2. Geological setting

The TCC intrudes the Namaqua metamorphic upper crustal basement. Detailed geological mapping outside the immediate area of the carbonatite is tightly regulated within the Sperrgebiet (‘restricted area’); hence, it is only possible to present an overview of the regional geological setting. In this area, the Namaqua Province comprises pre-tectonic migmatitic granulite-facies metasediments and metabasites of the Garub Group (Jackson, Reference Jackson1976), syn- to late-tectonic granitic gneisses (with subordinate aluminous metasediments, metapsammites, mafic granulite and calc-silicate) and post-tectonic leucogranites and pegmatites at 1004 ± 6 Ma (Diener et al. Reference Diener, White, Link, Dreyer and Moodley2013).

Following a period of comparative quiescence, a number of alkaline to highly alkaline intrusive bodies of Late Cretaceous to early Tertiary age were emplaced in southern Namibia (Miller, Reference Miller2008), including the TCC and spatially associated Dicker Willem, Keishöehe and Kaukasib carbonatite complexes (Fig. 1). The large Dicker Willem complex is interpreted as a high-level, sub-volcanic carbonatite (Cooper & Reid, Reference Cooper and Reid1991, Reference Cooper and Reid2000). It has a K–Ar mica and Rb–Sr mica-calcite isotopic age of 49 ± 1 Ma (Reid et al. Reference Reid, Cooper, Rex and Harmes1990), and the spatial relationship between the four carbonatites is taken to imply a common age (Verwoerd, Reference Verwoerd1993).

The closest alkaline complex to the TCC is the recently described Tsirub nephelinite intrusions, ∼20 km south of Dicker Willem and ∼35 km ENE of the TCC (Nakashole et al. Reference Nakashole, le Roex and Reid2020). The extent to which the carbonatites and alkaline complexes lie on a structural lineament (the NE-striking Luderitz lineament), possibly created during a period of Gondwanaland rifting and crustal extension, is uncertain (Reid et al. Reference Reid, Cooper, Rex and Harmes1990; Woolley, Reference Woolley2001; Alfonso et al. Reference Alfonso, Ben Masour, O’Reilly, Griffin, Salajeghegh, Foley, Begg, Selway, Macdonald, Januszczak, Fomin, Nyblade and Yang2022). Nevertheless, other anorogenic alkaline provinces aligned along ENE-striking zones in Namibia are suggested to be related to pre-existing crustal zones of weakness (Reid, Reference Reid1991; Smithies & Marsh, Reference Smithies and Marsh1996; Homrighausen et al. Reference Homrighausen, Hoernle, Geldmacher, Wartho, Hauf, Portnyagin, Werner, van den Bogaard and Garbe-Schönberg2018). It has been suggested that emplacement of carbonatites and kimberlites in southern Africa is related to melting of the sub-continental lithospheric mantle initiated by passage of the African plate over a mantle plume (Hartnady & le Roex, Reference Hartnady and le Roex1985). In this context, formation of the southern Namibian carbonatites appears to be related to the passage of the Vesma hot-spot track that first emerged in Late Jurassic/Early Cretaceous times beneath the East African rift, tracked SW, before passing beneath the TCC ∼40–50 Ma, and now lies beneath the South Atlantic (Alfonso et al. Reference Alfonso, Ben Masour, O’Reilly, Griffin, Salajeghegh, Foley, Begg, Selway, Macdonald, Januszczak, Fomin, Nyblade and Yang2022).

3. Local geology and structure

The exposed portions of the TCC stand ∼120 m above the surrounding sand and calcrete covered plains (Fig. 2a). The basement rocks of the Namaqua Metamorphic Province are exposed in gullies radiating from the carbonatite complex. The basement consists predominantly of strongly foliated, biotite-quartz-feldspar gneiss, with subordinate pegmatite, quartz schist, quartzite and amphibolite present throughout the wider area.

Fig. 2. Twyfelskupje carbonatite complex (TCC). (a) The direction of view is approximately SSE. The outcrops extend to ∼120 m above the desert plain. (b) Aerial view of the TCC (scale bar is 500 m).

Dicker Willem contains small exposures (0.12 % by area) of ijolite, but no other occurrences of genetically linked silicate magmatic rocks (Cooper & Reid, Reference Cooper and Reid2000). However, the TCC (as well as Keishöehe and Kaukasib) is a member of the ∼20 % of carbonatite complexes worldwide (Woolley & Kjarsgaard, Reference Woolley and Kjarsgaard2008) that do not have any exposures of associated volcanic or plutonic alumino-silicate rocks within or surrounding the complex.

The TCC forms a tectonically undeformed circular group of hills with a diameter of ∼1 km. Eight areas of the complex that crop out are recognized and designated TK1A and B, and TK2 through to TK7 (Fig. 2b). The outcrops form a central zone (TK1A and B, and TK2) and a peripheral zone occupied by TK3 through to TK7.

The TCC geology is summarized in Figure 3. The central zone consists of two distinct structural units: (1) sub-vertically banded, pale coloured, linear (TK1A) and arcuate (TK1B) carbonatite plugs; and (2) sub-vertical to steeply dipping, commonly darker coloured, irregularly oriented, and sometimes intersecting, carbonatite dykes (TK2). The dykes form a stockwork surrounding the TK1B outcrop area. Structurally, the peripheral zone is represented by shallow-dipping, darker coloured, banded, carbonatite cone sheets (TK3–TK7). In the outlying areas of the TK2 dyke stockwork, several ∼1 m thick, vertical, SE-trending dykes cut the shallow-dipping TK6 cone sheet. The absence of cone sheet outcrops on the NE side of the central zone suggests the complex plunges to the NE, and that any cone sheets on this side of the complex may have been removed by erosion.

Fig. 3. Simplified geological map of the Twyfelskupje carbonatite complex.

The sub-vertically banded, pale grey carbonatites form a linear plug at TK1A and an arcuate plug at TK1B, adjacent to the NE edge of TK2. The dyke stockwork extends for ∼450 m in an E–W direction, and ∼380 m N–S, with the density of the TK2 dykes within the stockwork increasing in the area of the elevated TK2 outcrop.

The peripheral zone occupied by the TK3 through to TK7 outcrops forms a third, distinct structural unit. Each outcrop area represents an individual cone sheet of varying thickness and orientation, which together form part of the overall peripheral cone sheet system. The structurally lower TK6 cone sheet has a thickness of a few metres, and forms an arched structure plunging ∼10° to the north. However, the base of the cone sheet undulates and locally displays dips of up to 30°. Units of Namaqua basement up to ∼1 m thick are intercalated between individual layers of the TK6 cone sheet, and increase in thickness towards the top of the cone sheet. The TK6 cone sheet is overlain by the TK5 cone sheet to the west and the TK7 cone sheet to the east. The TK5 sheet resembles an asymmetric synclinal structure and plunges ∼10° to the north. The western limb of the syncline is ∼30 m thick, while the eastern limb is only a few metres thick. The thinner eastern limb of the TK5 synclinal cone sheet overlies the western limb of the TK6 arch. The TK6 and TK5 cone sheets are separated by a unit of Namaqua basement a few metres thick. The TK5 cone sheet extends to outcrop TK4, and structural continuity of individual layers of carbonatite between the two cone sheets is seen in the lowest point of the ridge between them. Intercalations of Namaqua basement up to 2 m thick occur near the base of the TK5 cone sheet. The cone sheet exposed over TK3 is separated from, and appears slightly structurally higher than, the TK4 cone sheet. The footwall contacts of the TK3 and TK4 cone sheets have a shallow to sub-horizontal dip. Cone sheet TK7 is ∼30 m thick, dips ∼25° to the NE and forms the most prominent hill within the TCC. The TK7 cone sheet is also structurally higher than the TK6 cone sheet, and they are separated by a few metres of Namaqua basement. The TK5 and TK7 cone sheets may have been structurally continuous prior to denudation, which resulted in the structurally lower TK6 cone sheet being exposed over the N-plunging arch between TK5 and TK7. The TK3, TK4 and TK7 cone sheets dip in a radial direction and define a common apex plunging NE (Fig. 3). The dip of the banding within the carbonatites parallels the footwall contact, and progressively increases upwards through the cone sheets to peak at ∼35° near the hanging wall, implying that the cone sheets steepen and thin down-dip towards a central common apex. The carbonatite layers at the base of both the TK5 and TK7 cone sheets transgress to higher structural levels within the basement gneisses, with vertical transgressions of a few metres taking place over a lateral distance of <10 m.

The basement is not well exposed around the TCC; hence, it is difficult to assess the extent of alteration by fluids derived from the carbonatite. In addition, throughout southern Namibia the Namaqua basement underwent at least three phases of deformation under high-grade metamorphism prior to emplacement of the TCC (Jackson, Reference Jackson1976). Hence, it is also difficult to differentiate regional structural deformation from that associated with emplacement of the carbonatite. Basement rocks in direct contact with the carbonatite, especially in the footwall of the cone sheets, are brecciated and display drag folds and small faults and shears with <1 m displacements. Small apophyses of carbonatite extend from the footwall contact for a few tens of centimetres into the basement, where fenitization is marked by the presence of riebeckite (Fig. 4a).

Fig. 4. Field photographs of the TCC (see text for details). (a) Basement contact at the base of the TK6 cone sheet, showing apophyses of carbonatite extending into the basement. Diameter of lens cap for scale is 6 cm. (b) Block of layered fluorcarbonate mineralization in carbonatite matrix in TK1A. (c) Intensely folded fluorcarbonate layers in TK1B. (d) Brittle and ductile deformation in fluorcarbonate layers in TK1A. Length of hammer for scale is 33 cm. (e) Euhedral fluorcarbonate grains (3–4 mm) and fine-grained magnetite in carbonatite matrix in TK1A. Horizontal field of view ∼2 cm. (f) Fine-scale banding in TK5 parallel to basement contact.

The geological (and other) features of the different outcrops are summarized in Table 1.

Table 1. Characteristic features of TK structural components

4. Mineralogical methods and results

4.a. Optical and SEM microscopy

A Carl Zeiss LEO1450VP scanning electron microscope (SEM) (School of Ocean and Earth Science, University of Southampton) was used to capture high-resolution backscattered electron (BSE) images (Fig. 5). Elemental maps were also produced to assist mineral identification in advance of semi-quantitative microanalysis. Elemental analyses were calculated using oxygen stoichiometry, and all data normalized to 100 % to allow for easier comparison of the data. Elemental mapping and semi-quantitative microanalyses were undertaken using energy dispersive spectrometry (EDS), with an Oxford Instruments X-Act 10 mm² area Silicon Drift Detector, coupled with Aztec Energy software. The SEM operated at 20 kV, with a focal length of 20 mm.

Fig. 5. Backscattered electron images of TCC samples. (a) Fibro-radial aggregates of fluorcarbonate (from TK1). (b) Radiating rhythmic alternations of barite with calcite and Fe–Mn-oxide (from TK3). (c) Bladed aggregates of apatite intergrown with carbonate and Fe- and Fe–Mn-oxides (from TK2). (d) Monazite overgrowing and including apatite and carbonate (from TK2). (e) Colloform banded, concentric assemblages of fluorite and Mn-oxide (from TK3). (f) Celestine overgrowing barite and fluorcarbonate (from TK1).

Optical microscopy of the carbonatites reveals a fine-grained (50–200 μm) allotriomorphic-textured groundmass of calcite or dolomite grains overgrown by irregular-shaped aggregates of equally fine-grained yellow to brown REE fluorcarbonate, and Fe-oxide. The carbonate groundmass may pseudomorph earlier coarser-grained rhombic primary calcite (up to 1 mm grain size), or it may occur as very fine-grained recrystallized carbonate, intergrown with mainly iron oxides, barite and fluorcarbonates. The carbonate groundmass may also be replaced by rhythmically zoned and colloform banded intergrowths of fine-grained calcite and haematite, or calcite and barite, with the haematite displaying topotactic replacements along the calcite cleavage. Matrix-supported carbonatite micro-breccias containing rounded, milled quartz and perthite basement clasts, as well as carbonatite and carbonatite breccia, also occur as inclusions in the central zone calcio-carbonatites.

The fine-grained fluorcarbonate aggregates are composed of masses of acicular needles, which typically occur as plumose to fibro-radial aggregates that vary in size from a few micrometres to a few millimetres. Narrow sub-millimetre-scale veinlets containing quartz and carbonate cut the carbonate–haematite–fluorcarbonate mineral assemblage, whereas the strongly silica altered carbonatites contain quartz veins and segregations up to a few millimetres in size. The quartz occurs as coarse, strained grains, or crystalline grains rimmed by radial overgrowths of microcrystalline quartz.

Plumose to fibro-radial aggregates of fluorcarbonate minerals are most abundant in the central zone carbonatite (TK1) and are prominent in BSE images (Fig. 5a), with individual fluorcarbonate needles varying from <1 µm to a few micrometres wide, and 20 to 60 µm long. Typical plumose, fibro-radial aggregates of fluorcarbonate minerals are 50 to 300 µm in diameter, and individual needles may be curvilinear.

The carbonatites contain calcite, ankerite, REE fluorcarbonates, barite, apatite, monazite, fluorite, celestine, pyrochlore, magnetite and Fe–Mg silicates. The barite is present in the central zone and cone sheets, where the morphology varies from coarse grained (up to 1.5 mm) within the fine-grained carbonate groundmass, to finer-grained barite rimming the coarse-grained variety, or alternatively radiating rhythmic alternations with calcite and Fe–Mn-oxide (Fig. 5b). Barite also occurs as fine grains intimately associated with the fluorcarbonate segregations.

Apatite is most abundant in the central zone dyke stockwork (TK2), and where present it may constitute up to 10 modal % in the form of irregular-shaped masses, or as bladed aggregates up to 300 μm across, intergrown with carbonate (Fig. 5c). Monazite is also most abundant in TK2, where it typically occurs as irregular-shaped masses up to a few hundred micrometres across, which overgrow and include apatite and carbonate (Fig. 5d). The monazite also forms rims to the plumose aggregates of fluorcarbonate, or more rarely as 5–10 μm sub-rounded grains that overgrow the carbonate groundmass and the plumose fluorcarbonate aggregates. Fluorite forms early euhedral to anhedral grains up to 500 μm across in the carbonate groundmass, and is overgrown by barite and fluorcarbonate. Late-stage, colloform banded, concentric assemblages of fluorite and Mn-oxide (up to 200 μm) overgrow early fluorite (Fig. 5e) and are most prominent in the cone sheets (TK3 to TK7). Celestine occurs throughout the TCC as anhedral grains (up to 50 μm) which overgrow barite and fluorcarbonate (Fig. 5f).

Orthomagmatic constituents of the carbonatite include pyrochlore, various Fe–Mg silicates and magnetite. Pyrochlore is an accessory constituent, which occurs in the TK1A central zone calcio-carbonatite plug as interstitial, euhedral grains typically up to 20 μm (Fig. 5a). The presence of Fe–Mg silicate phases is typical of carbonatites and can account for >10 wt % SiO₂ in magnesio-carbonatites elsewhere (Gittins et al. Reference Gittins, Harmer and Barker2005), but the silicates at the TCC are rare accessory constituents with a grain size typically <10 μm. Indeed, most of the bulk-rock silica within the carbonatites results from quartz veining and vug filling associated with late-stage hydrothermal silica alteration.

Magnetite forms euhedral to anhedral grains (typically 0.5 to 1 mm). Colloform and banded textures identified in BSE images result from variations in abundance of Fe and Mn, and reflect late-stage alteration of early (magmatic) magnetite. The magnetite may be rimmed by barite, or exist as alternations of barite and magnetite. The magnetite also contains Cr, Zn, Pb and Cu (with the latter having concentrations of up to 4 wt %), and most base metals reported in the bulk whole-rock geochemistry are sequestered within magnetite, martite and other Fe- and Mn-oxides.

Metasomatic alteration of the Namaqua basement associated with fenitization is mainly restricted within and adjacent to veins, and pervasive alteration is limited. Biotite-bearing quartz feldspar gneisses are altered to sodic syenite fenites.

5. Geochemical methodology

Continuous channel samples (∼10 cm deep, ∼5 cm wide) across the TCC normal to the banding provided a representative sample suite.

Samples were prepared at the ALS laboratory in Swakopmund by ALS method PREP-31 (crush sample until at least 70 % is less than 2 mm, then riffle split off 250 g, and finally pulverize the 250 g split until at least 85 % is less than 75 microns). REE and trace-element analysis of lithium-borate flux of the pulps was undertaken at the ALS laboratory in Vancouver by inductively coupled plasma mass spectrometry (ICP-MS), with a precision of ±5 % (ALS method ME-MS85). High REE concentrations (Ce >10 000 ppm, La >10 000 ppm, Nd >10 000 ppm, Pr >1000 ppm and Sm >1000 ppm) were reanalysed at higher dilution by ICP atomic emission spectrometry (ICP-AES; ALS method ME-OGREE). Major oxides were analysed by ICP-AES on the same fusion products (ALS method ME-ICP06).

Thirteen field duplicates were included in the 295 channel samples collected at the TCC, and 40 Certified Reference Material (CRM) samples, supplied by Ore Research & Exploration in Melbourne, were included in the submission (20 OREAS 22d blanks and 20 OREAS 463 REE standards). The OREAS 463 REE standard is a supergene carbonatite REE–Nb ore with a total rare earth oxide (REO) content of 2.08 % that is a matrix-matched reference material prepared and certified by Ore Research & Exploration (https://www.oreas.com/crm/oreas-463). The values obtained for the submitted standard agreed with the certified values of CeO₂, La₂O₃, Nd₂O₃ and Pr₆O₁₁ (0.810 wt %, 5824 ppm, 4295 ppm and 1212 ppm, respectively) within analytical uncertainty.

Laser-ablation ICP-MS was used to determine REE and trace-element concentrations in REE-rich minerals and carbonates. The analyses were performed on 200 μm thick polished sections with a Thermo Scientific Element XR high-resolution ICP-MS attached to a New Wave Research 193 nm ArF laser ablation system with a standard ∼30 cm³ cell and 100 % He (mixed with Ar and N₂ after the cell) at the University of Southampton. The instrument was calibrated with the NIST-610 glass standard. The BCR-2 and BHVO-1 standards were analysed at the start and end of the run, and the REE concentrations were consistently within 10 % of the certified values (Kent et al. Reference Kent, Jacobsen, Peate, Waight and Baker2004). The laser was focused to a 25 mm spot with a fluence of ∼5 J cm⁻² and a 4 Hz repetition rate.

All radiogenic isotope analyses were also carried out at the University of Southampton. Sr isotopes were measured by thermal ionization mass spectrometry (TIMS), and Nd and Pb isotope ratios were measured by multi-collector ICP-MS using the methods of Ishizuka et al. (Reference Ishizuka, Taylor, Yuasa, Milton, Nesbitt, Uto and Sakamoto2007). ⁸⁷Sr/⁸⁶Sr data were normalized to ⁸⁶Sr/⁸⁸Sr of 0.1194. During the course of the study, Sr standard NIST SRM 987 was measured as 0.710247 ± 10. ¹⁴³Nd/¹⁴⁴Nd data were normalized to ¹⁴⁶Nd/¹⁴⁴Nd of 0.7219. Measurement of the La Jolla Nd standard gave a value of 0.511846 ± 5. Pb standard NBS 981 gave results of 16.9403 ± 27 for ²⁰⁶Pb/²⁰⁴Pb, 15.4973 ± 21 for ²⁰⁷Pb/²⁰⁴Pb and 36.7169 ± 66 for ²⁰⁸Pb/²⁰⁴Pb.