publication year
2019
Publication date
May 2019
Publisher
MDPI AG
e-ISSN
2075163X
Source type
Scholarly Journal
Language of publication
English
DOI
https://doi.org/10.3390/min9050313
ProQuest document ID
2311988923
Copyright
© 2019. This work is licensed under https://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.