RUSSIAN JOURNAL OF EARTH SCIENCES, VOL. 3, NO. 1, PAGES 1-32, MARCH 2001
Kola alkaline province in the Paleozoic: evaluation of primary mantle magma composition and magma generation conditions
A. A. Arzamastsev1, F. Bea2, V. N. Glaznev1, L. V. Arzamastseva1, and P. Montero2
1 Geological Institute, Kola Research Center, Russian Academy of Sciences, Apatity, Murmansk Oblast 2University of Granada, Dept, of Mineralogy and Petrology, Fuentenueva s/n, 18002, Granada, Spain
Abstract. This paper is an attempt to estimate quantitatively the chemical composition and volume of magma, the reactivation of which resulted in the formation during the Paleozoic of the northeastern part of the Baltic Shield in the Kola alkaline province. In contrast to the known models, a gravity-based method of 3-D density modelling was used to evaluate the extent of alkaline magmatism in the province and, accordingly, to estimate the volume of mantle magma produced during the Paleozoic cycle of activity. During the early-period of study, along with sample collection and geochemical analyzes, the deep structure of the province was investigated, and 3-D density models were derived for all alkaline intrusions of the province to a depth of 22.5 km. The next step included the high-precision determinations of trace element concentrations in the rocks using an ICP-MS method as a basis for calculating the weighted mean concentrations of these elements in the rocks of the province, deriving models for mantle rock melting, and estimating the geodynamic consequences of these mantle processes. The calculations showed that the total volume of the Paleozoic magma produced in the NE part of Fennoscandia had been 15000±2700 sq. km. The calculated composition of the magma that might have been melted from the mantle of an intermediate composition revealed that a significant amount of incoherent elements must have been added to the primary mantle material. It is shown with a high degree of certainty that the primitive magma was produced in the Kola Province because of the low melting degree of the substrate (0.3-0.5%) whose composition answered to a phlogopite (± amphibole) bearing garnet lherzolite residing at a depth of a garnet mantle. The enrichment degree of this substrate was calculated to have been 3 times higher than the mean contents of incompatible elements in the primitive mantle. It is shown that the process of magma generation involved a significant portion of the NE Fennoscandian lithosphere ca. 400 km across and 120 km in depth, that is, covered the entire depth of the mantle garnet lherzolite. This areal estimate agrees with the area of Paleozoic igneous rocks in the region. The estimated depth correlates with the PT conditions of the mantle xenoliths found in the dikes and breccia pipes of the region.
Copyright 2001 by the Russian Journal of Earth Sciences.
Paper number TJE01054.
CCC: 0000-0000/2001/0301-00054$ 18.00
The online version of this paper was published July 31, 2001. URL: http://rjes.agu.org/v03/TJE01054/TJE01054.htm Print companion will be issued.
1. Introduction
The research work done in the last decade furnished new proofs that the main factor responsible for continental magmatism in areas of ancient shields and their frames had been the reactivation of the upper mantle as result of a plume-lithosphere interaction and/or rifting [Baker et al., 1997;
Figure 1. Location map for the distribution of the products of Paleozoic magmatism in the NE Baltic Shield. Intrusions: 1) Khibiny, 2) Lovozero, 3) Niva, 4) Kovdor, 5) Sokli, 6) Vuoriyarvi, 7) Sallanlatva, 8) Kandaguba, 9) Mavraguba, 10) Afrikanda, 11) Ozernaya Varaka, 12) Lesnaya Varaka, 13) Salmagora, 14) Ingozero, 15) Turii Mys, 16) Pesochnyi, 17) Kontozero, 18) Ivanovka, 19) Sebl’yavr, 20) Kurga; 21) Terskii coast dikes and diatremes.
Bell and Simonetti, 1996; Kerr et al, 1995, 1996; Thompson and Gibson, 1991, 1994; Toyoda et al., 1994; White and McKenzie, 1989, 1995]. The results of deep seismic sounding combined with high-accuracy isotopic geochemical studies of mantle magmatic rocks and hypoxenoliths provided a basis for deriving models of magma generation in the mantle [Keen et al., 1994; McKenzie and O’Nions, 1991; Ryabchikov, 1998; White and McKenzie, 1995; William,son et al., 1995]. Based on the latest experimental data, these models are good enough to determine the behavior of chemical elements for the partial melting of mantle rocks and to estimate the compositions and, in some cases, the volumes of the melting products [McKenzie and Bickle, 1988; Niu, 1997; Walter, 1998; Winter, 1995]. At the same time these approaches are liable for random assumptions because of the uncertainty of some data for magma generation in the mantle. This circumstance calls for deriving models based on alternative approaches to determining the volumes and compositions of mantle magmas.
This paper is an attempt to estimate the chemical composition and volume of the mantle, the melting of which resulted in the formation in Paleozoic time of the NE portion of the Baltic Shield in the Kola alkaline province and to evaluate the composition of the source melts. In contrast to the models mentioned above, we used a method of 3-D
density modeling based on geophysical data [Glaznev et al., 1996].
The aims of this study were:
- to evaluate the volumes of the Paleozoic alkaline magmas in the region, including the calculation of the volumes of different types of rocks in the study area. The main results of this work, based on the study of the crust and mantle structure in the region and on the calculation of 3-D density models for all alkaline rock intrusions to a depth of 22.5 km, were reported earlier [Arzamastsev et al., 1998a; Arzamast-sev et al., 2000a];
- to collect samples of plutonic, dike, and volcanic rocks for a geochemical study and perform high-precision determinations of trace elements concentrations using an ICP-MS method in the laboratory of the University of Granada following the procedure described in [Bea, 1996];
- to calculate the weighted average concentrations of trace elements in the rocks of the province, use the results to calculate the mean compositions of the source magmas, and compare the resulting compositions with the least differentiated rocks of the province;
- to carry out a petrologo-geochemical modeling including the calculation of the probable concentrations of trace elements in the source mantle melts (based on experimental data reported in literature), compare them with the calcu-
lated contents in the source Paleozoic magmas of the Kola Province, and calculate the potential volumes of the zone of Paleozoic magma generation for the given degrees of mantle rock melting.
2. Geology of the Kola Paleozoic Igneous Province in Terms of the Model Applicability
The Kola Province occupies the northeastern region of the Baltic Shield and is made up of the world largest plutons of agpaite syenites and numerous intrusions of alkalic ultra-basic rocks with carbonatites (Figure 1). Volcanic rocks of Paleozoic age are scarce, are significantly reduced, and occur mainly as remnants in the collapse calderas of the Kontozero, Lovozero, Khibiny, and Ivanovka massifs [Arzamastsev et al., 1998b]. The widespread dike swarms and diatremes originated at the same time with the intrusion of plutons. The Kola alkalic intrusions rank among the well known geological objects; they were described by many investigators [Bussen and Sakharov, 1972; Galakhov, 1975; Gerasimovskii et al., 1966; Kukharenko et al., 1965, 1971]. For this reason we prefer to dwell on some principal features which define the applicability of a model for calculating the composition of mantle rocks for this region.
1. The province of study includes almost all products of the Paleozoic igneous activity including intrusions, dike swarms, and diatremes. The present-day level of the geological and geophysical knowledge of the Kola region [Mitrofanov et al., 1995] and of the adjacent areas of the Barents and White seas [Grachev, 2000a] suggests the minimum probability of discovering any new occurrences of Paleozoic igneous activity. This supposition is proved by the latest findings of alkaline rocks on the Barents Sea coast (Ivanovka Massif) [Rusanov et al., 1993], in the area of Lake Imandra (Niva intrusion) [Arzamastsev et al., 2000b], and in the Kandalaksha area (Kandaguba Massif) [Pilipyuk et al., 1998], whose contribution to the total volume of alkaline rocks in the province is not higher than 1%.
2. The level of the geological knowledge is high enough to reconstruct with a high degree of detail the internal structure of virtually all alkaline intrusions. Because most of the massifs were known to contain rare-metal ores, the area of all intrusions was covered by a large-scale geological survey, and the massifs were drilled to depths of 200-2000 m.
3. All products of Paleozoic igneous activity were em-placed during a relatively short time interval of 380-360 million years [Kramm et al., 1993]. This suggests that they originated during one strictly limited period of tectonomagmatic reactivation. This period was preceded by a long amagmatic period of the Baltic shield history, which lasted more than
1.3 billion years. No magmatic post-devonian events have been registered in the NE part of Fennoscandia.
4. The isotopic and geochemical characteristics of the Paleozoic plutonic and subvolcanic rocks of the province suggest the minimum contribution of crustal material in the origin of the alkaline rocks [Beard et al., 1998; Kramm and
Kogarko, 1994; Zaitsev and Bell, 1995] and in the origin of their parental magmas as a result of the direct melting of the old mantle material depleted in the course of the Archean and Proterozoic crust formation [Arzamastsev et al., 1998b].
The above features place the Kola Province into the number of the most promising regions where the reconstruction of the initial composition of the mantle is permissible.
3. Calculation of the Volumes of Paleozoic Magmatism in the Baltic Shield
We calculated the volumes of the alkaline ultrabasic intrusions using the results of our 3-D density modelling based on geophysical data, which enabled us to determine the geological structure of the intrusions to a depth of 22 km. The essence of the regional density modelling of the Earth’s crust under the Baltic shield and the technique of the 3-D density modelling of alkaline intrusions were discussed earlier [Arzamastsev et al., 2000a; The Structure of the Baltic Shield Lithosphere, 1993]. The interpretation of gravity data aimed at determining the structure of the central-type massifs consisted of two stages: first to calculate a regional density model for the crust and the gravity field it produced, and second to interpret the local gravity anomalies produced by density inhomogeneities in the upper crust.
Our calculation of a detailed density model for the upper crust was based on the method and calculation technique offered by V. N. Strakhov [Strakhov, 1990, 1999] for solving a general inverse linear problem. In our practical use of this method we introduced some additions to improve the convergence of the iteration solution of our 3-D inverse problem. To pick out local high-gradient anomalies, we used our own version of dispersion filtering, close in its sense to the known methods of adaptive filtering [Nikitin, 1979]. The spacing of our grid for calculating a 3-D density model was 2x2 km in plan, and the vertical interval was specified using a discrete series of the grid nodes: 0, 1.0, 2.0, 3.5, 5.0, 7.0, 9.0,
11.0, and 14.0 km. The accuracy of solving the inverse gravity problem was chosen to be ±0.25 mgal. This accuracy was sufficient for the accuracy of the density solution to be ±10 kg/m3. This algorithm of the calculation and visualization of the results was used to write computer programs to have the results of modelling in a graphic form.
In our calculation of volumes we included all known occurrences of alkaline-ultrabasic and carbonatite magmatism (Kovdor, Turii Mys, Afrikanda, Sebl’yavr, Vuoriyarvi, and other intrusions), the huge alkaline rock complexes of Khibiny and Lovozero, and also volcanic rocks from the Kontozero caldera. In view of the fact that the volume of the Paleozoic alkaline dikes was hard to calculate, we assumed, using the swarms of alkaline lamprophyre dikes, known from the Kandalaksha River shore and from the Neblo Mt. area, their volume to be 10% of the total volume of the alkaline-ultrabasic intrusions. It is obvious that the error of determining the dike volume may be as high as 50% or even higher.
Figure 2. Schematic maps showing the geologic structure of the Kola carbonatite massifs, modified after Ternovoi [1977] and Kogarko et al. [1995]: (1) phoscorite, (2) carbonatite, (3) nepheline syenite, (4) ijolite, (5) melteigite, (6) melilite rocks, (7) melilite-monticellite-olivine rocks, (8) phlogopite-diopside-olivine rocks, (9) pyroxenite, (10) peridotite and dunite. The A-B lines show the orientations of the density sections given in Figure 3.
3.1. Intrusions of Alkaline-Ultramafic Rocks and Carbonatites
The results of our density modeling suggest substantial differences in the deep structure of the carbonatite intrusions (Figure 2). The objects of our study included subvertical bodies of a cylindrical form (Sebl’yavr, Kovdor), intrusions with a near-surface magma chamber and a lateral feeding channel (Lesnaya Varaka, Afrikanda), lopolithlike intrusions (Salmagora, Turii Mys), and bodies that were actually the apical parts of large alkaline ultramafic intrusions (Sokli) (Figure 3). The results of our density modeling revealed that most of the intrusions had narrow necks in the zones of high-density rocks, which can be interpreted as transition zones between the magma chambers and the feeding channels. Considering the above mentioned limitations of the method in terms of the accuracy of solving an inverse gravity problem, the estimates of the lower limits of the chambers
may vary as much as 15-20%, the general pattern remaining valid.
All alkaline-ultramafic intrusions were found to have a multiphase structure which reflects the successive intrusion of an alkaline ultramafics-foidolite-carbonatite series. It was believed earlier [Epshtein and Kaban’kov, 1984; Epshtein et al, 1972; Frolov, 1972; Kukharenko et al., 1965; Landa, 1976; Samoilov, 1977] that most of carbonatite intrusions had a zonal structure with carbonatite dominating in the top of the magma column, underlain by foidolite which is replaced at a deeper level by a zone of ultramafic rocks. Accordingly, the poorly eroded massif must show carbonatites, and the highly eroded ones, the rocks of the alkaline-ultramafic series. The results of our modeling confirmed this observation: the established relationship between the modern forms of the bodies and the depths to the bottoms of the magma chambers suggests that initially most of the Kola carbonatite intrusions had the form of a lenticular symmetrical stock with a distinct transition from the magma chamber to the feeding
Figure 3. Density distribution in the Kola carbonatite massifs. See Figure 2 for the orientations of the section lines.
channel, the diameters of the latter being 1/5 to 1/3 of the maximum sizes of the intrusions [Arzamastsev et al, 2000a]. The apical part of this hypothetical intrusion seems to be represented in the Sokli Massif, where the carbonat.it.es are associated with a large swarm of alkaline lampropliyre dikes, the fact, typical of the poorly eroded intrusions. We used the Sebl’yavr and Kovdor intrusions, which preserved the large parts of their magma reservoirs, to reconstruct, their sizes. We found that, a ratio between the initial heights of the chambers and their diameters must, have been 2:1, and the vertical lengths of the reservoirs, 15 20 km (Figure 3).
Using the data available on the deep structure of the intrusions, we calculated, for each of them, the volumes of their near-surface magma chambers, of their eroded parts, and of their feeding channels connecting the zone of magma generation and the shallow magma reservoir. The results
of our calculations are presented in Table 1. We assumed that, there had been no intermediate magma chambers in the crust, or upper mantle. The circumstantial evidence of this is provided by isot.opic data [Arzamastsev et al, 1998b: Kramm and Kogarko, 1994], suggesting an insignificant, role of crust.al contamination which would have been observed in the case of the long standing of mantle magma in crust.al chambers.
Proceeding from the fact. that. most, of the intrusions have a concentrically zoned structure, as follows from geological observations and from the results of our density modelling, a truncated cone was assumed as an acceptable approximation of their forms (Figure 4). We used the following parameters of the approximation form:
(1) the height, of the magma chamber estimated from the results of the density modeling as a distance from the surface
Table 1. Calculated volumes of alkaline-ultramafic intrusions of the Kola Province
Massif Surface Chamber Chamber Chamber Feeder Feeder Feeder Erosion Erosion
area, radius base radius height volumes, radius, length volume, height volume,
km3 Ri, km R2, km hi, km km3 km Ьз, km km3 li2, km km3
Kovdor 37.5 3.43 5.0 7.0 782.6 1.0 41 128.7 1.0 16.0
Lesnaya 13.1 2.04 1.0 4.5 33.6 0.2 51 31.7 10.5 59.6
Ozernaya 0.8 0.50 0.5 4.0 3.1 0.1 51 16.0 11.0 3.8
Afrikanda 5.0 1.26 1.0 4.0 16.0 0.2 51 32.0 11.0 23.8
Salmagora 38.0 3.48 2.0 6.5 155.3 0.4 49 60.9 8.5 139.9
Sokli 31.0 3.14 5.0 6.0 629.0 1.0 43 135.0 3.0 40.3
Turii Mys 43.0 3.70 3.0 4.5 157.6 0.6 51 95.1 10.5 195.6
Sebl’yavr 20.0 2.52 4.0 6.5 437.3 0.8 42 105.5 2.0 17.3
Vuoriyarvi 20.0 2.52 2.0 5.0 79.9 0.4 50 62.8 10.0 86.6
Sallanlatva 6.0 1.38 1.0 5.0 22.2 0.2 50 31.4 10.0 26.0
Kovdozero 1.6 0.71 0.5 5.0 5.8 0.1 50 15.7 10.0 6.9
Kandaguba 1.0 0.56 0.5 5.0 4.4 0.1 50 15.7 10.0 4.3
Ivanovka 5.0 1.26 1.0 5.0 20.0 0.2 50 31.4 10.0 21.7
Kurga 30.0 3.09 2.5 5.0 243.8 0.5 45 70.7 5.0 65.0
Iivara 18.0 2.39 3.0 4.5 204.4 0.6 46 86.7 6.0 46.8
Kontozero 65.0 4.55 4.5 3.0 126.0 0.9 53 149.8 13.0 366.6
Total
volume, km3 - - - - 2921±290 - - 1069±320 - 1120±340
Note. The total volume of intrusions including the volumes of their shallow chambers, feeders, and eroded portions amounts to 4040±950 km3.
erosion level to the depth level of the transition to the feeding channel (hi);
(2) the radius of the intrusion at the surface (Ri) found from the computed area of the massif. The latter and the outcrop areas of various rock types were computed from map data [Kukharenko et al., 1965, 1971];
(3) the radius of the magma chamber bottom (R2) at the level where it changes to a feeding channel estimated from the results of the density modelling. The maximum diameter of the chamber (R3) was calculated for intrusions of a lenticular form. In this case the volume was calculated as the sum of volumes of two truncated cones;
(4) Considering that the total volume of the magma chamber included its eroded portion, the volume of the latter was calculated using the radius of the intrusion near the surface (Ri), the radius of the apical portion taken as 0.25 Ri, and the height li2 estimated as a difference between the height of a hypothetical carbonatite intrusion (15 km) [Arzamastsev et al., 2000a] and the height of the magma chamber hi;
(5) The volumes of the feeding channels were calculated using a formula for cylindrical bodies having a diameter measuring 0.25 of the bottom diameter of the intrusion and a height (ha) equal to a distance from the bottom of the magma chamber to the zone of magma generation residing at a depth of ca. 55 km, as estimated in [Arzamastsev and Dalyren, 1993].
The volumes of the rocks making up the intrusions (dunite, pyroxenite, melilitholith, foidolite, and carbonatite) were estimated on the basis of their proportions at the eroded surface (Table 2) and of the results of the den-
sity modeling. For some intrusions (Sokli), the presence of silicate rocks in the uneroded portion of the massif was taken into account. It was assumed that the feeder was filled with the rock whose composition was similar to olivine melteigite porphyry. According to [Arzamastsev and Arzamastseva, 1990; Koehurova and Ivannikov, 1976; Kukharenko et al., 1971], the latter represents the average composition of the alkaline-ultramafic province.
With the adopted method of approximating the forms of the alkaline intrusions, the errors of calculating their volumes were 10-15% for the magma chambers and approximately 30% for the zone of the feeder and for the eroded portion. The calculated total volume of all carbonatite intrusions of the province, including the volumes of their shallow chambers, feeders, and eroded portions, amounted roughly to 4000±1000 km3.
3.2. Khibiny and Lovozero Massifs
The volumes of these massifs were calculated using the following geological evidence on their structure at the present-day erosion level (Figure 5) and the results of geophysical interpretation based on the 3-D density modeling [Arzamastsev et al., 1998a].
1. The southeastern, southern, and western contacts of the Lovozero Pluton are subvertical to a depth of 4 km in the zone of nepheline syenites and grow gentler beginning with the depths of 8-10 km (Figure 6). The northern and northwestern contacts are more gentle: the dips vary within
Figure 4. Examples of calculating the volumes of alkaline-ult.ramafic intrusions in the Kola Province from the results of density modeling shown for the Turii Mys and Sebl’yavr intrusions. The density values are given in kg/km3.
50 60° near the surface and within 30 40° at depths of 4 5 km. At greater depths the contact is subvertical to a depth of 9 10 km.
2. The Lovozero Plut.on consists of two zones of different densities at a depth greater than 2 km (Figure 6). The southwestern zone is made up of rocks with densities of 2660 2750 kg/m3, these values being typical of neplieline syenite. A local negative density anomaly was recorded in the central part of the plut.on in the Lake Sedyavr area. This anomaly marks a body of alkaline and analcime syenites with a density of 2580 2630 kg/m3. This region seems to host, a feeder for the neplieline syenite intrusion. The northeastern zone consists of rocks with a density higher than 2800 kg/m3. According to field geology and drilling data, the top of the zone is composed of the remnants of alkaline volcanic rocks of the Lovozero suite of Devonian age. and also of the alkaline-ult.ramafic rocks similar to those known from the Kliibiny Massif [Arzamastsev et al., 1998a].
3. The conic-circular structure of the Kliibiny Plut.on per-
sists within the depths accessible for observation, namely to a depth of 12.5 km. The eastern contact, in the region of a carbonat.it.e stock is subvert.ical to a depth of 3 4 km and tends to become suddenly gentler at. a depth of 4 5 km. The western and southern contacts dip inward at. an angle of 65 70° to a depth of 4 km. The position of the contact, is as gentle as 30° in a depth interval of 4 6 km and becomes as steep as 50 60° below a depth of 7 km.
4. The results of our study suggest, that, the alkaline-ult.ramafic rocks are more abundant, in the Kliibiny Plut.on than it. was believed earlier [Galakhov, 1975]. The results of our density modeling show that, boreholes reached merely the roof of a thick zone of alkaline ult.ramafics showing a positive density anomaly and extending along the entire northern sector of the massif (Figure 6). The holes drilled through the kliibinit.es intersected thick zones composed of peridot.it.e. py-roxenit.e, melilit.olit.e. and ult.rabasic foidolite xenolit.lis. The western sector of the plut.on. which according to Snyatkova et al. [1986] is marked by a combination of gravity and mag-
Table 2. Ratio of rocks in the Kola intrusions and their portions in the total volume of the products of alkaline-ultramafic magmatism
Dunite Pyroxenite Melilite rocks Melteigite Ijolite Melteigite Nepheline + ijolite syenite Carbonatite Nephelinite, melilitite
Rock index PRO PRX MML FOM FOI FO SFN CC NFM
Kovdor 9.0 12.0 3.5 — — 9.5 0.5 3.0 —
Lesnaya 10.0 2.0 - - - 1.0 - 0.1 -
Ozernaya - - - 0.8 - - - - -
Afrikanda 0.5 3.5 - 1.0 - - - - -
Salmagora 13.0 8.0 5.6 - - 9.5 - 1.9 -
Sokli — — — — — — — 9.4 —
Turii Mys — 2.0 21.0 — — 19.0 — 1.0 —
Sebl’yavr - 14.0 - - - 2.0 - 4.0 -
Vuoriyarvi 1.0 11.0 - - - 6.0 - 2.0 -
Sallanlatva - - - 1.5 3.5 - - 1.0 -
Iivara — — — 6.0 12.0 — — — —
Kovdozero — — — 1.0 — — — — —
Kandaguba - - - - 1.0 - - - -
Ivanovka - 3.0 - 2.0 - - - - -
Kurga 6.0 18.0 - - - - 6.0 - -
Kontozero - 4.0 - - - - 1.0 - 60.0
Total area
of intrusions, km2 39.5 77.5 30.1 12.3 16.5 47.0 7.5 22.4 60.0
Percentage of rock in intrusion area, % 12.63 24.78 9.62 3.93 5.27 15.03 2.40 7.16 19.18
Total volume of rock, km3 510.3 1001.3 388.9 158.9 213.2 607.2 96.9 289.4 775.2
Note. The total volumes of the rocks were calculated taking into account their eroded volumes and the results of the density modeling to a depth of 22.5 km.
netic anomalies, was found to include a large zone of alkaline ultramafics which extends as far as 15 km along a contact between the massive and the trachitoid khibinites. In contrast to the northern zone, the analysis of the structure of the southwestern part of what is known as an “ijolite-urtite arc” showed the absence of positive density anomalies at low levels. This confirms the trend revealed by drilling that the ijolite-melteigite intrusion pinches out at a depth of ca. 3 km.
It follows from the above that the results of our 3-D density modelling were good enough to determine the structure of the Khibiny and Lovozero plutons to a depth of ca. 12 km, which is sufficient for estimating the total volumes of the magma reservoirs of these plutons and clarifying the volumetric relations of their rocks. Taking into account the circular configuration of these intrusions in plan, their total volume can be approximated as a sum of truncated cones, whose radii Hi H,, and heights hi-h„ are known (Figure 6). The calculations of the rock proportions in the total volume was performed on the basis of the density modelling within the areas outlined for the Khibiny and Lovozero plutons to the depths of 10.1 and 11.9 km, respectively. The results
of our calculations are presented in Table 3. We assumed a priori that the radii of the feeding channels for these intrusions were 3 km for Khibiny and 1 km for Lovozero, these values being roughly 10% of the surface diameters of the intrusions. The channels have lengths equal to a distance between the bottom of the magma chamber and the zone of magma generation, which was inferred to reside at a depth of 55 km [Arzamastsev and Dalgren, 1993]. Taking into account the depth of erosion estimated by Virovlyanskii [1975] to be not more than a few kilometers, and also the numerous outliers of sedimentary and volcanic rocks that had formerly composed the roofs of the plutons, it can be assumed that the portion of the eroded rocks in the total volumes of the intrusions was approximately 10%.
Taking into account the approximated forms of the Khibiny and Lovozero massifs, the errors of calculating their volumes are not higher than 10% for their magma chambers, 30% for the feeders, and 40% for the eroded rocks. The calculated total volumes of the Khibiny and Lovozero massifs, including the volumes of the shallow chambers, feeders, and eroded rocks, were found to be 9100±1400 km3 and 1600±250 km3, respectively.
Figure 5. Schematic map showing the geologic structure of the Khibiny and Lovozero plutons based on the data reported by Bussen and Sakharov [1972], Galakhov [1975], and Gerasimovskii et al. [1966] and the results of this study.
4. Compositions of the Primary Magmas of the Paleozoic Phase of Tectono-Magmatic Reactivation
We calculated the average weighted concentrations of trace elements using the geochemical data obtained from analyzing the samples of the main varieties of Paleozoic igneous rocks in the Kola region. Our petrochemical data set included 1070 analyzes for the Khibiny Massif, 280 analyzes for the Lovozero Massif, 360, for the carbonatite intrusions,
230 analyzes for the volcanic rocks of the Lovozero and Kon-tozero suites, and 350 analyzes for the Paleozoic dikes and diatremes. The mean contents of trace elements were calculated using 116 analyzes of the representative samples of rocks collected in the above mentioned sites. Some of our chemical analyzes are presented in Tables 4 to 11.
The procedure of calculating the average weighted compositions of the primary magmas consisted in computing first the mean contents of elements for each rock type and then the concentrations of elements, taking into account the rock volumes and densities. Apart from the rocks of the alkaline-
Figure 6. Map of density distribution at a depth of 3.8 km in the Kliibiny and Lovozero massifs from the results of 3-D modeling. The contour lines show the boundaries of the rocks on the ground surface. The density sections show the contour lines used to calculate the volumes of the intrusions. The densities of the rocks are given in kg/m3.
ult.ramafic and phonolit.e series, calculations were made for the rocks of the Kliibiny and Lovozero massifs (Table 12). Attempts to determine the compositions of the latter were made earlier, including high-precision techniques [Busseji, and Sakharov, 1972; Gerasimovskii et al., 1966; Kukharanko at al., 1971]. The recent, data on the age, geologic structure, and geochemistry of the Kliibiny and Lovozero massifs suggest, that, they are composed of the rocks of two series: alkaline-ult.ramafic and phonolit.e ones [Arzamaststiv tit, al., 1998a; Galakhov, 1988]. Prom this standpoint, the mean composition of the Kliibiny rocks calculated earlier [Kukharenko at al., 1971] does not. give an idea of the composition of the primary magma of this unique massif. Moreover, our estimates of the mean compositions of the Kliibiny and Lovozero rocks (Table 12) are different, markedly from the earlier estimates [Kukharenko at al., 1971], because our calculations included a significant, volume of the alkaline-ult.ramafic rocks from a depth of more than 2 km in the northern part, of the Kliibiny Massif and in the northeastern part, of the Lovozero Massif. As a result., the chemical compositions of both massifs were displaced toward the higher contents of femic components and also of P, Cr, Ni, Co, Sc, and V.
Primary magmas of the alkaline-ultramafic series.
To improve the reliability of our estimate of the average composition of the alkaline-ult.rabasic magma, we compared our
average weighted composition of the alkaline-ult.ramafic intrusions with the compositions of the contemporaneous rocks of the province representing the most, primitive mantle magmas. The characteristics ascertaining the magmas to be most, primitive and least, differentiated mantle melts were
(1) the magnesium number =$=mg>68 found experimentally for the magnesium number of primary mantle melts [Egglur, 1989], (2) the relatively high contents of Ni and Cr, and
(3) the mineralogical and pet.rograpliic evidence of the mantle origin of rocks, such as the presence of mantle xenolit.lis and/or of the xenocryst.s of high-pressure phases (chrome diopside, Cr-bearing magnesian garnet., and chromite).
The most, probable candidates, composit.ionally resembling the primary magmas of the Kola alkaline-ult.ramafic series, have been found in the Paleozoic volcanics and dikes, which were emplaced prior to and after the emplacement, of the intrusions during a period of 405 360 Ma, respectively [Arzamaststiv tit, al., 1998b; Kramm at al., 1993]. We distinguished the following groups of rocks.
1. The alkaline-ult.ramafic volcanic rocks of the Lovozero and Kont.ozero suites, as the earliest, manifestations of the Paleozoic volcanic activity in the region. The alkaline pi-crit.es and ankaramit.es show $=mg = 0.72 0.81, Ni = 160 520 ppm, Cr = 143 1100 ppm, and Co = 21 100 ppm. Some samples were found to contain chrome diopside xenocryst.s.
2. The olivine and pyroxene melt.eigit.e porphyry, found in the satellites of large carbonat.it.e intrusions and emplaced
ARZAMASTSEV ET AL.: KOLA ALKALINE PROVINCE IN THE PALEOZOIC Table 3. The ratio of the rocks and their portions in the volumes of the Khibiny and Lovozero plutons
Rock portion in pluton volume Chamber volume, km3 Eroded volume, km3 Feeder volume, km3 Total volume, km3
Khibiny
Khibinite 0.23 1640 164 292 2097
Foyaite 0.17 1212 121 216 1550
Inequigranular syenite 0.08 571 57 102 729
Pulaskite 0.05 357 36 64 456
Calcilithic nepheline syenite 0.09 642 64 114 821
Peridotite 0.06 428 43 76 547
Pyroxenite 0.08 571 57 102 729
Melilitholith 0.02 143 14 25 182
Ijolite 0.17 1212 121 216 1550
Melteigite 0.03 214 21 38 274
Carbonatite 0.02 143 14 25 182
Total volume of the pluton 1.00 7132±710 713±285 1272±385 9117±1380
Lovozero
Lujavrite, differentiation product 0.26 337 34 37 407
Foiyaite, differentiation product 0.19 246 25 27 297
Eudialite lujavrite 0.09 116 12 13 141
Poikilitic sodalite and analcime syenites 0.13 168 17 18 203
Murmanite lujavrite 0.01 13 1 1 16
Alkaline syenite 0.05 65 6 7 78
Alkaline-ultramafic rocks 0.21 272 27 30 329
Ankaramite of Lovozero Suite 0.04 45 5 5 55
Basalt of Lovozero Suite 0.02 32 3 4 39
Total volume of pluton 1.00 1294±130 129±50 141±40 1565±220
Note. The total volume of the rocks was calculated from the eroded surface and as a result of density modeling to a depth 14.5 km.
during the main stage of magmatic activity. In spite of the extensive development of these rocks in different areas of the Kola Peninsula (Turii Mys, Ivanovka, Ozernaya Varaka), the melteigite porphyry showed poor variations in the contents of petrogenic and trace elements (Tables 4 and 5). Except for the samples from Ozernaya Varaka, showing some indications of fractionation, the melteigite porphyry samples yielded #mg = 67-76, Ni = 140-610 ppm, and Cr = 310820 ppm.
3. The olivine melanephelinite dikes and diatremes are spread over the entire territory of the Kola Peninsula, commonly concentrating in the frames of the alkaline intrusions. Geological data suggest that they were emplaced during the terminal phase of magmatic activity. Most of the dikes are poorly differentiated, as indicated by the presence of xeno-liths and xenocrysts of mantle origin [Arzamastsev and Bely-atskii, 1999], which could be preserved only under the condition of a relatively rapid rise of nephelinite magma from the zone of its generation. On this basis, the variety of olivine melanephelinite from the Namuaiv diatreme in the Khibiny Massif (Sample 1635/297.8) is comparable in terms of its Mg number and Ni and Cr contents with the most primitive magma.
Therefore we believe that the above mentioned three
groups of rocks are most consistent with the primary magmas that were generated during a relatively short period of magmatic activity in northeastern Fennoscandia.
The REE distribution patterns for all types of the distinguished rocks are presented in Figure 7a. The partition coefficients (La/Yb)N vary within 28.4 and 53.4 with a regular growth of (La/Yb)N from the early (volcanic) to the latest (dike) rocks. Comparison with the average weighted composition of the plutonic alkaline-ultramafic rocks of the province, calculated with due account for the geophysical data, showed that their REE contents were close to those in the melteigite porphyry, this supporting the earlier assumption that these rocks are close to the average composition of the alkaline-ultramafic rocks [Kukharenko et al., 1971].
In contrast to the rare earth elements, variations in the contents of other trace elements are more significant (Figure 7b), which stems, first, from the variations in the distribution of the accessory phases, such as apatite (P, Sr) and perovskite (Ti, Nb, Ta, Th), and, secondly, from the higher mobility of lithophile elements (Li, Rb). Nevertheless, the rocks of the initial, main, and terminal phases of magmatic activity show a regular, slow increase in the concentrations of most of incoherent elements in the rocks of the late phase. To sum up, our comparison shows that the
Table 4. Representative chemical analyses and densities of the alkaline-ultramafic intrusions of the Kola Province
Dunite Pyroxenite Turjaite Melteigite
Massif KVD KVD LSV SLM AFR AFR VUO VUO SLM KVD KVD KVD KVD KVD
Sample 4/400 4/898 Z-6 SL-23 AFR-5 AFR-6 93/192 282/223 SL-24 227/43 252/100 7/394 7/348 5/740
Density,
kg/m3 3350 3360 3660 3210 2960 3020 2990 2980 3010 2920 2900 3020 2960 3010
Si02 37.81 37.25 38.74 38.58 37.68 32.17 43.21 44.37 39.33 41.25 41.10 44.10 48.24 38.35
Ti02 0.24 0.30 0.35 0.52 1.69 7.19 4.14 2.93 3.86 0.79 0.47 1.26 0.22 1.29
A1203 1.20 1.16 0.38 0.96 3.36 7.41 3.88 4.47 7.05 10.90 8.02 10.15 1.24 4.01
Fe203 1.48 3.47 3.74 4.90 4.48 10.95 7.15 5.78 6.90 3.74 2.68 4.37 2.46 8.78
FeO 9.01 9.26 11.22 6.07 4.81 9.41 4.36 3.91 9.12 4.38 3.22 6.19 3.43 12.36
MnO 0.20 0.20 0.23 0.24 0.13 0.22 0.14 0.13 0.21 0.10 0.09 0.15 0.17 0.21
MgO 44.05 45.61 43.30 39.67 8.81 9.18 12.60 12.78 8.41 10.10 9.90 10.27 14.76 14.41
CaO 4.17 1.17 0.69 3.38 28.87 15.95 22.48 22.32 20.98 19.60 26.40 14.47 22.50 14.68
Na20 0.10 0.07 0.03 0.08 0.82 1.55 0.50 0.64 1.68 4.65 3.78 4.56 1.43 0.46
K20 0.05 0.14 0.03 0.51 0.06 1.29 0.21 0.49 0.37 2.10 1.35 2.54 0.77 2.02
p2o5 0.03 0.01 0.04 0.04 8.05 1.01 0.19 0.58 0.38 0.05 0.07 0.12 1.76 0.08
C02 0.24 0.18 0.16 0.10 0.20 0.27 0.36 0.73 0.30 0.28 0.40 0.21 1.73 0.68
Stot. 0.08 0.02 0.02 0.05 0.21 0.25 n.a. 0.03 n.a. n.a. n.a. n.a. n.a. 0.01
F 0.01 0.01 0.01 0.01 0.40 0.07 0.03 0.05 0.02 0.06 0.05 0.07 0.18 0.07
H20 0.72 0.58 0.50 3.96 0.47 3.07 0.44 0.67 1.33 1.42 1.86 0.88 0.89 2.18
Total 99.39 99.43 99.44 99.07 100.04 99.99 99.69 99.88 99.94 99.42 99.39 99.34 99.78 99.59
Mg# 0.90 0.90 0.87 0.92 0.77 0.64 0.84 0.85 0.62 0.80 0.85 0.75 0.88 0.68
Ijolite Nepheline Melteigite porphyry Ankaramite Olivine
syenite nephelinite
Massif KVD KVD SLN SLN KVD KVD OZV OZV TUR IVN LVZ KHI
Sample 5/610 7/30 25/15 26/151 27/65 MK-10 13- 8-OV 3011 M-9-87 107/111 1635/295.8
Density,
kg/m3 2860 2800 2850 2900 2910 2680 2890 2880 2890 2930 — —
Si02 44.56 44.44 41.93 41.25 42.92 51.83 40.76 45.40 40.00 40.58 44.27 34.48
Ti02 0.13 0.34 0.73 0.78 1.92 0.82 3.05 0.85 2.20 4.93 4.62 2.83
A1203 19.56 12.50 15.94 16.20 7.20 16.52 8.98 3.87 10.24 7.42 7.82 8.29
Fe203 1.17 0.22 4.48 6.57 4.56 2.18 6.91 3.55 8.00 6.98 3.14 6.70
FeO 2.01 7.43 6.71 4.67 7.92 4.70 7.02 6.76 5.43 7.51 10.96 3.76
MnO 0.10 0.18 0.17 0.13 0.14 0.12 0.19 0.24 0.16 0.20 0.19 0.20
MgO 5.66 5.26 5.35 5.62 11.86 3.38 10.39 8.97 9.67 12.22 12.35 13.89
CaO 9.52 14.74 11.16 11.30 17.40 4.44 14.32 22.67 15.22 11.66 9.85 15.23
Na20 9.94 7.29 8.53 8.77 2.67 8.58 2.80 2.52 4.99 2.83 2.49 0.92
K20 4.04 2.69 2.84 2.99 0.64 3.64 2.43 0.34 1.35 1.38 1.34 4.62
p2o5 0.79 1.00 0.76 0.67 0.20 0.54 0.55 3.41 0.33 0.93 0.50 0.91
C02 0.81 1.10 n.a. 0.59 0.80 0.44 0.64 0.26 0.64 0.44 0.11 2.45
Stot. 0.01 n.a. 0.04 0.05 n.a. 0.10 0.06 0.01 0.22 0.17 0.14 0.11
F 0.06 0.05 0.04 0.03 0.06 0.10 0.21 0.20 0.23 0.04 0.14 0.33
H20 1.15 0.81 0.85 0.41 1.29 1.86 1.51 0.62 0.80 2.05 1.56 4.60
Total 99.51 98.05 99.53 100.03 99.58 99.25 99.82 99.67 99.48 99.34 99.48 99.32
Mg# 0.83 0.56 0.59 0.68 0.73 0.56 0.73 0.70 0.76 0.74 0.67 0.87
Note. Here and in the tables that follow: KVD - Kovdor, AFR - Afrikanda, VUO - Vuoriyarvi, SLN - Sallanlatva, OZV - Ozernaya Varaka, IVN - Ivanovka, TUR - Turii Mvs, LVZ - Lovozero, KHI - Khibinv; n.a. - not analvzed; n.d. - not discovered. Mg# =
Mg/(Mg+Fe2+).
Figure 7. Chondrite (a) and primitive mantle (b) normalized trace element distribution in the Kola rocks of average compositions compared with their distribution in the undifferentiated rocks of the region. The normalizing factors for REE were used after Evensen et al. [1978] and Hofmann [1988].
average weighted contents of the majority of trace elements in the plutonic alkaline-ultramafic rocks, calculated with due allowance for geophysical data, agree with the values of the most primitive magmas of the alkaline-ultramafic series of the province, being most close to the contents in the olivine melteigite porphyry.
Primary magma of the phonolite series. Proceeding from the fact that the products of the phonolite magma were found only in the Khibiny and Lovozero massifs, the basis for calculating the mean composition of the phonolite magma was, first, the analytical data for the samples of all types of agpaite syenites from these intrusions and, secondly, the results of our 3-D density modeling, which allowed us to calculate the average weighted contents of trace elements. The results are presented in Table 12. The phonolite magma was found to have a high agpaitic coefficient, (Na+K)/Al = 1.09, and high LILE and HFSE concentrations, higher than the average values for alkaline-ultramafic magmas. We could not compare our average weighted composition of phonolite magma with the compositions of phonolite from the dikes in the surroundings of the Kovdor, Vuoriyarvi, and Ivanovka massifs because of the great scatter of many trace element contents in the latter.
5. Composition of the Paleozoic Mantle
The data available for the concentration of petrogenic and trace elements in the rocks of the Kola Province are sufficient to estimate the composition of the mantle which was reactivated in Paleozoic time and served as a source of alkaline magma. The data available today for the composition of the mantle, the PT conditions of magma generation, the phase equilibria at high pressures, as well as for the distribution patterns of trace elements, are good enough to get correct results not only through modeling the conditions of komatiite magma generation [Herzberg and Zhang, 1997; Vrevskii, 2000; Walter, 1998; Wei et al, 1990], but also for the melting of moderately enriched mantle rocks [McKenzie and O’Nions, 1991; Niu and Hekinian, 1997; Pickering-Witter and Johnson, 2000; Walter et al., 1995].
It is known that the concentration of a trace element in magma Cl is a function of the following variables: (1) the element concentration in the initial rock C0 (wt.%); (2) the melting degree F (the amount of melt relative to the initial rock); (3) melting type (partial, fractional, etc.); (4) the number of mineral phases involved in the melting process;
(5) the mineral-melt partition coefficient D. The initial sub-
Table 5. Contents of trace elements in the representative samples of rocks from the alkaline-ultramafic intrusions of the Kola Province (ppm)
Dunite Pyroxenite Turjaite Melteigite
Massif KVD KVD LSV SLM AFR AFR vuo VUO SLM KVD KVD KVD KVD KVD
Sample/Hole 4/400 4/898 Z-6 SL-23 AFR-5 AFR-6 93/192 282/223 SL-24 227/43 252/100 7/394 7/348 5/740
Li n.d. n.d. 2.58 3.32 n.d. 4.80 n.d. n.d. 6.22 n.d. n.d. n.d. n.d. n.d.
Rb 4.53 5.83 0.94 18.7 5.05 25.0 10.4 13.5 11.7 47.3 35.8 69.6 23.4 63.0
Cs n.d. n.d. 0.08 0.29 n.d. 0.11 n.d. n.d. 0.14 0.36 0.20 0.61 0.12 0.75
Sr 74.5 34.3 7.67 160 1525 1313 399 424 1103 1998 3050 358 563 298
Ba 21.1 111 12.3 152 20.6 25.7 151 280 801 1011 951 401 103 937
Sc 7.82 7.49 7.09 8.80 14.9 14.4 79.0 62.8 46.2 12.6 2.34 28.5 97.5 13.5
V 20.8 21.1 20.8 58.3 177 210 142 135 355 73.1 41.6 171 191 190
Cr 1462 1977 2124 2725 23.2 10.2 30.3 33.1 38.6 3.96 5.07 1083 51.1 30.4
Co 112 120 168 93.9 35.8 69.0 35.8 31.1 2.4 36.7 35.1 49.6 12.9 69.1
Ni 1480 1636 1432 1961 40.6 29.7 59.8 45.8 54.5 145 85.4 321 21.5 231
Y 1.49 n.d. 0.69 2.38 66.9 25.9 27.9 16.1 29.4 3.18 3.76 6.20 10.3 3.51
Nb 8.64 8.12 3.00 10.3 31.6 379 208 66.8 238.3 12.7 10.8 18.8 18.5 32.4
Ta 0.41 0.48 0.38 0.44 1.89 41.7 20.4 7.12 13.7 0.86 0.73 0.46 0.93 2.80
Zr 21.0 27.3 6.31 80.9 419 472 456 584 425 98.5 25.8 113 190 210
Hf 0.55 0.70 n.d. 1.93 12.9 5.72 18.0 21.9 11.9 2.88 0.68 2.99 4.78 2.59
U 0.29 0.25 n.d. 0.43 1.53 6.19 3.28 1.13 5.38 0.22 0.24 0.45 0.50 0.83
Th 0.95 0.65 0.29 0.48 7.36 72.7 15.9 8.30 12.2 0.81 0.88 1.07 3.80 2.30
La 5.16 1.69 0.95 5.39 354 475 224 85.7 172 28.5 42.6 21.2 42.5 8.25
Ce 11.1 4.60 1.66 10.1 551 1037 502 197 368 52.9 76.2 50.0 99.6 18.5
Pr 1.24 0.60 0.17 1.13 53.0 111 57.5 23.0 43.2 5.71 8.08 6.09 12.2 2.32
Nd 3.37 0.96 0.55 4.08 189 386 222 89.0 142 19.9 27.4 22.1 47.7 8.14
Sm 0.60 0.20 0.11 0.70 31.1 44.2 35.5 14.0 20.2 2.69 3.74 3.57 7.30 1.58
Eu 0.23 0.10 0.02 0.21 9.23 10.1 9.26 3.70 5.36 0.52 0.84 0.95 1.99 0.36
Gd 0.32 n.d. 0.08 0.65 24.8 23.2 24.1 9.38 13.8 1.62 2.06 2.28 5.15 1.02
Tb 0.05 n.d. 0.02 0.09 3.18 2.31 2.70 1.08 1.74 0.16 0.22 0.28 0.59 0.14
Dy 0.32 n.d. 0.09 0.47 16.0 8.19 10.9 4.68 7.64 0.71 0.90 1.42 2.59 0.77
Ho 0.06 0.01 0.02 0.10 2.74 1.10 1.52 0.75 1.23 0.13 0.14 0.26 0.41 0.14
Er 0.19 n.d. 0.05 0.26 5.92 2.14 2.65 1.46 2.70 0.28 0.32 0.63 0.90 0.40
Tm 0.03 0.02 0.01 0.04 0.67 0.25 0.31 0.19 0.36 0.04 0.04 0.10 0.13 0.07
Yb 0.21 0.09 0.06 0.24 3.50 1.48 1.67 1.16 2.03 0.25 0.23 0.67 0.93 0.42
Lu 0.03 0.02 0.01 0.04 0.49 0.21 0.23 0.17 0.27 0.04 0.03 0.12 0.14 0.08
(La/Yb)N 17.4 13.3 11.7 15.7 71.1 226.4 94.2 52.0 59.6 81.9 128.5 22.3 32.0 13.9
strate subject to melting can be primitive mantle [Hofmann, 1988], depleted mantle [McDonogh and Sun, 1995], and also metasomatized mantle enriched in incompatible elements. Because the contents of elements in depleted mantle and in primitive mantle were calculated using the composition of chondrite Cl [Evensen et al., 1978] and were found to be 1.5 and 2.51, respectively, the results of modeling are applicable to both compositions, differing merely in the general amount of magma enrichment in incoherent elements. In all of the models calculated here we used the composition of primitive mantle as the initial mantle substrate (Tables 13 and 14). In our calculations we used the partition coefficients of olivine and orthopyroxene after [Beattie, 1994], of clinopy-roxene after [Johnson, 1998], and of garnet after [Johnson, 1998; Prinzhofer and Allegre, 1985] (Tables 13 and 14). The values of the amphibole partition coefficients were used after [White, 1997].
The concentrations of elements in the products of partial melting Cl were calculated using the standard formulas [Rollinson, 1993]:
Cl/Co = l/[D0 + F(1 ^ P)],
where Do is the bulk partition coefficient in the initial mantle rocks before melting, and P is the bulk partition coefficient calculated for the minerals producing the melt.
The composition of the restite Cs was calculated using the formula
Cs/C0 = Do/[Do+F(l-P)].
The models of the Rayleigh fractional melting were calculated by the formulas
Cl/C0 = 1/D0(1 - PF/D0)WP-r),
Table 5. (continued)
Ijolite Nepheline syenite Melteigite porphyry Ankaramite Olivine nephelinite
Massif KVD KVD SLN SLN KVD KVD OZV OZV TUR IVN I.VZ KHI
Sample/Hole 5/610 7/30 25/15 26/151 27/65 MK-10 13-OB 8-OV 3011 M-9-87 107/111 1635/295.8
Li n.d. n.d. n.d. n.d. 5.21 43.4 3.60 4.20 16.0 12.3 40.8 14.4
Rb 54.6 63.7 50.1 52.9 15.5 131 64.2 7.91 35.5 36.4 53.4 133.2
Cs 0.04 0.01 0.04 n.d. n.d. 0.94 0.68 0.12 n.d. 0.46 1.12 2.25
Sr 281 730 359 388 429 1039 918 1106 1148 1543 1233 1461
Ba 129 163 76.2 67.1 210 1101 1047 31.6 444 574 759 1567
Sc 22.3 11.6 8.01 13.5 49.7 10.7 39.6 11.9 27.7 30.5 29.1 27.5
V 85.4 175 101 94.9 294 124 246 200 216 409 357 259
Cr 5.16 76.0 13.3 19.6 409 55.4 143 59.1 338 564 1025 613
Co 7.55 23.0 31.6 33.1 53.7 18.9 51.1 32.5 53.3 70.8 73.3 48.9
Ni 7.55 30.8 19.4 18.2 130 31.9 68.3 24.4 159 405 468 266
Y 4.66 7.21 6.25 6.33 10.6 12.5 14.8 20.5 15.8 43.1 28.2 24.6
Nb 20.4 65.3 16.3 16.3 16.1 52.8 163 29.0 87.1 70.5 79.9 131
Ta 2.16 3.99 0.54 0.81 0.73 2.87 13.9 2.05 5.76 5.05 5.85 9.28
Zr 264 283 58.2 55.4 82.8 155 218 164 182 609 321 266
Hf 5.41 4.79 1.71 1.80 3.24 3.73 6.53 3.55 5.20 14.9 8.16 6.35
U 0.50 1.54 0.49 0.44 0.38 1.68 1.53 0.83 1.55 2.39 1.87 2.92
Th 7.02 17.2 1.86 2.33 1.31 8.56 14.7 12.2 6.84 7.08 7.12 10.5
La 32.0 55.4 21.6 22.6 18.5 52.1 133 169 91.3 86.5 70.9 131
Ce 70.2 118 40.0 44.1 36.2 88.7 273 315 160 216 169 248
Pr 7.93 13.1 4.42 4.99 4.19 8.40 28.9 34.1 16.1 29.0 21.7 28.8
Nd 28.7 46.0 15.5 18.3 16.1 27.3 100 116 55.6 131 88.2 106
Sm 4.22 5.94 2.55 3.12 2.92 3.99 12.8 15.1 7.92 26.0 15.7 15.7
Eu 1.12 1.45 0.80 0.91 0.97 0.78 3.09 3.60 2.09 7.23 4.17 4.36
Gd 2.69 3.47 2.06 2.33 2.52 2.84 7.65 11.1 4.99 19.4 10.9 10.8
Tb 0.30 0.37 0.25 0.28 0.37 0.39 0.88 1.28 0.64 2.29 1.39 1.18
Dy 1.32 1.48 1.31 1.38 2.07 2.16 3.86 5.26 3.31 10.4 6.58 5.79
Ho 0.20 0.27 0.25 0.25 0.40 0.44 0.65 0.82 0.61 1.71 1.10 0.98
Er 0.42 0.71 0.58 0.57 0.99 1.26 1.43 1.87 1.44 3.62 2.52 2.13
Tm 0.06 0.10 0.09 0.08 0.15 0.19 0.18 0.25 0.20 0.45 0.31 0.27
Yb 0.50 0.72 0.60 0.54 0.93 1.22 1.09 1.50 1.19 2.60 1.67 1.67
Lu 0.08 0.12 0.11 0.10 0.14 0.18 0.17 0.25 0.18 0.34 0.23 0.22
(La/Yb)N 45.0 54.3 25.4 29.5 14.0 30.0 86.1 76.2 54.1 23.4 29.9 55.0
Cs/Co = (1 — /'/•"//.)„)I;'’/(I — F) 5.1. Models for the Melting of Normal Primitive
Mantle
for the derivates and the restite, respectively.
The PT conditions for the generation of nephelinite magmas in the Kola Province estimated using mantle xeno-liths [Arzamastsev and Dalgren, 1993] show that alkaline-ultrabasic magmas might have been produced in the conditions of the mantle facies of spinel and garnet Iherzolites. In the sections that follow we describe the calculations of the melting models:
(1) for normal primitive mantle (Tables 13 and 14) having the composition of spinel or garnet peridotite;
(2) for enriched mantle in which the concentrations of elements were 3 times as high as those in the primitive mantle; the versions here were for the melting of spinel and garnet peridotite, both containing amphibole and phlogopite.
Melting of spinel peridotite. In this version we considered the melting of primitive mantle having the composition (Ol0.578 + Opxo.27 + Cpxo.119 + Spl0.033) [McKenzie and O’Nions, 1991] in the melting interval of 0.1-15%, for which the compositions of the melts and complementary restites are controlled in the interval of spinel stability [Robinson and Wood, 1998; Walter et al., 1995] (pressure 1.5-2.8 GPa) by the cotectic Olo.io + Opxo.15 + Cpxo.55 + Splo.2o- The resulting compositions of the melts (Figure 8) showed, in contrast to the average compositions for the Kola Province, the low contents of light REE and a poorly fractionated distribution pattern (La/Yb)N<9, this pattern being controlled by the amount of dissolving clinopyroxene.
Table 6. Contents of petrogenic elements and densities in the representative samples of alkaline and ultramafic rocks from the Khibiny Massif
Rock PRD PRD PRX PRX PRX PRX MML MML FOM FOM FOI FOI CC
Sample/Hole 1010 A-1044 1010 A-1036 A-1038 A-1087 1010 1010 455 466 1072 455 603
Depth, m 1052 - 1186 - - - 1059 1165 345 552 530 402 23
Density, kg/m3 3350 3330 3300 3120 3090 3020 2850 2820 3020 2990 2830 2850 2860
Si02 38.26 43.62 39.52 41.60 41.37 37.53 28.01 29.98 37.56 44.00 43.48 44.81 2.89
Ti02 3.51 3.41 7.25 4.91 4.18 2.90 6.01 2.84 7.73 4.60 2.67 1.97 0.01
AI2O3 4.29 5.21 9.17 5.92 7.37 11.09 6.12 3.58 3.38 3.64 18.85 17.44 0.98
Fe203 10.31 5.41 8.00 4.33 8.90 5.90 15.57 10.51 11.60 9.20 4.88 5.31 3.62
FeO 5.25 7.06 7.00 11.25 5.22 4.04 5.83 5.18 11.81 9.13 3.17 3.19 2.05
MnO 0.28 0.19 0.28 0.23 0.23 0.17 0.26 0.29 0.61 0.33 0.16 0.21 0.91
MgO 19.93 17.85 7.01 11.67 13.38 6.49 9.20 16.58 7.17 8.32 3.35 3.94 0.88
CaO 12.60 9.36 11.74 11.20 9.09 18.40 23.43 28.46 14.68 13.41 7.70 7.91 41.75
Na20 0.65 2.26 4.56 3.47 3.18 5.69 1.35 0.67 3.30 4.02 10.58 10.74 1.24
K20 2.06 2.91 2.36 2.11 3.60 1.78 0.86 0.04 0.81 1.46 4.45 3.78 0.12
P2O5 0.42 0.36 1.25 0.38 0.36 2.97 0.77 0.37 0.99 0.27 0.65 0.22 0.11
C02 0.38 0.14 0.32 0.23 0.32 0.96 0.49 0.35 0.05 0.05 0.31 0.07 38.96
Stot. 0.16 0.03 0.19 0.12 0.04 0.40 0.04 0.02 0.10 0.10 0.03 0.05 0.42
Cl n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. n.a. 0.01
F 1.06 0.45 0.32 0.60 0.91 0.14 0.58 0.16 0.20 0.36 0.09 0.07 0.35
LOI 0.68 1.01 0.48 1.52 1.32 1.27 1.53 0.46 0.33 1.08 0.20 0.48 0.17
Total 99.84 99.27 99.45 99.54 99.47 99.73 100.05 99.49 100.32 100.46 100.57 100.19 94.47
#Mg 87 82 64 65 82 74 74 85 52 62 65 69 43
Note. PRD - peridotite, PRX - pyroxenite, MML - melilite rock, FOM - melteigite, FOI - ijolite, CC - calcitic carbonate; n.a. - not analyzed.
The greatest differences were observed in the distribution of heavy REE which showed, with their total elevated content, an extremely low fractionation degree (Sm/Yb)N < 2. Similar results were obtained for the version of fractional melting.
Melting of garnet peridotite. The melting of mantle rocks with the composition of (Olo.eo + Opxo.20 + Cpxo.os + Grto.12) [McKenzie and O’Nions, 1991] requires a higher pressure (>2.8 GPa), at which, in the melting interval of 0.1-15%, the compositions of the melts and complementary restites are controlled by the cotectic OI0.05 + Opxo.os + Cpxo.36 + Gro.54- It should be noted that cotectic relationships are hard to determine at different PT conditions and can be estimated very roughly [Walter et al., 1995]. At the same time the composition of the cotectic is not essential because at low degrees of melting, the partitioning of trace elements between the melt and the restite takes place in accordance with their own D values.
In contrast to the version with spinel, both the partial and fractional melting of garnet peridotite produce melts with a high degree of REE fractionation (La/Yb)N = 50-130 (F =
0.1-0.5%) (Figure 9, a and b). Comparison with the composition of primary magma in the Kola Province shows a similarity of the REE distribution to the compositions of melts with low degrees of melting (F = 0.1-1.0%), however the threshold total REE content in the models for the melt-
ing of “normal” primitive mantle (that is, with F—¥ 0%) is many times lower than that observed in the magmas of the province. A specific feature of the model discussed is a similarity between the composition of the restite obtained for 1-per cent melting and the composition of depleted mantle after [McKenzie and O’Nions, 1991].
The models of the partial and fractional melting of trace elements (Figure 9, c and d) showed higher variations. This might have been caused by the higher mobility of some elements and by the less exact calculation of partition coefficients. Nevertheless, the data obtained for the majority of trace elements were similar to those for REE and showed the significantly higher Nb, Ta, Zr, Hf, and Y contents in the Kola primary melts, as compared to their threshold contents in the model melts with low melting degrees.
5.2. Models for the Melting of Enriched Metasomatized Mantle
Inasmuch as the above models showed a low probability of getting melts enriched in incompatible elements, resembling the contents observed in the primary magmas of the Kola Province from the melts produced by the normal primitive mantle, this version was aimed to calculate the melting of mantle rocks, in which the contents of incompatible elements
Table 7. Contents of trace elements in the representative rock samples of the alkaline-ultramafic series from the Khibiny Massif (ppm)
Rock PRD PRD PRX PRX PRX PRX MML MML FOM FOM FOI FOI FOI CC
Sample/Hole 1010 A-1044 1010 A-1036 A-1038 A-1087 1010 1010 455 466 301/500 1072 455 603
Depth, m 1052 - 1186 - - - 1059 1165 345 552 - 530 402 23
Li 8.01 36.6 22.3 46.1 84.3 2.60 5.97 7.53 12.2 28.4 6.01 28.5 7.90 8.86
Rb 138 115 86.0 113 208 23.9 58.5 1.13 15.9 37.7 29.8 23.4 34.4 8.40
Cs 2.60 1.30 0.60 1.52 2.20 0.32 0.79 0.03 0.32 0.22 0.32 3.62 0.19 0.09
Sr 1126 893 2194 995 1485 748 5933 539 2544 3237 1012 31.3 1352 3595
Ba 1364 558 852 432 521 187 1063 49.4 168 1114 248 357 335 4993
Sc 23.9 21.4 20.0 28.2 21.1 19.0 42.0 24.0 26.5 22.3 1.32 2.50 19.5 6.08
V 506 213 428 251 265 242 298 83.1 673 739 230 1.80 276 14.4
Cr 1277 1131 135 800 724 23 158 1061 112 39.1 35.3 72.8 51.4 33.9
Co 98 81 46 66 63 28 84 102 65 75.6 14.0 2.6 16.0 12.9
Ni 1018 915 134 428 568 38 278 994 104 61.9 9.9 37.4 29.1 31.9
Y 27.7 19.7 86.6 30.4 33.6 45.9 30.5 18.3 63.0 36.0 27.2 41.8 24.1 316
Nb 73 39 371 104 95 154 312 157 261 169 173 215 110 40.3
Ta 5.41 2.55 28.0 7.64 5.75 6.83 23.3 15.1 31.2 16.4 13.7 15.8 7.98 0.62
Zr 345 220 744 481 453 429 480 173 812 814 275 929 565 2.05
Hf 8.74 5.94 18.0 10.3 11.1 12.2 12.5 4.59 19.8 24.8 7.86 25.3 12.9 1.22
U 1.56 0.41 1.57 1.76 1.86 3.05 4.45 2.97 0.85 0.20 0.26 3.68 1.08 2.46
Th 5.04 2.67 23.4 9.09 7.22 6.10 27.9 19.2 3.99 0.85 1.89 23.2 3.19 533
La 85.6 62.0 380 102 102 143 251 128 222 108 109 119 69.4 2909
Ce 176 138 747 223 216 255 465 270 441 250 230 238 150 3144
Pr 20.3 16.5 88.9 26.4 24.8 28.1 49.2 28.9 50.8 30.7 25.1 27.3 16.6 413
Nd 79.9 68.4 323 105 99.0 112 173 103 190 116 89.3 97.6 62.2 1787
Sm 13.7 11.6 49.5 18.0 16.7 22.0 23.3 13.3 30.4 19.9 14.2 16.8 10.4 379
Eu 3.9 3.3 14.3 5.1 4.7 7.1 6.2 3.5 9.0 5.8 3.96 1.68 3.04 118
Gd 10.8 8.47 33.1 13.2 12.0 20.6 13.8 7.50 22.8 13.8 11.3 11.2 7.63 269
Tb 1.39 1.03 4.37 1.65 1.64 2.82 1.66 0.90 3.08 1.9 1.48 1.73 1.05 31.8
Dy 6.42 4.99 21.0 7.57 7.71 12.2 7.85 4.20 14.6 9.1 6.54 9.44 5.26 105
Ho 1.04 0.81 3.42 1.22 1.34 1.88 1.18 0.69 2.46 1.6 1.14 1.97 0.93 15.2
Er 2.45 1.85 7.83 2.63 3.04 4.03 2.67 1.64 5.61 3.6 2.44 5.31 2.37 30.3
Tm 0.28 0.21 0.86 0.31 0.37 0.44 0.29 0.20 0.66 0.5 0.29 0.81 0.32 3.82
Yb 1.54 1.21 4.80 1.82 2.19 2.40 1.66 1.20 4.06 3.2 1.53 4.71 2.20 25.0
Lu 0.21 0.17 0.60 0.27 0.30 0.32 0.22 0.18 0.59 0.6 0.17 0.70 0.34 3.42
Note. See Table 6 for the rock codes.
were taken to be n times higher than in primitive mantle.
Melting of spinel peridotite. In this version we modeled the melting of amphibole-bearing spinel peridotite OI0.59 + Opxo.21 + Cpxo.io + Splo.o5 + Ampho.os, close to the mineral composition of the mantle rock from a diatreme in the Khibiny Massif [Arzamastsev and Dalgren, 1993]. The plots presented in Figure 10, a and b, show a substantial difference of the REE distribution pattern in the model magma from that observed in the rocks of the Kola Province. The melts obtained for both the partial and the fractional melting of threefold enriched primitive mantle yielded poorly fractionated spectra in the region of Sm-Lu (Sm/Yb)N < 1.8. The distribution of the other trace elements (Figure 10, c and d) shows that the melting of the substrate of this composition cannot give the Rb and Nb concentrations observed in the primary magmas of the province.
Melting of garnet peridotite. We calculated a melting model for two compositions: OI0.59 + Opxo.20 + Cpxo.os + Grto.o8 + Phlogo.os and OI0.59 + Opxo.20 + Cpxo.os + Grto.o8 + Phlogo.o2 + Ampho.o3. The existence of these mineral associations is controlled by the stability of phlogopite and/or amphibole in the presence of garnet and clinopy-roxene in mantle conditions. K. Sato and E. Ito [1997] proved the stability of phlogopite in garnet harzburgite in the mantle underlying a craton at pressures growing as high as 5 GPa. On this basis they suggested the possibility of phlogopite formation as a secondary mineral produced by the reaction of garnet with the rising metasomatic fluid flow. It was supposed earlier [Dawson and Smith, 1982] that inasmuch as the stability of amphibole in the mantle is limited by a narrow pressure range, corresponding to a spinel facies depth, this mineral, in contrast to phlogopite, cannot be a receptacle of incoherent elements in deep zones of the mantle.
Table 8. Contents of petrogenic elements in the representative rock samples from the phonolite series of the Khibiny Massif________,_______________________________________________________________________________________________________,
Rock SFNX SFNX SFNX SFNX SFNX SFNX SFNR SFNR SFNF SFNF SFNF SAP SAP
Sample (Hole/depth) Z-l A-1035 A-1037 A-1042 A-1046 A-1049 455/890 818/637 2237 A-1014 A-1029 642/210 642/397.7
Si02 54.24 51.98 53.67 54.07 42.70 47.89 48.48 50.54 53.03 55.22 56.98 58.69 60.59
Ti02 0.69 0.22 0.50 0.75 14.81 4.78 1.30 0.81 0.75 0.66 0.17 0.50 0.40
AI2O3 20.62 23.16 22.41 22.14 8.46 11.30 23.54 22.03 20.60 20.85 21.14 18.68 18.28
Fe203 3.14 2.66 1.26 1.30 3.37 5.40 2.08 2.17 2.01 1.28 1.30 0.44 0.41
FeO 1.03 2.00 2.07 2.46 2.64 4.58 1.94 1.96 2.19 2.87 2.07 2.85 2.67
MnO 0.18 0.17 0.12 0.15 0.32 0.62 0.12 0.12 0.17 0.21 0.10 0.09 0.09
MgO 0.40 0.14 0.54 0.41 0.96 1.45 0.40 0.80 0.71 0.84 0.23 0.72 0.32
CaO 1.06 0.66 1.16 0.76 14.06 6.50 0.96 1.25 2.76 0.63 0.39 1.89 1.38
Na20 11.21 12.20 11.16 10.67 5.08 6.97 9.12 8.30 9.52 9.68 7.31 7.54 7.20
K20 5.63 5.03 5.36 5.45 2.47 4.24 11.19 10.99 5.98 5.44 8.28 5.61 5.63
P2O5 0.12 0.09 0.11 0.09 1.53 0.66 0.31 0.15 0.16 0.20 0.02 0.16 0.09
C02 0.06 0.05 0.01 0.01 0.09 3.03 0.02 0.05 0.20 0.78 0.14 0.77 0.84
Stot. 0.18 0.09 0.03 0.04 0.02 0.11 n.a. n.a. 0.02 0.13 0.07 0.18 0.14
Cl 0.06 0.012 0.037 0.035 0.027 0.004 0.06 n.a. 0.41 0.007 0.03 0.43 0.04
F 0.14 0.08 0.13 0.13 0.69 0.56 0.04 0.07 0.11 0.23 0.05 0.05 0.05
LOI 0.88 1.09 0.80 0.83 0.71 1.14 0.17 0.70 1.05 0.51 1.15 0.68 1.22
Total 99.64 99.63 99.37 99.30 97.94 99.23 99.73 99.94 99.67 99.54 99.43 99.28 99.35
Note. SFMX - agpaite syenite from the peripheral part of the massif, SFNF - agpaite syenite from the central part of the massif, SAP - pulaskite, SFNR - calcilithic nepheline syenite; n.a. - not analyzed.
However, Niida and Green [1999] showed that the stability of pargasite amphibole was controlled by the bulk content of Xii <)—K () in the mantle rocks: at T=1000°C, it is limited by pressure of 2.6 GPa and 0.33 wt.% X;i.()—K.(). and grows higher at 2.9-3.0 GPa and 1.17 wt.% X;i.()—K.(). thus extending into the garnet stability region. Moreover, Niida and Green [1999] discovered that the Na2 0 content in pargasite was also a function of pressure. Our calculations of the melts from the unenriched primitive mantle, quoted above, show that at low melting degrees (F = 0.1-0.5%) the content of K2O alone rises as high as 0.5-1.1 wt.%. On the other hand, pargasite from the harzburgite xenoliths in the Khibiny Massif contains 2.91-3.10 wt.% Na20. Therefore it can be assumed that under the PT conditions of magma generation in the Kola Province the mantle rocks might have contained not only phlogopite but also amphibole.
The REE distribution plots (Figure 11, a and b) show an agreement between the real composition of primary magma in the Kola Province and the melts obtained through the melting of enriched mantle material containing, apart from olivine, orthopyroxene, clinopyroxene, and garnet, also phlogopite (up to 5%), or phlogopite (2%) and amphibole (3%). The results that were most close to the calculated ones were obtained for the 0.3-0.5% fractional melting of phlogopite-amphibole peridotite (Figure 11, b), the Kola magma composition fitting the range of the latter. The results of modelling the concentrations of the other trace elements (Figure 11, c and d) yielded, like in all of the other models, a wide scatter of values, which allows one to merely surmise the generation of the Kola magmas as a result of the low-degree partial melting of phlogopite-amphibole peridotite
(<1%). At the same time the presence of a negative P and Ti anomaly in the primary magma of the Kola Province suggests the potential presence of apatite and perovskite in the initial mantle rocks. Of particular significance are the high contents of Nb, Ta, Zr, and Hf in the Kola primary magmas, which are 5 to 10 times higher than their threshold concentrations in the model melts of enriched mantle.
6. Discussion of Results
6.1. Compositions and Generation Conditions of Primary Magmas
Our calculated average weighted contents of rare earth elements in the primary ultramafic magmas of the Kola Province agree with the values reported for some varieties of the most primitive magmas of the region [Beard et al., 1998; Ivanikov et al, 1998; Rukhlov, 1997] and also with their mean contents in alkaline lamprophyres [Rock, 1987] and in the most primitive melanephelinite melts from other alkaline provinces [Le Bas, 1987; Rock, 1987]. The results obtained for the other trace elements showed, as reported earlier [Kogarko, 1984], a significant enrichment of the mean composition of the Kola phonolite mantle magma in Nb, Ta, Zr, and Hf (Figure 12, a). At the same time no positive HFSE anomaly was found in the primitive alkaline-ultramafic magmas of the region. Comparison with the less differentiated rocks of the Meimecha-Kotui Province [Arndt
Table 9. Contents of trace elements in the representative rock samples of the phonolite series from the Khibiny Massif (ppm)
Rock SFNX SFNX SFNX SFNX SFNX SFNX SFNR SFNR SFNF SFNF SFNF SAP SAP
Sample (Hole/depth) Z-l A-1035 A-1037 A-1042 A-1046 A-1049 455/890 818/637 2237 A-1014 A-1029 642/210 642/397.7
Li 31.3 15.7 17.8 18.8 36.0 110 7.42 14.8 15.6 57.1 8.03 14.9 26.3
Rb 162 83.7 68.5 58.4 83.6 128 234 286 66.1 388 156 96.6 92.0
Cs 1.89 1.94 1.34 1.45 2.22 1.98 4.03 6.63 1.45 3.79 1.15 1.72 1.69
Sr 2711 1005 1318 1209 2600 3522 687 561 1500 450 907 936 309
Ba 1469 570 1029 1033 404 1312 905 1738 1316 572 366 1633 485
Sc 1.24 1.68 3.39 2.49 4.80 5.52 2.97 3.90 1.74 1.90 0.19 2.04 1.72
V 43.6 28.7 38.4 55.6 278 198 68.3 69.5 79.5 18.2 41.4 46.8 34.2
Cr 34.3 19.6 11.1 21.3 14.9 16.1 19.6 15.8 35.9 23.4 24.5 38.1 33.3
Co 2.84 1.47 1.77 1.52 3.71 4.62 3.89 4.08 5.14 2.41 2.49 3.96 2.75
Ni 7.11 4.80 4.55 4.98 9.62 5.73 4.31 5.35 11.1 6.00 10.4 10.0 8.96
Y 51.2 18.8 21.7 19.5 387 212 6.60 7.86 15.8 21.2 6.02 12.9 8.19
Nb 225 184 140 156 1627 895 90.2 117 150 103 55.1 102 79.9
Ta 9.49 11.1 9.14 11.8 243 81.5 3.37 3.63 9.94 5.52 1.24 8.58 6.74
Zr 638 309 520 621 2367 1456 161 291 238 251 204 254 223
Hf 15.0 6.13 10.6 13.3 72.1 36.9 3.22 4.98 4.55 5.46 3.55 5.34 4.64
U 8.93 3.84 3.42 2.57 7.00 14.6 1.54 2.50 2.18 1.51 1.06 3.52 3.66
Th 30.7 12.5 10.0 9.07 26.1 64.8 5.60 6.90 14.4 9.37 7.32 16.5 18.1
La 163 77.9 79.3 73.4 2906 844 35.9 33.9 184 159 28.7 98.7 60.6
Ce 352 165 161 144 5437 1792 60.9 58.3 266 276 33.8 165.0 98.9
Pr 32.9 19.4 18.0 18.4 528 238 6.28 5.41 20.5 25.7 3.32 14.3 8.91
Nd 108 72.8 64.8 68.6 2075 876 20.7 17.7 58.3 77.7 9.29 42.8 27.1
Sm 16.2 11.2 9.8 0.5 347 131 2.75 2.42 6.51 9.13 1.19 5.28 3.24
Eu 4.50 3.14 2.76 2.99 94.2 35.8 0.68 0.64 1.71 1.89 0.30 1.35 0.89
Gd 12.8 7.51 6.53 7.05 215 82.0 1.89 1.78 3.83 5.07 0.83 3.09 1.97
Tb 1.85 1.02 0.96 0.96 28.3 11.1 0.27 0.27 0.54 0.74 0.15 0.45 0.29
Dy 9.81 4.99 4.99 4.85 124 52.6 1.47 1.62 3.05 4.13 1.00 2.55 1.64
Ho 1.84 0.83 0.90 0.85 18.2 8.44 0.28 0.33 0.58 0.73 0.23 0.49 0.32
Er 4.41 2.04 2.25 2.12 37.4 19.0 0.74 0.85 1.54 1.99 0.76 1.30 0.88
Tm 0.63 0.24 0.29 0.28 3.77 2.17 0.10 0.12 0.21 0.28 0.12 0.19 0.14
Yb 3.45 1.36 1.69 1.67 19.2 11.7 0.65 0.75 1.43 1.76 0.72 1.16 0.87
Lu 0.46 0.17 0.24 0.23 2.29 1.49 0.09 0.11 0.21 0.26 0.11 0.18 0.14
Note. See Note in Table 8 for the legend.
et al., 1995, 1998] (Figure 12, b) revealed that the distribution of trace elements in the Kola alkaline-ultramafic magmas resembled that in alkaline picrites and melanephelinites. The primitive magmas of both provinces showed a negative K anomaly, which, along with the low Rb contents, seems to have been related to the fractionation, prior to lava flow, of a K-bearing phase, probably phlogopite. Our model calculations show that the Kola primary magmas, rich in incoherent elements, could not be derived from primitive mantle even in the case of critically low melting degrees. Therefore the most probable case was the melting of enriched mantle, the composition of which had been altered by the process of mantle metasomatism. Based on the estimates obtained for the Meimecha-Kotui Province [Arndt et al., 1998] and on the model calculation of carbonatite magma melting [McKenzie and O’Nions, 1991], we assumed that the degree of the rock enrichment might have been 3 times higher than the mean contents of incompatible elements in primitive mantle.
It appears that the existence of the enriched mantle substrate was related to the processes of a plume-lithosphere interaction, which produced extensive zones of metasoma-tized mantle. According to the results of studying mantle xenoliths, the mineral composition of mantle in zones of mantle metasomatism differs by the presence of amphi-bole, phlogopite, rutile, ilmenite, and apatite, in addition to olivine, orthopyroxene, clinopyroxene, spinel, and garnet [Haggerty, 1995; Konzett et al., 2000]. There is numerous evidence proving the existence of metasomatized mantle in regions of alkaline magmatism [Bailey, 1987; Wyllie, 1995; Yaxley et al., 1998], the Kola alkaline Province being one of them [Tolstikhin et al., 1999]. The direct proofs of the existence of the zones of mantle metasomatism in the region are the findings of spinel harzburgite xenoliths, containing pargasite and phlogopite, in a diatreme from the Khibiny Massif [Arzamastsev and Dalgren, 1993].
Our modeling of the behavior of trace elements during
Table 10. Contents of petrogenic elements in the representative samples from the Lovozero Massif
Rock SA SA SA SFS SFS SFS SFNDL SFNDL SFNDF SFNDF SFNDF SFNDF SFNLE SFNLE SFNLE SFNLE SFNLE SFNLE
Sample/Hole 903 903 903 145 193 143 202 100 215 109 901 A-1210 7 7 1510-g 1571-d A-1208 A-1209
Depth, m 978 1195 827.5 138 268 80 94.7 57.8 371.3 64.7 993.4 - 8.7 128.3 - - - -
Si02 52.58 50.65 51.61 56.34 53.64 54.11 54.16 51.62 53.99 54.02 52.14 59.24 54.25 53.19 52.03 52.76 55.64 55.71
Ti02 1.29 0.87 2.16 0.62 0.52 1.09 0.89 1.20 0.62 0.47 1.52 0.48 1.14 1.10 1.28 1.28 0.83 0.72
AI2O3 19.54 20.93 19.47 18.13 21.92 19.96 14.64 13.37 21.53 19.62 19.40 20.05 13.61 14.12 16.54 14.09 14.87 17.33
Fe2C>3 2.63 3.03 1.72 2.32 2.68 3.87 9.05 9.94 4.27 3.41 3.55 2.08 5.61 5.26 6.47 8.20 4.85 4.55
FeO 1.60 1.35 3.28 0.71 1.52 0.82 2.44 2.32 0.88 0.80 1.33 0.82 3.42 3.21 1.71 1.73 2.37 1.56
MnO 0.37 0.21 0.40 0.30 0.20 0.18 0.28 0.34 0.13 0.18 0.32 0.11 0.45 0.45 0.55 0.51 0.44 0.27
MgO 0.91 0.37 0.94 0.27 0.25 0.96 1.21 1.43 0.36 0.41 0.51 0.12 0.87 1.24 0.92 0.94 1.85 0.32
CaO 1.15 1.64 0.90 0.86 0.49 1.20 2.37 2.07 0.19 1.49 0.79 0.35 1.51 1.32 1.34 2.07 1.80 0.92
Xa.O 8.65 9.50 10.07 10.67 10.76 10.14 7.98 10.50 10.76 10.68 13.26 6.88 10.31 11.70 8.82 7.93 9.85 9.93
K20 3.54 2.07 4.57 6.04 5.51 5.73 4.28 4.50 6.32 6.10 5.13 7.66 4.79 4.52 5.91 5.46 4.59 5.05
P2O5 0.28 0.38 0.17 0.45 0.06 0.34 0.09 0.05 0.24 — 0.08 0.02 0.10 0.05 0.06 0.04 0.02 0.02
C02 0.59 1.17 0.63 0.75 0.62 0.30 - 0.23 - 0.21 0.20 0.06 - - - - 0.18 0.07
Stot. 0.48 0.07 0.44 0.29 0.08 0.21 0.05 0.04 0.01 0.02 0.03 0.05 0.22 0.17 0.11 0.14 0.04 0.07
Cl 0.01 0.01 0.01 0.29 0.15 0.05 0.07 0.04 0.05 — 1.09 0.01 — — 0.15 0.17 0.23 0.30
F 0.14 0.06 0.21 0.32 0.03 0.23 0.03 0.06 0.12 0.05 0.08 0.01 0.10 0.21 0.16 0.14 0.39 0.02
LOI 5.46 6.99 2.92 0.79 0.95 0.65 1.67 1.54 0.96 1.89 0.82 1.65 1.15 1.18 1.60 2.50 0.78 1.23
Total 99.22 99.30 99.50 99.15 99.38 99.84 99.21 99.25 100.43 99.35 100.25 99.59 97.53 97.72 97.65 97.96 98.73 98.07
Note. SA - alkaline syenite, SFS - poikilitic sodalite syenite, SFNDF - foyaite (differentiated), SFNDL - lujavrite (differentiated), SFNLE - eudialyte Lujavrite, ANK ankaramite, BAS - alkaline basalt.
ARZAMASTSEV ET AL.: KOLA ALKALINE PROVINCE IN THE PALEOZOIC
Table 11. Contents of trace elements in the representative samples of rocks from the Lovozero Massif (ppm)
Rock SA SA SA SFS SFS SFS SFNDL SFNDL SFNDF SFNDF SFNDF SFNDF SFNLE SFNLE SFNLE SFNLE SFNLE SFNLE
Sample/Hole 903 903 903 145 193 143 202 100 215 109 901 A-1210 7 7 1510-g 1571-d A-1208 A-1209
Depth, m 978 1195 827.5 138 268 80 94.7 57.8 371.3 64.7 993.4 8.7 128.3
Li 133 82.9 43.5 60.4 28.0 56.7 29.4 40.3 27.2 52.2 28.7 12.4 62.8 96.7 111 96.0 92.0 8.28
Rb 19.6 22.3 50.9 124 138 31.5 62.6 40.7 77.0 89.6 60.1 215 83.7 112 59.5 88.5 47.2 105
Cs 9.56 25.8 1.23 1.61 1.91 1.26 0.64 2.04 1.11 2.38 0.98 2.03 1.98 1.81 2.88 1.44 0.94 0.94
Sr 738 1073 900 808 364 1447 257 381 304 54.1 126 168 1334 1271 5925 5862 1355 940
Ba 290 179 229 642 338 985 126 209 112 147 41.6 523 403 403 1715 732 537 346
Sc 10.0 8.04 11.1 13.6 11.3 11.4 10.9 11.0 14.0 11.3 14.5 4.55 15.1 15.2 15.0 14.2 14.7 16.2
V 50.1 46.7 33.8 12.0 15.4 60.1 243 195 42.4 11.6 54.5 5.98 69.8 65.2 78.8 117 72.2 49.0
Cr 3.95 13.6 23.8 7.43 24.2 14.3 3.49 5.02 2.87 0.15 3.19 17.8 13.6 4.63 8.22 7.22 9.11 18.8
Co 2.82 2.05 2.78 0.92 1.25 2.81 2.92 3.70 0.71 0.44 1.22 0.40 4.90 3.11 5.92 6.01 3.55 2.17
Ni 4.79 7.68 11.3 3.92 5.94 7.41 5.73 4.00 2.69 1.57 4.61 5.57 13.9 9.09 5.51 5.20 22.1 11.2
Y 24.9 28.7 13.8 61.9 14.2 36.4 8.45 19.1 15.7 0.80 2.99 4.89 368 300 232 250 356 296
Nb 488 460 334 690 260 327 228 461 645 372 301 271 890 643 813 527 516 328
Ta 25.8 24.6 23.6 48.5 14.5 21.1 19.4 36.9 65.1 14.6 12.3 10.4 76.2 60.8 57.6 42.5 47.5 34.8
Zr 619 591 628 4693 1799 1311 1704 2410 1229 467 737 451 6769 6894 6887 6831 7374 7435
Hf 17.7 18.5 17.0 97.3 38.1 29.5 57.7 77.5 31.5 12.0 19.9 10.0 234 191 178 177 239 214
U 6.75 6.90 5.28 16.2 8.78 5.43 3.45 8.22 5.24 4.18 5.50 5.01 12.8 11.3 18.4 20.6 5.31 3.64
Th 51.4 64.8 12.5 44.6 15.2 36.2 27.2 42.4 55.6 15.2 13.3 11.9 45.0 27.6 34.5 24.1 8.92 7.51
La 110 138 54.3 209 17.5 116 262 234 550 9.39 12.1 11.7 284 244 195 236 157 147
Ce 183 304 121 376 38.8 262 531 493 1115 19.4 28.8 25.7 635 517 464 507 370 341
Pr 17.5 33.8 13.6 36.7 4.86 29.0 50.6 47.4 119 1.90 3.49 2.77 72.6 56.8 52.1 56.1 50.2 45.1
Nd 63.5 120 48.4 128 19.3 104 141 139 325 6.08 13.1 9.46 273 217 205 209 215 199
Sm 11.0 19.2 7.83 22.0 4.71 17.9 12.0 14.1 24.6 0.65 2.21 1.56 67.1 53.2 50.5 49.1 61.3 55.4
Eu 2.97 5.05 2.09 6.02 1.43 5.01 2.33 3.14 4.30 0.13 0.56 0.39 21.1 16.7 16.4 15.5 20.0 19.0
Gd 7.74 12.3 5.21 16.8 3.78 12.3 6.79 8.14 13.6 0.36 1.37 1.13 66.4 51.9 43.6 44.0 62.6 57.6
Tb 1.17 1.60 0.68 2.54 0.61 1.65 0.64 1.00 1.31 0.04 0.17 0.14 11.3 9.10 7.38 7.51 10.7 9.73
Dy 6.40 8.16 3.58 14.7 3.67 8.63 2.30 4.22 5.48 0.19 0.81 0.72 77.8 60.8 46.2 47.4 72.2 64.8
Ho 1.15 1.37 0.65 2.85 0.73 1.57 0.38 0.75 0.76 0.03 0.14 0.13 16.9 13.1 9.22 9.71 15.1 13.7
Er 2.71 3.05 1.55 7.37 1.90 3.78 0.99 2.05 1.77 0.08 0.34 0.32 45.6 36.0 23.9 25.5 41.1 36.6
Tm 0.36 0.41 0.22 1.14 0.28 0.53 0.21 0.38 0.27 0.01 0.05 0.05 6.60 5.31 3.51 3.74 5.79 5.31
Yb 1.73 2.19 1.23 5.97 1.60 2.97 1.72 2.76 1.55 0.07 0.42 0.29 37.5 29.4 18.7 20.0 32.8 29.6
Lu 0.24 0.30 0.19 0.82 0.22 0.40 0.36 0.53 0.23 0.01 0.08 0.04 5.17 4.13 2.45 2.74 4.51 4.01
Note. See Table 10 for the rock codes.
ARZAMASTSEV ET AL.: KOLA ALKALINE PROVINCE IN THE PALEOZOIC
Table 12. Weighted average chemical compositions of alkaline intrusions from the Kola Province
Calculated data Literature data
Alkaline ultrabasic intrusions Phonolites Kola Province Khibiny Lovozero Khibiny Lovozero Alkaline ultrabasic province
1 2 3 4 5 6 7 8
Si02 36.90 55.06 47.61 48.66 51.96 53.22 53.35 36.38
Ti02 2.68 0.96 1.63 2.10 1.61 1.05 0.91 3.22
A1203 7.20 20.53 15.38 17.32 15.67 21.26 17.62 7.94
Fe203 8.96 2.87 4.56 4.14 5.72 2.59 5.73 8.37
FeO 6.18 2.11 3.76 3.49 3.09 1.58 1.55 6.88
MnO 0.25 0.20 0.22 0.22 0.27 0.18 0.31 0.12
MgO 12.42 0.68 5.35 3.52 3.70 0.65 0.95 14.95
CaO 16.81 1.57 7.88 6.26 4.99 1.80 1.36 14.46
Na20 2.92 9.38 6.88 8.20 7.95 9.81 10.11 3.17
K20 1.82 6.46 4.70 5.21 4.50 6.52 5.20 1.52
p2o5 1.20 0.19 0.61 0.54 0.33 0.29 0.15 0.37
C02 1.76 0.00 0.70 0.22 0.10 0.14 0.04 1.80
H20 0.90 0.00 0.72 0.12 0.14 0.91 2.72 0.82
Total 100.00 100.00 100.00 100.00 100.00 100.00 100.00 100.00
Li 13.5 32.2 24.8 24.2 36.1 20 55 -
Rb 49.4 153.3 112.1 114.9 66.8 220 230 —
Cs 0.64 2.43 1.72 1.89 1.75 3.5 1.62 -
Sr 2094 1476 1728 1398 855 1100 610 1293
Ba 1116 578 797 629 389 1191 690 851
Sc 24.8 4.4 12.2 8.0 17.9 2.7 2.8 2.4
V 104.0 85.3 90.7 137.9 156.2 50 108 440
Cr 293.1 19.7 123.1 143.7 135.1 10 28 —
Co 42.5 3.03 17.2 16.9 18.3 12 5 150
Ni 242.5 6.82 102.2 106.7 77.2 45 12 360
Y 33.6 61.5 50.5 53.2 47.2 27 16 20
Nb 95.8 332.9 238.4 226.8 326.2 150 696 300
Ta 5.46 32.9 21.9 22.4 24.1 20 60 34
Zr 347 922 693 531 1824 640 3480 348
Hf 7.65 24.5 17.8 13.4 51.7 13 83 -
U 2.15 4.49 3.56 2.85 5.71 5 16 15
Th 8.51 19.0 14.9 23.4 24.9 14 35 90
La 131.3 192.0 167.7 206.8 162.3 130 481 -
Ce 249.3 328.4 296.7 322.8 335.9 200 860 —
Pr 27.4 38.6 34.1 39.3 35.3 20 - -
Nd 96.9 128.0 115.6 143.6 115.6 70 298 -
Sm 14.4 20.4 18.0 25.2 17.0 84 45 —
Eu 3.60 5.27 4.60 6.82 4.55 2.6 11 -
Gd 10.2 12.8 11.8 16.7 12.9 7.5 32 -
Tb 1.26 1.78 1.57 2.19 1.83 6 —
Dy 6.02 9.16 7.91 9.72 10.4 2.4 23 -
Ho 1.05 1.61 1.39 1.61 2.03 1.0 5 -
Er 2.42 3.96 3.34 3.75 5.25 1.1 14 —
Tm 0.32 0.52 0.44 0.47 0.77 - - -
Yb 1.83 2.97 2.51 2.81 4.46 1.6 10 -
Lu 0.26 0.41 0.35 0.39 0.65 - 1.8 -
Note. The chemical compositions of the alkaline ultrabasic intrusions (1), phonolites (2), Kola Province (3), Khibiny (4) and Lovozero (5) massifs were calculated taking into account the volumetric ratios of rocks in the intrusions to a depth of 22.5 km. The compositions of the average samples for Khibiny (“Khibiny General”) (6), Lovozero (7), and the province as a whole are given after Bussen and Sakharov [1972], Gerasimovskii et al. [1966], and Kukharenko et al. [1971].
Table 13. Concentrations (ppm) and partition coefficients of rare earth elements used in the model calculations
La Ce Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb Lu
Calculated average
composition for Kola Province 167.7 296.7 34.1 115.6 18.0 4.60 11.75 1.57 7.91 1.39 3.34 0.44 2.51 0.35
Composition of
primitive mantle 0.6139 1.6011 0.2419 1.1892 0.3865 0.1456 0.5128 0.094 0.6378 0.1423 0.4167 0.0643 0.4144 0.0637
Composition of
enriched mantle 1.8417 4.8033 0.7257 3.5676 1.1595 0.4368 1.5384 0.282 1.9134 0.4269 1.2501 0.1929 1.2432 0.1911
D0i 0.0000088 0.000019 0.000049 0.00009* 0.00045 0.00099* 0.0019* 0.00324 0.01* 0.00927 0.018* 0.027* 0.0366 0.05
D0px 0.0056 0.0058 0.006 0.007 0.0085 0.0078 0.011 0.011 0.015 0.019 0.021 0.025 0.032 0.042
Dcpx 0.049 0.07 0.12* 0.178 0.293 0.31* 0.34* 0.36* 0.38 0.387* 0.391* 0.395* 0.4 0.449
Dgarnet 0.0016 0.005 0.03* 0.052 0.25 0.4 1.00* 1.60* 2.2 2.90* 3.6 4.45* 5.3 5.8
Dspinel 0.0002 0.0002 0.0002* 0.0002* 0.0001 0.0002* 0.0002* 0.0002* 0.0002* 0.0002* 0.0002* 0.0002* 0.0012 0.0004
Damphibole 0.058 0.116 0.178 0.273 0.425 0.387 0.725 0.779 0.816 0.783 0.699 0.6* 0.509 0.645
Dphlogopite 0.030 0.034 0.033 0.032 0.031 0.030 0.030 0.03 0.03 0.032 0.034 0.04 0.042 0.046
Note. Primitive mantle composition is given after [Hofman, 1988]. Composition of enriched mantle is assumed as a threefold composition of the primitive mantle. Dai and
Dopx are given after [Beattie, 1994], Dcpx and Dgarnet are given after [Johnson, 1998; Salters and Longhi, 1999]; the data for Yb and Lu were calculated as averages from the
data reported by [Johnson, 1998], and [Prinzhofer and Allegre, 1985]; data for Airopftiftole are S?ven after White [1997].
* The values were calculated using the linear interpolations of the contents of neighboring rare earth elements.
ARZAMASTSEV ET AL.: KOLA ALKALINE PROVINCE IN THE PALEOZOIC
Table 14. Concentrations (ppm) and partition coefficients of the trace elements used in the model calculations
Rb Ba Th u K Nb Sr P Hf Zr Ti Y
Average concentrations calculated for the Kola Province 111.7 793.2 14.82 3.56 36530 238 1723 2892 17.77 692 8997 50.34
Primitive mantle composition 0.5353 6.049 0.0813 0.0203 258.2 0.6175 18.21 95.00 0.2676 9.714 1085 3.94
Enriched mantle composition 1.6059 18.147 0.2439 0.0609 774.6 1.8525 54.63 285 0.8028 29.142 3255 11.82
D0i 0.000044 0.000003 0.000052 0.00002 0.00017 0.00005 0.000063 0.00004 0.001 0.00068 0.0002 0.0098
Dopx 0.022 0.0067 0.0056 0.015 0.003 0.015 0.0068 0.01 0.021 0.004 0.1 0.014
Dcpx 0.0033 0.0022 0.014 0.013 0.0028 0.0081 0.095 0.2 0.2 0.119 0.34 0.412
Dgarnet 0.007 0.0007 0.014 0.0059 0.002 0.0538 0.0025 0.1 0.24 0.27 0.29 3.1
Dspinel 0.007 0.007 0.03 0.00001 0.0001 0.08 0.0001 0.0001 0.05 0.06 1.2 0.00001
Damphibole 0.437 0.282 0.016 0.001 0.35 0.197 0.184 0.001 0.638 0.3 1.5 0.634
Dphlogopite 3.06 1.09 0.1 0.1 2.0 0.088 0.081 0.001 0.5 0.6 0.9 0.03
Note. The primitive mantle composition is given after Hofman [1988]. The enriched mantle composition is taken as a threefold composition of primitive mantle. Dai and Dopx are given after Beattie [1994] and White [1997]; Dcpx is given after Johnson [1998], Salters and Longhi [1999], and White [1997]; Dgarnet, after Johnson [1998] and Salters and Longhi [1999]; Damphibole i after Irving and Frey [1984], Rollinson [1993], and White [1997].
ARZAMASTSEV ET AL.: KOLA ALKALINE PROVINCE IN THE PALEOZOIC
La Ce Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb Lu La Ce Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb Lu
Figure 8. Cliondrite-normalized REE distribution in the products of the partial (a) and fractional (b) melting of normal primitive mantle having a composition of spinel peridotite OI0.578 + Opxo.27 + Cpx0.n» + Splo.o;«- The thick line is the average composition of primary magmas in the Kola alkaline province, the shaded line denotes the compositions of the alkaline-ult.ramafic and phonolit.e series. The thin lines are the model compositions of the melts and complementary rest.it.es (broken lines) for the 0.1 10% degrees of melting. The normalizing factors used were after Evensen et al. [1978].
the melting of differently enriched mantle rocks of different, compositions showed that the generation of primitive magmas in the Kola Province had been favored by the critically low melting degrees of the rocks (0.3 0.5%) whose composition agreed with that, of phlogopit.e-bearing (± ampliibole) llierzolit.e at. a garnet, mantle depth (>2.8 GPa). The resulting melting degree («0.3%) agreed, for the given PT parameters, with the calculations modeling the melting of met.asomat.ized mantle during a mantle plume lithosphere interaction [White and McKenzie, 1995].
6.2. The Volume of the Paleozoic Magma Generation Zone in the Northeastern Baltic Shield
As a result, of our calculations, we estimated the total volume of magma generated during the time of Paleozoic t.ect.onomagmat.ic reactivation. The computed volume (15100±2700 km3) includes the magmat.ic systems of the Kliibiny (9100±1400 km3) and Lovozero (1600±250 km3) massifs, alkaline ultramafic intrusions (4000±1000 km3), and dikes (400±200 km3). Experimental data show that neplieli-nit.e melts of this type, enriched in incoherent, elements, could be generated at. the low degrees of mantle melting, not. higher than 3 5% [Edgar, 1987; McKenzie, 1984]. One of the main factors controlling the minimum volume of mantle melt, is the ability of the melt, to separate from the matrix, which mainly depends 011 the content, of volatiles [Maalue, 1998]. In the case of neplielinite melts, enriched significantly in H2O and CO2 [Schiano et al., 1998; Wyllie, 1995], the volume of
the mantle melt, can be as small as 1%. Proceeding from the calculated volume of the Paleozoic magma, the total volume of the partially molten mantle rocks could be 3 to 5 million sq. km with the melting degrees of 0.3% and 0.5%, respectively. It. is obvious that, these estimates of the volumes of the magma generation zone are minimal, because the calculation was made using the volumes of the melted mantle rocks, whose manifestations are recorded at. the level of erosion. At. the same time, taking into account, the unique features of geophysical anomalies produced by alkaline intrusions, whose identification helps to trace the occurrences of alkaline magmat.ism to the depth of the lower crust, base, we can suppose that, our calculations did not. include the magmas that, had not. reached the ground surface but. had been conserved in the zone of the Devonian magma generation.
The data available for the Kola Province show that, the zone of the lateral propagation of alkaline magmat.ism in the northeastern part, of the Baltic Shield is limited by a circumference with a diameter of about. 400 km, corresponding to a distance between the Sokli Massif in the west, and the Ivanovka Massif in the east. (Figure 1). However, the data available for the PT conditions of the formation of neplieli-nit.e magma, based 011 mantle xenolit.lis [Arzamastsev and Dalgren, 1993] and 011 the geophysical data for the position of the M discontinuity [The Structure of the Baltic Shield Lithosphere, 1993], suggest, the zone of Paleozoic magma generation to be a cylinder with a radius of 200 km. The lower limit, of the melting region varies from 80 to 120 km depending 011 the melting degree (0.3% to 0.5%), this depth interval corresponding to the PT conditions of mantle garnet, llierzo-
0.01 1 1 ' • 1 1 ' ^ i i i i i i i i i i i » i i i
La Ce Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb Lu La Ce Pr Nd Sm Eu Gd Tb Dy Ho Er Tm Yb Lu
RbBaThU K Nb La Ce Sr Nd P Hf Zr SmTi Tb Y RbBaTh U KNbLaCeSrNdP Hf Zr SmTi Tb Y
Figure 9. Cliondrite-normalized trace element, distribution in the products of the partial (a, c) and fractional (b, d) melting of normal primitive mantle having a composition of garnet, peridotite Olu.ou + Opxo.iH) + Cpxo.ox + Grto.12. The thick line is the average composition of primary magmas in the Kola alkaline province, the shaded line denotes the compositions of the alkaline-ult.ramafic and plionolit.e series. The thin lines are the model compositions of the melts and complementary rest.it.es (broken lines) for the 0.1 10% degrees of melting. The dotted lines show the composition of depleted mantle after McKenzie and O’Nions [1991]. The normalizing factors used were after Evensen et al. [1978] for these and after Hofmann [1988] for the other elements.
lit.e (Figure 13). The position of the lower boundary of the magma generation zone for lieplielinite magma is controlled by the PT values for a graphite diamond phase transition, which corresponds to a depth interval of 140 160 km under the Baltic Shield [Kennedy and Kennedy, 1976; Kukkonen and Peltonen, 1999].
These estimates agree with the data on the sizes of mantle plumes [Leitch et al., 1998] whose periods of igneous activity lasted 10 to 30 Ma. In particular. Grachev [2000b] showed that, the calculated size of the Kola Paleozoic plume
was roughly similar to the products of plume magmat.ism in Greenland, Columbia, and Arabia.
7. Conclusion
The results of this study of the Paleozoic magmat.ism in the northeastern part, of the Baltic Shield, based on geo-
Rb Ba Th U K Nb La Ce Sr Nd P Hf Zr Sm 71 Tb Y Rb Ba Th U K Nb La Ce Sr Nd P Hf Zr Sm Ti Tb Y
Figure 10. Cliondrite-normalized trace element, distribution in the products of the partial (a, c) and fractional (b, d) melting of enriched met.asomat.ized mantle having a composition of ampliibole-bearing spinel peridotite Olo.5» + Opxu.21 + Cpxo.uj + Splu.ua + Ampliu.us. The thick line is The average composition of primary magmas in the Kola alkaline province. The shaded line denotes the compositions of the alkaline-ult.ramafic and plionolite series. The thin lines are the model compositions of the melts and complementary rest.it.es (broken lines) for the 0.1 5% degrees of melting. The normalizing factors used were after Evensen et al. [1978] for these and after Hofmann [1988] for the other elements.
physical and geochemical data and model calculations, can be summarized as follows.
1. The magma generated during the time of the Paleozoic t.ect.onomagmat.ic reactivation had a volume of 15,000±2700 km3. The total volume of mantle rocks melted during a period of 380 360 million years might, have been 3 to 5 million sq. km, which corresponds to a region of the reactivated mantle as thick as 40 km under the entire Kola area involved in alkaline magmat.ic activity.
2. The calculated average weighted composition of the primary magmas in the Kola Province showed its similarity with the average composition of olivine melanephelinit.e and agreed with the compositions of the most, primitive magmas
found in the volcanic rocks and small intrusions of the region. The plionolite magma was found to have been enriched in Nb, Ta, Zr, and Hf, whereas no positive HFSE anomaly was found for the primitive alkaline-ult.ramafic magmas of the region.
3. The modelling of the trace element, behavior during the melting of differently enriched mantle rocks having different, mineral compositions showed that, (a) the primary magmas of the Kola Province could not. be derived from the primitive mantle even at. critically low melting degrees; (b) the generation of alkaline magma at. the PT conditions of spinel stability is highly improbable; (c) the primitive magmas could be produced in the province as a result, of the low melting de-
Figure 11. Cliondrite-normalized trace element, distribution in the products of the partial (a, c) and fractional (b, d) melting of enriched met.asomat.ized mantle having a composition of ampliibole- and plilogopit.e-bearing garnet, peridotite Olu.s» + Opx0.2o + Cpx0.08 + Grto.os + Phlog0.02 + Amph0.0;l. The thick line is the average composition of the primary magmas of the Kola alkaline province, the shaded line denoting the composition of the alkaline-ult.ramafic and plionolit.e series. The thin lines are the model compositions of the melts and complementary rest.it.es (broken lines) for the 0.1 5% degrees of melting. The normalizing factors used were after Evensen et al. [1978] for these and after Hofmann [1988] for the other elements.
gree of the rocks (0.3 0.5%), under the conditions of a garnet, mantle depth, whose enrichment, was 3 times higher than the average contents of incompatible elements in primitive mantle; (d) also involved in melting were the mantle rocks with a composition of plilogopit.e-bearing (± ampliibole) garnet, llierzolit.e.
Acknowledgments. Wo are grateful to A. B. Vrevskii and V'. A. Matrenichev (Institute of Precambrian Geology and Geochronology, Russian Academy of Sciences) for their useful consultations on the development of computer models for mantle melting. Thanks are also due to Yu. A. Balashov for his critical comments and valuable suggestions concerning the planning of this study. This work was supported by the Russian Foundation for Basic Research (grant 00-05-64229) and by NATO grant 974904.
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(Received July 19, 2001)