Raman Microspectroscopy of Garnets from S-Fibulae from the Archaeological Site Lajh (Slovenia)

: Garnets (19 pieces) of Late Antique S-fibulae from the archaeological site at Lajh-Kranj (Slovenia) were analysed with Raman microspectroscopy to obtain their mineral characteristic, including inclusion assemblage. Most garnets were determined as almandines Type I of pyralspite solid solution series; however, three garnets showed a higher Mg, Mn and Ca contents and were determined as almandines Type II. Most significant Raman bands were determined in the range of 169–173 cm −1 (T(X 2+ )), 346–352 cm −1 (R(SiO 4 )), 557–559 cm −1 (ν 2 ), 633–637 cm −1 (ν 4 ), 917–919 cm −1 (ν 1 ), and 1042–1045 cm −1 (ν 3 ). Shifting of certain Raman bands toward higher frequencies was the result of an increase of the Mg content in the garnet composition, which also indicates the presence of pyrope end member in solid garnet solutions. Inclusions of apatite, quartz, mica, magnetite, ilmenite, as well as inclusions with pleochroic or radiation halo and tension fissures (zircon), were found in most of the garnets. Rutile and sillimanite were found only in garnets with the highest pyrope content. Spherical inclusions were also observed in two garnets, which may indicate the presence of melt or gas residues. The determined inclusion assemblage indicates the formation of garnets during medium- to high-grade metamorphism of amphibolite or granulite facies. According to earlier investigations of the garnets from Late Antique jewellery, the investigated garnets are believed to originate from India. Billerica, MA, USA) with a 3 mm X-ray spot to determine their chemical composition. The analyses were performed using the Cu/Zn Mining mode with continuous helium purge for better detection of light elements (Mg, Si, Al, S and P), which are included in the manufacturer’s software. The reference materials SiO 2 , NIST-88b and NIST-1d were used at the beginning and end of the measurements to calibrate light elements. The pre-calibration with 25 international standards was performed with the same specifications and preferences as the measurements. Calibration curves were generated for all elements of interest (Si, Al, Fe, Mg, Ca, Mn). Two measurements were made on garnet of the fibulae, with an of 210 s for each measurement. The element assignments the Billerica, MA, USA). The


Introduction
The production of ornamented metal jewellery decorated with red garnets has a long history in both European and Eastern cultures, dating back to the 3rd century BC. Garnet-inlaid metalwork made in the "cloisonné" technique, became widely spread among Migration Period Germanic tribes during the Late Antique to Early Middle Ages (4th to 8th century AD), although, the manufacture of cloisonné jewellery supposedly originated from the East in the Black Sea region [1,2]. The investigation of geographical and geological origin of garnets using chemical and mineralogical characterisation is and remains the subject of many studies, from the perspective of understanding the deposits of minerals and trade routes that linked them to the rest of the world, since large amounts of gemstones have been used in jewellery production [2][3][4][5][6][7][8][9][10].
The determination of the structure, composition and physical properties of minerals from archaeological artefacts is difficult since they should not be compromised. In this case, non-destructive analytical methods can be used. Chemical analysis is obtained by various analytical provide information about material transfers in the Earth system [27]. Melt, fluid or gas phases could also be observed in minerals, which can be trapped or preserved during (re-)crystallisation and are mostly associated with the material transfer in the Earth system, from shallow mineralization to re-fertilization of the mantle by subduction [27].
The characteristics of inclusions can be identified by Raman microspectroscopy. In garnets, solid inclusions are mostly found in almandines, pyrope-almandines and pyropes, although various inclusions or textures may be observed in other types of garnets as presented in Table 1, depending on the environment of formation and origin [30,31]. Table 1. Commonly recognized solid inclusions in garnets [30,31]. By determining the chemical composition and, in rare cases, even the mineral inclusions of Merovingian Kingdom (mid-5th-7th century AD); gemstones from France, Belgium and South Germany; and five different types of garnets and their probable geographical-geological origin have been possible to be identified to date (e.g., [2][3][4][5][6][7][8][9]). Two types of almandine, group of garnets with the intermediate composition of pyrope-almandine (also in terms of gemmology-rhodolite or pyraldine, e.g., [5]) and two types of pyrope were determined. Differences in the garnet composition are shown in Table 2. Table 2. Determined groups of garnets from Late Antique-Early Middle age jewellery, according to the definition of Calligaro et al. (2002) [4] and Gilg et al. (2010) [8], based on the chemical composition of garnets.

Calligaro et
al. [ Almandine (Type I and II) garnets supposedly originate from India, with several possible deposits in Rajasthan, Andhra Pradesh and Odisha, whereas rhodolites (Type III) originate from Sri Lanka. Pyropes (Type V) originate from the Czech Republic, but also Portuguese and/or East African pyropes (Type IV) can be found [5][6][7]. Another variety of almandine garnet with high Ca content (Group C) was found mainly in Scandinavian jewellery [8,10]. Depending on the time of the occurrence, rhodolites and Type II almandines were common until the 5 th century AD, while type I almandines prevailed since the 6th century AD. In the 7th century AD, significant changes in trading routes occurred on the East, which contributed to the use of Bohemian pyropes (Type V garnets) [8].
Optical microscopy and Raman spectroscopy used in inclusion analysis show that mostly  apatite, monazite, zircon, uraninite, xenomorphic Fe-chlorite, and rarely rutile, were present in Type  I almandines. On the other hand, for type II almandines, xenomorphic quartz crystals, ilmenite,  zircon, uraninite, monazite, rutile needles and sillimanite were identified [4,8,31,32]. The latter might indicate the formation in high metamorphic rocks [31,32]. Concerning the geological origin of garnets and their deposits, they are all vastly characterised by various metamorphic rocks of different ages (Precambrian to younger). The Indian deposits are geologically characterised by various rocks of amphibolite to granulite facies (e.g., different types of schists, gneiss and amphibolites) formed during medium-to high-grade metamorphism, which can provide almandines and pyropes of various chemical compositions [33,34]. The island of Sri Lanka is formed of various Precambrian metamorphic rocks (e.g., granulites, gneiss, schists, and quartzite), while intact garnet crystals can be often found in alluvial deposits originating from these rocks [35]. The geological variety of Sri Lanka also greatly contributed to the chemical diversity of almandine-pyrope garnets found on the jewellery. Deposits of pyropes in Bohemia are mainly found in alluvial plains south of the Bohemian massive, although the formation of minerals took place in garnet peridotites [36]; while in Portugal, garnets could be excavated from Palaeozoic gneisses, gabbro or peridotites in the vicinity of Lisbon, where pyropes can still be found [37]. The East African deposits are rich in many gemstones, including spessartines, pyropes and rhodolites; due to the high complexity of the rocks found in the eastern area, many of the deposits remain strongly active [38].
The archaeological site at Lajh in Kranj is one of the most important archaeological cemeteries in Slovenia ( Figure 1) dating back to the Late Antiquity (5th to 6th century AD). More than 700 graves have been excavated so far [39]; some of them are rich in metallic artefacts. These small finds are related mainly to the Romans and Germanic tribes of the Lombards and Eastern Goths [40,41]. Ornamented metal jewellery found in the cemetery is especially characteristic of Germanic females. Among other finds, variously fashioned gilded silver and bronze brooches were found, which were decorated with gemstones in the cloisonné technique or more rarely, with a coloured glass [39]. A special type of brooches from this site are S-shaped fibulae, which were mostly found among Romans, Lombardic and other Germanic tribes between the 5th to 7th century AD [42,43].  [46] using various analytical techniques (XRF spectroscopy, Raman spectroscopy, PIXE/PIGE). On the studied artefacts, Type I almandines dominated, with several examples of Type II almandines and a few rhodolites (Type III). One of three garnet types appears either alone or as a combination of two types on an individual piece of jewellery. All three types of garnets are rarely found together [40]. The investigated garnets of Type I and II correspond to Indian deposits, while Type III rhodolites correspond to the deposits of Sri Lanka, as recognised in previous works [2][3][4][5][6][7][8]. Whether the different types of garnets were used intentionally on jewellery is still unknown [45].
The aim of this study was to investigate garnets of Late Antique jewellery (mid-6 th century AD) from Slovenian archaeological site Lajh (Kranj) by means of Raman microspectroscopy in order to determine the type of garnets and inclusions present, as well as to discuss their potential provenance. The data were supported by X-ray fluorescence (XRF) spectroscopy.

Artefacts
A total of 19 garnets from six S-fibulae were analysed in this study, as shown in Figure 2. Fibulae were excavated in 2007 during the archaeological excavation of the Lajh cemetery in Kranj (Slovenia). Fibulae are dated to the mid-6th century AD, according to their specific type Schwechat-Pallersdorf (NA246, NA247, NA843, NA806) [42]. Milavec (2007) [42] described fibulae similar to NA892 as Schwechat-Pallersdorf type alike, which is supposedly a South German derivate of this type. The type of S-fibulae NA401 has not yet been determined. Garnets of the fibulae were polished to approximately 3-mm-thick inlays and attached in metal cell work in the cloisonné technique. Apart from the fibulae NA806 with five, all other fibulae were inlaid with three garnets (on fibula NA892 one of the three garnets is missing). Each garnet was numbered and abbreviated with the letter G (e.g., NA246 G1).

Study of Garnets.
The Raman spectra of the garnets were obtained using a LabRAM HR800 spectrometer equipped with a high-stability BX 40 optical microscope (Horiba JobinYvon, Villeneuve d'Ascq, France). The Raman spectrometer had a grating with 600 grooves per mm and an air-cooled CCD detector. Measurements were performed in the LabSpec acquisition software program (software version 5.25.15, Horiba JobinYvon, Villeneuve d'Ascq, France) using a 785 nm laser excitation line with an output power of 31.4 mW and an Olympus LMPLFL N 50x/0.50 objective, at a spectral resolution of about 1 cm −1 . On each garnet, at least three measuring points were selected, with the acquisition time of 60 s. Spectra were acquired in the range of 80-2000 cm 1 . All spectra were also analysed in LabSpec 5 Raman spectroscopic data processing software. Baseline corrections or normalisation of spectra were not undertaken. The classical method of multivariate statistics (hierarchical cluster analysis) was applied for checking and evaluating the variability in Raman spectra of studied garnets. Cluster analysis is a typical method that aims to identify similarity patterns (clusters) in a data set. The similarity was detected and demonstrated between the features (bands yielded and shifting of bands in Raman spectra) that characterize the garnets. In general, cluster analysis follows several steps: calculation of the similarity distances; in the present study, the squared Euclidean distances were chosen as similarity measure; linking of the objects to clusters using the Ward's linking method; and graphical representation of the clustering by a hierarchical tree diagram. All statistical calculations were performed with the software package STATISTICA (software version 13.3, TIBCO Software Inc., Munich, Germany). The data used for the cluster analysis are averages of three measurements of Raman mode frequencies for each garnet in the fibulae.
Garnets from the S-fibulae were analysed with the handheld energy dispersive X-ray fluorescence spectroscopy (ED-XRF) Niton instrument GOLDD XL3t 900S-He (0.1 mA; 50 kV) (ThermoFisher Scientific, Billerica, MA, USA) with a 3 mm X-ray spot to determine their chemical composition. The analyses were performed using the Cu/Zn Mining mode with continuous helium purge for better detection of light elements (Mg, Si, Al, S and P), which are included in the manufacturer's software. The reference materials SiO2, NIST-88b and NIST-1d were used at the beginning and end of the measurements to calibrate light elements. The pre-calibration with 25 international standards was performed with the same specifications and preferences as the measurements. Calibration curves were generated for all elements of interest (Si, Al, Fe, Mg, Ca, Mn). Two measurements were made on each garnet of the fibulae, with an acquisition time of 210 s for each measurement. The element assignments were defined using the NITON Data Transfer (version NDT_REL_8.0.1 software, Thermo NITON Analyser LLC, Billerica, MA, USA). The peak intensities for the ED-XRF spectra were given as Counts per Second (cps).

Study of Inclusions
Inclusions in garnets were determined by optical microscopy and Raman microspectroscopy. The microscopic examination of the inclusions in garnets was performed with the Olympus BX-60 optical microscope (Olympus, Tokyo, Japan). One garnet (NA401 G3) was no longer attached to the metal of the fibula that enabled to observe the inclusions in transmitted light. The rest of the garnets were observed in reflected light at both parallel and crossed polars. The microphotographs of inclusions were taken with the Olympus SC50 camera and Olympus Stream software.
The Raman spectra of inclusions were obtained with the same Raman microspectrometer and software settings as for garnet analysis, except for adjusting the acquisition time, which varied between 10 and 60 s. The Raman spectra of inclusions were often masked by a strong signal of garnet, except for the minerals with a strong Raman scattering (e.g., rutile, quartz).

Garnets
Frequencies of bands in Raman spectra and assigned Raman vibration modes are contained in Table 3. Table 3. Raman bands (cm −1 ) for the investigated garnets, assigned to site motion and mode of vibration.

Assignment (mode)
Site motion [22] Band The Raman spectra of investigated garnets agree well with Raman spectra of pyralspites and the dominant end member almandine [20][21][22]26], and can be grouped into three distinct energy regions: low frequency regions between (169374 cm −1 ); medium energy bands (479-637 cm −1 ); and high energy peaks (862-1046 cm −1 ) (Figure 3). Among the expected 25 Raman active modes (3A1g + 8Eg + 14T2g) of garnet group minerals [20], a total of 15 vibration modes were observed in the Raman spectra obtained that could be grouped into four main regions [22]. The two Raman bands at the range 120-280 cm −1 are assigned to translation modes, i.e., to the translation motion of Fe 2+ (band I) [47] and translation motions of SiO4 (band II) [22,48]. At the range of 280-450 cm −1 , four Raman bands were observed (bands IIIVI) dominated by rotation motions of SiO4 [22]. Six Raman bands (bands VIIXII) were located in the range 450-750 cm −1 assigned to Si-O bending (symmetric ν2 or asymmetric ν4), while three Raman bands (bands XIIIXV) yielded at the range 950 to 1100 cm −1 and were assigned to stretching motions of the Si-O band, either symmetric (ν1) or asymmetric stretch (ν3).
As furthermore seen from Figure 4, multivariate analysis based on Raman mode frequencies showed that the 19 garnets are clustered into three major distinct groups. This reflects the results of X-ray fluorescence spectroscopy, where in relation to major chemical element contents, three groups of the garnets were recognized ( Figure 5). According to ED-XRF spectra, all garnets consisted of Fe, Si and Al, confirming almandine composition of the pyralspite solid solution serie. Magnesium, indicating the presence of pyrope component, was also detected, followed by minor Ca (grossular component) and Mn (spessartine component) contents. However, some differences in Fe, Mg, Mn and Ca contents were observed for the garnets, which affect the shifting of Raman bands towards higher or lower frequencies. Hence, group II includes seven garnets (NA247 G1-G3, NA401 G2, NA806 G3, NA843 G2 and NA892 G1) and is characterised with the highest Fe contents, whereas Mg, Ca and Mn contents are the lowest among the studied garnets. The lowest values of most of the Raman mode frequencies were observed for this group. On the other hand, group III consisted of three garnets (NA843 G3, NA806 G2 and G5) and is characterised with the highest Mg content as well as Ca and Mn contents and shifting of certain vibrational modes to higher frequencies (e.g., SiO stretching ν3, SiO bending ν2 and ν4, and rotation of SiO4 modes). However, the majority of analysed garnets belong to Group I, which contains nine garnets (NA246 G1-G3, NA401 G1 and G2, NA806 G1 and G4, NA843 G1 and NA892 G2) and is the middle range between Groups II and III.  The comparison of Raman spectra of representative members of each group is shown in Figure  6, in which NA247 G3 is assigned to Group I, NA246 G2 to Group II and NA806 G2 to Group III. The majority of mode frequencies decrease linearly with the almandine contents (i.e., decrease with ionic radii Mg 2+ (0.89) > Fe 2 (0.92) Å) in all four regions of the Raman spectra. As seen from the Figure  6, this is observed as shifting of certain Raman bands to the left for garnets of group III to group II. Namely, most Raman bands of the pyralspite group can show strong overlap, especially in the range of SiO bending and rotation modes R(SiO4)). For spessartine, shifts to lower frequencies of SiO stretching mode bands at 905-915 cm −1 and 1030-1035 cm −1 are indicative, due to the presence of a slightly larger Mn 2+ ion in the octahedral coordination, with respect to the Fe 2+ ions in almandine [11,20]. On the contrary, in pyrope, the presence of smaller Mg 2+ cation in octahedral coordination [18] affects the shifts of several vibrational modes to higher frequencies, especially ~363 cm −1 , ~510 cm −1 , ~640 cm −1 and ~1055 cm −1 [20,43]. In addition, Raman bands at ~170 cm −1 (band I) and ~330 cm −1 (band VI) showed a tendency to diminish towards pyrope composition as also recognised by Pinet and Smith (1994) [22]. Anyway, some bands, for instance, Raman band at 214 cm −1 (band II) assigned to the translational mode of the SiO4 tetrahedron, showed the opposite trend with increasing the mode frequencies with almandine contents. An inverse correlation with ionic radii Mg 2+ (0.89) < Fe 2+ (0.92) < Mn 2+ (0.96) Å for this frequency mode was reported also by other authors [22,26]. Figure 7 shows trends in the selected frequency distribution from the four ranges of the Raman spectra assigned to the translation mode of the X 2+ cation (band I), rotation of the SiO4 tetrahedron (band V) and vibration modes of Si-O bending (ν4-band XII) and SiO stretching (ν3-band XV). Raman shifts of vibration modes were attributed to the changes in the end member composition, which was confirmed by XRF spectroscopy (Figure 5). The lowest observed frequency modes in the ranges of 169-170 cm −1 , 346-347 cm −1 and 633-634 cm −1 are the result of higher Fe contents for the garnets of the Group II. On the other hand, the increase of Mg content affected the shifts of the Raman bands in the ranges of 171-173 cm −1 , 350-352 cm −1 and 635-637 cm −1 to higher frequencies in three investigated garnets of Group III (NA806 G2 and G5, NA843 G3), respectively (Figure 7a-c). The proposed trend could not be observed completely in the distribution of frequencies 1041-1045 cm −1 (Figure 7d) assigned to Si-O stretching (ν3). With the exception of NA247 G2, the frequencies for the garnets of group II were shifted to lower values, whereas for the garnet of group III, NA806 G2, the band for this mode was shifted to higher frequencies, which corresponds to increased Mg content within the group. Rather low frequency was observed for the garnets NA806 G5 and NA892 G1, which could be explained with slightly lower values of Mg and enhanced contents of Mn compared to garnet NA806 G2 within group III.

Inclusions
As observed by optical microscopy, garnets from S-fibulae contained several inclusions that were additionally examined by Raman microspectroscopy. Most of the studied garnets contained apatite, quartz and minerals with radiation and pleochroic halo (e.g., zircon). Some also contained mica (muscovite, phlogopite) and opaque minerals (ilmenite). Rutile was observed only in two garnets, while sillimanite fibres only appeared in one garnet. In two of the garnets, unidentified spherical inclusions were observed, which could be fluid or gas inclusions. The inclusions determined in garnets are listed in Table 4. Figures 8-16 show characteristic microphotographs of mineral inclusions and their associated Raman spectra. Table 4. Observed inclusions in garnets from S-fibulae, regarding a type of inclusion, their mineralogy and affiliation to certain garnets. Apatite was determined in garnets from fibulae labelled NA246, NA247, NA401, NA806 (G1 and G4) and NA892 (G1). As shown in Figure 8b, strong characteristic Raman bands of apatite yielded at 272 cm −1 , 432 cm −1 , 592 cm −1 , 965 cm −1 and 1083 cm −1 [49]. Apatite mainly occurred as elongated xenomorphic crystals, from 50 to 300 μm in size (Figure 8a). However, in garnet G3 from fibula NA401, it occurred as idiomorphic crystals in a size of approximately 300 μm. Garnet G3 from fibula NA401 also contained several xenomorphic grains of quartz in a size of up to 20 μm (Figure 9a). Characteristic Raman bands at 128, 208 and 465 cm −1 confirmed the presence of -quartz, however, some spectra also yielded minor bands at 394 cm −1 [50] (Figure 9b). Quartz inclusions were also identified in other garnets (NA806 G2, G4 and G5). Opaque grains mostly occurred in groups as tiny elongated crystals (20-50 μm) (Figure 10a). These inclusions were identified in fibulae NA247 (G1 and G2) and NA401 G2. Raman bands indicating the presence of iron oxide minerals were observed in several spectra, e.g., in Figure 10b, where besides quartz (black asterisk), a broad band at ~680 cm −1 is also visible (red asterisk), which could be assigned to ilmenite [50][51][52]. Namely, ilmenite flakes with quartz inclusions are commonly found in garnets [31]. Anhedral rounded inclusions with pleochroic (brownish) or radiation halo and inclusions damaged with tension fissures are common in most of the investigated garnets (Figure 12a-d). Their size varies from 20-200 μm. They occurred in fibulae NA246 (G2), NA247 (G2), NA401 (G2), NA806 (G2, G3 and G5) and NA843 (G2). Inclusions with tension fissures are minerals, in which a deformation of the crystal lattice occurs due to changes in the environmental conditions (pressure, temperature) during the growth of the host crystal or in subsequent processes, that influence changes in the structure of the host crystal [53]. Pleochroic or radiation halos are the result of radiation damage within the host crystal structure, caused by the process known as metamictization [18]. This process is characteristic for crystals containing radioactive elements in their crystal structure and can result in radiation damage and crystalline structure changes to an amorphous state, while the outer crystal shape is retained [18]. Such minerals are zircon, monazite, xenotime or apatite, which accommodate thorium or uranium into the crystal structure [54]. Raman spectra of some deformed inclusions showed strong luminescence, which masked most bands ( Figure 13). A weak Raman band at ~1014-1017 cm −1 and a stronger band at ~1398 cm −1 , often accompanied by a broad band at 1280 cm −1 , can be indicative of zircon. Namely, as suggested by some authors (i.e., Kloprogge (2017) [18], Nasdala et al. (2002Nasdala et al. ( , 2018 [55,56]), the crystal structure of zircon inclusion may be damaged due to metamictization or pressurization in their hosting minerals resulting in decreasing of intensity and broadening of the strong Raman band characteristic of zircon at ~1008 cm −1 . Moreover, an increase in temperature and pressure will cause a shift and lower the intensity of the Raman band to 1014-1022 cm −1 [57]. However, luminescence and presence of strong Raman bands in the range of 1200-1400 cm −1 are related to amorphous SiO2, which appears due to changes in inclusions after heath treatment [57]. Raman spectra of particular xenomorphic transparent crystals of 20 to 200 um in size that corresponded to mica were observed in several garnets (NA401 G3, NA806 G2, G4 and G5 ( Figure  14). Namely, two types of phyllosilicates were recognised. Raman bands at ~100 and ~700 cm −1 are indicative of muscovite type (Figure 14b, below), whereas at ~670-680 cm −1 of phlogopite type ( Figure  14b, above) [58]. According to Schönig et al. (2018) [59], bands determined at 190-200 cm −1 can be present for both types of mica, however, a strong band of ~270 cm −1 is characteristic only in muscovite-paragonite type. Among the investigated garnets, only in garnet G5 of fibula NA806 fibre-like inclusions were present, which might be attributed to sillimanite (Figure 15a). Similar curved fibres of sillimanite were also determined in almandines by Calligaro et al. (2002) [4], Schmetzer et al. (2014) [31] and Horváth and Bendó (2011) [32]. Due to strong luminescence, only a Raman band at 235 cm −1 (black asterisk) is present besides common almandine bands (171 cm −1 , 312 cm −1 , 349 cm −1 , 558 cm −1 and 918 cm −1 ) (Figure 15b). For sillimanite, bands at ~235 cm −1 , 310 cm −1 , 456 cm −1 , 870 cm −1 and 965 cm −1 are characteristic [50,60]. Raman bands at 235 and 312 cm −1 (for analysed almandine garnets, this band is observed at slightly higher values 315-317 cm −1 ) could indicate the presence of sillimanite. Furthermore, brown plate-like inclusions that occurred in garnets (NA246 G2, NA843 G3, NA892 G2) could indicate the presence of biotite (Figure 16a), whereas according to Horváth and Bendó (2011) [32], similar inclusions were attributed to the phosphate mineral xenotime.

Type of Inclusion Mineralogy and Chemical Formula Artefact and Garnet
In addition, garnet G1 of fibula NA843 and garnet G2 of fibula NA892 showed the presence of transparent spherical grains, 100-400 μm in size, which most probably represent fluid or gas inclusions (Figure 16b).

Discussion
The Raman spectra of garnets obtained in this study all show similar Raman bands indicating almandine as the dominant end member in solid solution. However, shifts of the Raman bands to higher frequencies, e.g., modes assigned to the translation mode of X 2+ , the rotation mode of SiO4 tetrahedron and the Si-O stretching mode, indicate the presence of higher pyrope content in the solid solution for the three garnets. The correlation between the composition of the natural garnets and changes in Raman vibrations was determined in the study of Henderson (2009) [11,22,26]. In the case of almandine garnets, Henderson (2009) [11] observed shifts to higher frequencies (the Si-O bending (ν3) at 10441047 cm −1 , the stretching (ν4) 636641 cm -1 and the rotation (R(SiO4)) modes at 350357 cm −1 ) with an increase in the pyrope content, although when spessartine content increased in composition, this end member interfered with the linear trend of the increase in all mode frequencies.
Similarly, Kuang et al. (2019) [26] observed a linear increase in the frequencies of Si-O stretching and bending, the rotation mode of the tetrahedron (R(SiO4)) and the translation of the X 2+ mode (T(X 2+ )) with increasing pyrope content and vice versa for the translation of the tetrahedron (T(SiO4)) when studying synthetic pyrope-almandine garnets, which is consistent to a certain extent (considering the vibration modes) with our results.
According to the observed trends in Raman shifts of vibrational modes in the obtained Raman spectra, the presence of three groups of almandines on the examined S-fibulae was determined, each of which differs in its pyrope content, while spessartine and grossular components were also present in minor amounts. According to similar Fe, Mg, Ca and Mn contents, we classified 16 garnets from the S-fibulae from Groups I and II as Type I almandines (almandines poor in Mg, Ca, Mn), which showed a shifting of the Raman bands to lower frequencies compared to the three garnets of Group III. Garnets from this group were classified as Type II (almandines rich in Mg, Mn) and characterised with shifting of the Raman bands of certain vibration modes (i.e., T(X 2+) , Si-O stretching and R(SiO4)) to higher frequencies due to increased Mg contents. In comparison to the study of several Slovenian brooches by Šmit et al. (2014) [45], Type I almandine also predominates in S-fibulae and can be combined with Type II almandines, which are also present in minor numbers. Almandines Type II may point to older artefacts of the mid-5 th to 6 th century AD, according to Šmit et al. (2014) [45]. Concerning the geographical provenance, as Bimson et al. (1982) [6] first suggested almandines, both of Type I and II, originate from Indian deposits, most likely from Rajasthan or NW India.
In addition, several solid inclusions in garnets from Late Antique jewellery have been observed in works by Calligaro et al. (2002) [4], Horváth and Bendó (2011) [32], which have been systematically classified as Type I and Type II almandine. Apatite, quartz, Fe-oxide minerals, mica and deformed crystals with pleochroic halos, radiation halos or tension fissures can be observed in both garnet types of the examined S-fibulae. In the present study, sillimanite and rutile needles were found only in Type II almandine, which was also reported by Horváth and Bendó (2011) [32] as being more common for Type II almandines As far as geological formation is concerned, observed mineral inclusions-apatite, quartz, mica and zircon are common in almandines and can form in different geological environments. They are more common in felsic lithologies, although they also occur in mafic rocks [59]. Sillimanite and rutile are considered important for geological provenance studies as they indicate a smaller range of metamorphic facies [59]. Both are usually associated with medium-to high-grade metamorphism in which rutile is an abundant accessory mineral. According to Force (1980) [61] and Zack et al. (2004) [62], the increasing pressure of the upper amphibolite facies favours rutile formation, but when subjected to low-grade formation, it breaks down to form other titanium bearing phases. Sillimanite is restricted to the medium pressure part of the amphibolite facies and is mostly restricted to granulite facies [63]. Spherical inclusions observed in two garnets of the S-fibulae may indicate the presence of either gas or melt residue. Melt droplets may be entrapped at any phase of garnet recrystallization, especially under rapid heating conditions and disequilibrium melting [64,65]. According to Ferrero et al. (2018) [27], garnet is the most common host for melt inclusions because it is the most widespread peritectic phase resulting from incongruent melting in the continental crust. Since garnets were processed into thin inlays to fit the cloisonné technique of jewellery, some of the inclusions were probably excluded from the host mineral, leaving an inclusion arrangement in the garnets studied incomplete.
As described in the introduction, metamorphic rocks are spatially distributed in the region of NW Indian (Rajasthan), from amphibolite facies of medium-grade metamorphism in the west to granulite facies of high-grade metamorphism in the east, which support the theory of the geological formation of inclusion assemblage in garnets and their probable deposition in the Rajasthan area [33]. Similar rock formations can also be found in parts of East India (Garibpet deposit), where according to Schmetzer et al. (2017) [31], garnets were also excavated in Late Antique times and traded to the west. However, these almandine garnets, which the author has examined, were mainly used and traded as beads.

Conclusions
The studied garnets from the S-fibulae of the Slovenian archaeological site Lajh-Kranj (mid-6th century AD) were identified as almandines, determined as Type I and Type II, according to their Raman spectra, chemical characteristics and inclusion assemblage.
Specific mineral inclusion assemblage, with emphasis on rutile and sillimanite, imply the origin of garnets in metamorphic rocks of amphibolite or granulite facies. Almandine garnets from the studied S-fibulae are consistent with other studied garnets of Late Antique artefacts found in Slovenia and also in a wider European area of 6th century AD and originating from Indian deposits.