1. Introduction
The core part of the Central Asian Orogenic Belt (CAOB, also called the Altaid Orogenic Belt) is a complex collage of island arcs, continental blocks and fragments of oceanic crust that amalgamated during Palaeozoic–Mesozoic time (Fig. 1). Several mutually contradictory plate tectonic interpretations have arisen since the 1990s (e.g. Coleman, Reference Coleman1989; Heinhorst et al. Reference Heinhorst, Lehmann, Ermolov, Serykh and Zhurutin2000; Zhang et al. Reference Zhang, Ai, Li, Rubatto and Song2007; Windley, Alexeiev & Xiao, Reference Windley, Alexeiev and Xiao2007; Xiao, Han & Yuan, Reference Xiao, Han and Yuan2008; Zhu et al. Reference Zhu, Guo, Song, Zhang and Gu2009; Han et al. Reference Han, He, Wang and Guo2011; Wilhem, Windley & Stamp, Reference Wilhem, Windley and Stamp2012). Zonenshain, Kuzmin & Natapov (Reference Zonenshain, Kuzmin and Natapov1990) suggested that the ophiolites of Central Asia represent the subducted crust of the Palaeo-Asian Ocean that separated east Europe, Siberia and Gondwana during the end of Neoproterozoic time. This interpretation was based on the assumption that most ophiolites were formed during late Precambrian–early Cambrian time and are therefore older than the spatially associated magmatic arcs. However, early Palaeozoic conodonts occur in most ophiolites of Kazakhstan, indicating a synchronicity of magmatic arcs and ophiolites and suggesting that the CAOB hosts relics of the former oceanic back-arc rather than truly oceanic basins (Yakubchuk, Reference Yakubchuk2004). Sengor, Natal’in & Burtman (Reference Sengor, Natal’in and Burtman1993) suggested that Precambrian crustal blocks and early–middle Palaeozoic turbiditic units could originally constitute the basement and accretionary wedges of only two magmatic arcs (Kipchak and Tuva–Mongol). This model implies that a subduction zone existed along the southern margin of the Siberian craton throughout Palaeozoic time, producing a vast complex of arc and subduction–accretion material including scraped-off ophiolitic fragments at the front of seawards-migrating magmatic fronts. This would indicate a steady-state subduction–accretion over a prolonged period of time. In contrast, many other researchers (Zhang & Huang, Reference Zhang and Huang1992; Mossakovsky et al. Reference Mossakovsky, Ruzhentsev, Samygin and Kheraskova1994; He et al. Reference He, Li, Jia and Zhou2001; Khain, Bibikova & Salnikova, Reference Khain, Bibikova and Salnikova2003; Xu, He & Li, Reference Xu, He and Li2006; Zhang et al. Reference Zhang, Xiao, Han, Mao, Ao, Guo and Ma2011; Yang et al. Reference Yang, Li, Santosh, Yang, Zhang and Tong2013; Zhu et al. Reference Zhu, Chen, Xu, Qiu and An2013b ) have identified distinct ophiolite belts in the core part of the CAOB, interpreted as discrete suture zones between tectonic blocks. These authors are in favour of a model of punctuated accretion by collision and closure of multiple ocean basins now marked by ophiolitic sutures.
These controversial interpretations have encouraged the study of ophiolitic suites in the core part of the CAOB in order to provide new constraints on this issue. As a major component of the core part of the CAOB, west Junggar, located south of the Tajin–Tarbahatai–Kujibai–Honguleleng ophiolitic belt (TTKH; Fig. 1b), is considered to be a Palaeozoic orogenic belt resulting from the convergence of the Siberian and Kazakhstan–Junggar plates (Kwon, Tilton & Coleman, Reference Kwon, Tilton and Coleman1989; Zhu et al. Reference Zhu, Chen, Xu, Qiu and An2013b ). Several ophiolite mélanges occur in this region (Fig. 1c): the Tangbale ophiolite mélange to the SW; the Darbut–Sartohay ophiolite mélanges in the NE; and the newly discovered Baijiantan–Baikouquan ophiolitic mélanges in the east. Blueschist in the Tangbale ophiolitic mélange was dated at 458–470 Ma (40Ar/39Ar on sodium amphibole; Zhang, Reference Zhang1997). The Darbut–Sartohay ophiolite belt was dated as being of Early Devonian age, based on radiolarian fossils in chert (Feng, Reference Feng1986). Zircons separated from metagabbro in the Darbut–Sartohay ophiolite mélange were dated at 391 Ma (Gu et al. Reference Gu, Li, Zhang, Tong and Wang2009) and 426 Ma (Chen & Zhu, Reference Chen and Zhu2011).
This paper focuses on the petrology and geochemistry of the Baijiantan–Baikouquan ophiolite mélanges. We examine comprehensive geological, petrographic and geochemical datasets, discuss pressure–temperature (P–T) conditions for metamorphic evolution of the ophiolitic mélanges based on thermodynamically calculated P–T pseudosections for garnet amphibolite and interpret the lithological characteristics of west Junggar in a subduction– accretion scheme.
2. Geology
The original structures of ophiolitic mélanges in west Junggar have been deformed due to various late Palaeozoic geological events. Nevertheless, detailed field observations can be used to reconstruct the stratigraphic sections of most ophiolitic mélanges; we describe two distinct ophiolitic sequences. The Ordovician Tangbale ophiolitic mélange has a curved shape (Fig. 1c). The ophiolitic units are generally in contact with metamorphosed immature terrigenous sedimentary rocks of Silurian age along faults; these are locally uncomformably covered by early Silurian terrigenous detrital sedimentary rocks. Stratigraphic sections of ophiolites are reconstructed from base to top as follows: (1) ultramafic units consisting mainly of serpentinite with blocks of harzburgite, dunite and lherzolite, the main matrix of the ophiolitic mélange; (2) gabbro locally cross-cut by mafic dykes; (3) volcanic rocks consisting of altered basaltic lavas, pillow basalt, volcanic agglomerate and tuff; and (4) chert containing Middle Ordovician radiolaria grades upwards into turbidites at the top.
The Baijiantan–Baikouquan ophiolitic mélanges (Fig. 1c) consist of abyssal radiolarian chert interlayered with tuff, metabasaltic pillow lava with vesicular structure, metagabbro, spinel-bearing dolomite marble and serpentinized lherzolite and/or spinel-bearing serpentinite. The ophiolite units have been strongly deformed and weathered (Fig. 2a). A geological section shows the relationship among different rock units across this ophiolitic mélange (Fig. 2b). Dolomite marble, present as bodies from a few decimetres to hundreds of metres in size, are intermingled with ultramafic units (Fig. 2c, d); ultramafic blocks occur in dolomite marble as relics (Fig. 2d) and one large dolomite marble lens marks the south boundary of this ophiolitic mélange. The abyssal radiolarian chert and tuffs are strongly deformed, with microfossils in the Baijiantan region indicating that the palaeo-ocean closed during the Late Ordovician period (He et al. Reference He, Liu, Zhang and Xu2007). The ophiolitic mélanges were covered by Devonian – lower Carboniferous volcanic-sedimentary rocks consisting mainly of sandstone, tuffaceous sandstone, siltstone, basalt, tuff and volcanic breccia (Zhu et al. Reference Zhu, Yan, Ma and Lehmann2011). The northern part of this ophiolitic mélange is covered by chert, siltstone and turbidite with tuff; metagabbro, marble and lherzolite lenses are randomly present in the serpentinite matrix.
The ophiolitic mélange in the Baikouquan region is restricted to a narrow zone bounded by faults. Strongly deformed chert and siltstone are present along the south boundary whereas the north boundary is a contact zone (Fig. 3a) between foliated basaltic rocks and early Carboniferous volcanic breccia, the latter unaffected by metamorphism or deformation. The central part of this ophiolitic mélange consists of serpentinite matrix with metagabbro and amphibolite lenses (Fig. 3b); most metagabbro lenses are located along the boundary between foliated basalt and serpentinite. Deformed basalt and chert cover the serpentinite.
Pre-Devonian pillow basalts found in the western mountains of Karamay city adjacent to the Baijiantan ophiolitic mélange preserve typical ocean-island-basalt- (OIB-) like geochemical signatures (Zhu, Xu & Wei, Reference Zhu, Xu and Wei2007); they are unlikely to be related to the ophiolites. These volcanic rocks differ from the Carboniferous rocks covering ophiolitic mélange in western Junggar, which are also considered to be unrelated to the ophiolites (An & Zhu, Reference An and Zhu2009; Zhu et al. Reference Zhu, An, Xu, Guo, Xia, Xiao, Zhang, Lin, Qiu and Wei2013a ).
3. Analytical methods
The compositions of mineral phases in polished thin-sections were analysed with a Cameca SX100 electron probe microanalyser (EPMA) at the University of Stuttgart. This EPMA, equipped with five wavelength-dispersive spectrometers, was used to determine the contents of Na, Mg, Al, Si, K, Ca, Ti, Cr, Mn, Fe and Ba. Counting times were 20 s at the peak and on the background. We used synthetic and natural minerals, glasses (e.g. Ba glass for the BaLα1-peak) and pure oxides as standards. An acceleration voltage and beam current of 15 kV and 15 nA were used; beam diameter was c. 5 μm but also 1–2 μm in the case of small mineral grains. The energy-dispersive system was used to identify minerals, and the compositions of representative major minerals are listed in the Supplementary Tables available at http://journals.cambridge.org/geo.
Zircons were hand-picked under a binocular microscope, and cathodoluminescence (CL) images obtained using a CAMECA SX-50 microprobe. Zircons were mounted in epoxy resin together with chips of the zircon standard TEMORA in the Beijing SHRIMP (sensitive high-resolution ion microprobe) Centre, Chinese Academy of Geological Sciences. The mount was ground down and polished so that the zircon interiors were exposed; zircon was photographed in reflected and transmitted light and under CL using a CAMECA SX-50 microprobe (accelerating voltage 10 kV, beam current 109 mA). The mount was then cleaned and gold-coated. Isotopic analyses were performed with the SHRIMP II of the Beijing SHRIMP Centre (analytical procedures outlined by Williams, Reference Williams, McKibben, Shanks and Ridley1998). Prior to each analysis, the surface of the analysis site was pre-cleaned by rastering of the primary beam for 2–3 min to reduce or eliminate surface common Pb. The reduced 206Pb/238U ratios were normalized to 0.0668, which is equivalent to the adopted age of 417 Ma for zircon standard TEMORA. Six scans through the critical mass range were made to collect data, giving a slightly elliptical spot size of c. 25–30 μm. Common-Pb corrections were applied using the 204Pb-correction method. Errors of individual analyses are given at the 1σ level and are based on counting statistics; errors of pooled analyses are reported at the 2σ confidence interval. The analytical data (Table 1) are graphically presented on conventional concordia diagrams.
Whole-rock samples were ground in an agate mill, after careful washing in distilled water and drying. Major elements were measured by an X-ray fluorescence spectrometer on glass disks made by fusion of whole-rock powder with lithium metaborate. Trace-element contents of whole-rock samples were analysed by quadrupole inductively coupled plasma mass spectrometry (ICP-MS); the precision is <10% deviation from true values for most trace elements although it could be >20% for elements with concentration less than 1 ppm. The contents of rare Earth elements (REE) and other incompatible elements in clinopyroxene from metagabbro and garnet amphibolite were measured with laser ablation (LA) ICP-MS. The same method is used to measure the contents of trace elements in garnet from garnet amphibolite. Samples for isotopic analysis were dissolved in Teflon bombs after being spiked with 84Sr, 87Rb, 150Nd and 147Sm tracers prior to HF+HNO3 (with a ratio of 2:1) dissolution. Strontium and neodymium were extracted by conventional ion exchange chromatographic techniques. Sr and Nd isotope ratios were measured using a Finnigan MAT 262 multiple collector thermal ionization mass spectrometer running in dynamic mode at the Institute of Geology and Geophysics in Beijing, according to the method described by Zhu et al. (Reference Zhu, Sun, Gu, Ogasawara, Jiang and Honma2001). Replicate analyses of the Sr isotope reference material BCR-1 gave average 87Sr/86Sr values of 0.705086±0.000011 (1σ, n = 16; the recommended value for BCR-1 is 0.70501±8; Balcaen et al. Reference Balcaen, Schrijver, Moens and Vanhaecke2005). The 87Sr/86Sr ratio was corrected for instrumental mass fractionation assuming 86Sr/88Sr = 0.1194; the 143Nd/144Nd ratio was corrected for instrumental mass fractionation assuming146Nd/144Nd = 0.7219. The Nd La Jolla reference material yielded an average ratio of 143Nd/144Nd = 0.511842±0.000012 (1σ, n = 12; recommended value for Nd La Jolla is 0.511849; Upadhyay, Scherer & Mezger, Reference Upadhyay, Scherer and Mezger2008). Blanks were of the order <0.3 ng for Sr and <0.1 ng for Nd. The Nd isotope data were normalized to the accepted reference values for La Jolla.
4. Petrography
4.a. Lherzolite
Lherzolite in the Baijiantan ophiolitic mélange consists mainly of olivine (0–7%), orthopyroxene (20–33%), clinopyroxene (30–45%), spinel (2–4%) and serpentine (15–40%). Olivine and orthopyroxene were replaced by serpentine in most cases; olivine is locally present as inclusions in clinopyroxene or orthopyroxene (Fig. 4a). Brown spinel with homogeneous composition (Cr number 8.5–12.9 mol.%) is replaced by ilmenite along rims and orthopyroxene is partly replaced by serpentine along rims and cleavages. Both clinopyroxene and orthopyroxene show exsolution textures; orthopyroxene lamellae occur in clinopyroxene (Fig. 4b, c) and parallel clinopyroxene lamellae occur in orthopyroxene (Fig. 4d). The compositional variation of these pyroxenes is shown in Supplementary Figure 1 and Supplementary Table 1 (both available at http://journals.cambridge.org/geo). Host clinopyroxene (diopside) contains enstatite–pigeonite lamellae and host orthopyroxene (enstatite) contains diopside lamellae. Diopside–enstatite pairs are common in the studied lherzolite samples and have very limited compositional variation in the En–Wo–Fs plots, whereas the trace element contents in these different pyroxene phases are distinguishable. For example, host clinopyroxene is rich in Si and poor in Ti and Cr relative to clinopyroxene lamellae, while host orthopyroxene and lamellae have a similar content of Na, Ti and Cr. The Ti mostly partitioned into diopside lamellae relative to their orthopyroxene host, and Cr partitioned largely into diopside lamellae during exsolution of orthopyroxene.
4.b. Dolomite marble
Dolomite marble lenses, ranging in size from several decimetres to hundreds of metres, occur in the Baijiantan ophiolitic mélange together with lherzolite lenses (Fig. 2b, c). Dolomite marble consists of dolomite (20–45%), calcite (10–15%), serpentine (10–15%), quartz (5–10%), spinel (2–4%) and magnetite (2–5%). Zoned dolomite coexists with quartz and magnetite; quartz+magnetite+dolomite assemblage replaced serpentine in most cases. Brown spinel in marble was replaced by magnetite along its rim (Fig. 4e). Dolomite marble lenses usually contain relics of spinel-bearing serpentinite, which suggest that the dolomite marble was transformed from spinel lherzolite (Zhu et al. Reference Zhu, Xu, Chen and Xue2008). The observed mineral assemblages and pyroxene pseudomorphs (Fig. 4f) resulted in the transformation of pyroxene into dolomite+quartz+ magnetite via the reaction of pyroxene+CO2 = dolomite+magnetite+quartz; serpentine was also transformed to dolomite+quartz+magnetite via a reaction of serpentine+calcite = dolomite+ magnetite+quartz. Spinel is the only original mineral preserved during metamorphism, with a highly variable composition (Supplementary Table 2 and Supplementary Figure 2, available at http://journals.cambridge.org/geo). Spinel grains in dolomite marble are characterized by higher Cr number (>0.6) and lower Mg number (<0.6) than those in lherzolite.
4.c. Metagabbro
Metagabbro consists of clinopyroxene (25–40%), plagioclase pseudomorphs (30–45%), amphibole (5–10%) and other second mineral phases (zoisite, albite, chlorite, ilmenite and quartz); plagioclase pseudomorphs consist mainly of zoisite and albite (Fig. 5a–d). As a mineral phase crystallized from magma, clinopyroxene was replaced by amphibole (Fig. 5e, f) and garnet occurs along the rim of plagioclase pseudomorphs (Fig. 5g, h). The latter suggests a transformation from plagioclase to garnet, which was accompanied by growth of chlorite and ilmenite (Fig. 5h).
4.d. Garnet amphibolite
Garnet amphibolite blocks, ranging in size from a few decimetres to several metres, occur rarely in the Baikouquan region. Garnet amphibolite contains various amounts of garnet and amphibole with minor amounts of zoisite, epidote, chlorite, clinopyroxene, ilmenite, biotite and sphene. Garnet grains vary greatly in size (from <0.1 mm to >1 mm), and large garnet grains are usually cracked (Figs 6a, 7a). Zoisite occurs in the matrix, pseudomorphing plagioclase (Fig. 6a), and fills cracks in garnet and clinopyroxene grains, the latter containing ilmenite inclusions (Fig. 6b). Garnet contains various kinds of mineral inclusions including clinopyroxene, rutile, apatite, ilmenite, biotite and quartz (Fig. 7b, g).
Garnet compositions (Supplementary Table 3, available at http://journals.cambridge.org/geo) vary significantly from one sample to another (Fig. 8), although most analyses are restricted to a range of Py10–25Gro25–30Alm55–75. Garnet in sample K26 contains relatively higher pyrope (mostly >20 mol.%) and lower grossular component. All these garnet analyses fall within in the field corresponding to garnet in eclogite coexisting with blueschist (Fig. 8a). No compositional zoning has been found in garnet grains, although there is variation in some element contents from core to rim in different garnet grains (Fig. 8b–j).
Compositional variation of clinopyroxene in garnet amphibolite is listed in Supplementary Table 4 and shown in Supplementary Figure 3 (both available at http://journals.cambridge.org/geo). Clinopyroxene from sample K24 is rich in Ca (Wo>46 mol.%) and located in the region of diopside-hedenbergite, while clinopyroxene from sample K26 is rich in Mg (En>33 mol.%). Na2O contents in clinopyroxene from sample K26 (>0.4 wt%) are obviously higher than that in sample K24 (<0.4 wt%). Amphibole is highly variable in composition (Supplementary Figure 4 and Supplementary Table 5, both available at http://journals.cambridge.org/geo) and defines the substitution series with magnesiohornblende and tschermakite as end-members. However, amphibole analyses for different samples have similar compositions, suggesting their similar metamorphism conditions from one sample to another.
5. Geochronology of zircons from metagabbro and amphibolite
Metagabbro (DJ101) and amphibolite (DJ81) samples collected from the Baikouquan region (Fig. 3b) were used for a zircon chronology study. Most zircons have narrow rims showing a bright CL image (Figs 9a, b, 10a); the narrow rim is generally irregular and discontinuous with a width of 0–20 μm. The irregular boundary between igneous zircon with oscillatory zoning pattern and its discontinuous rim suggests a replacement reaction. Zircon rims showing a bright CL pattern are typical of metamorphic zircon (Zheng et al. Reference Zheng, Wu, Zhao, Zhang, Xu and Wu2005; Zhang et al. Reference Zhang, Ai, Li, Rubatto and Song2007), which differs from hydrothermal zircon rims with dark CL images (Zhu, Reference Zhu2011). Similar metamorphic zircon rims have been reported in most metamorphic rocks, including eclogite and amphibolite.
In the amphibolite igneous zircon would have crystallized during gabbro emplacement, its U–Pb age representing magma intrusion time. Most zircon grains in sample DJ101 show a weakly oscillatory zoned pattern combined with a sector zoning pattern. Several zircon grains have narrow metamorphic rims (most <3 μm with bright CL image; Fig. 9a). The narrow metamorphic rim of zircon in the metagabbro likely formed during metamorphism. Zircons in this metagabbro sample have Th/U ratios ranging from 0.24 to 0.84 and apparent U–Pb ages of 402–359 Ma. One zircon with an apparent U–Pb age of 401±12 Ma (spot –8.1; Table 1) differs from other zircon grains by its bright CL image (Fig. 9a, b). This may suggest a different origin, and will not be discussed here. Another obviously old apparent U–Pb age (402±12 Ma, spot –13.1) is for a zircon core, while its rim gives a much younger U–Pb age (388±11 Ma, spot –14.1; Fig. 9b). These two apparent U–Pb ages of >400 Ma with large errors are not included in the following calculations. Spot –12.1, with the obviously younger U–Pb age (359.1±9.5 Ma), might represent a mixed U–Pb age between igneous zircon and its metamorphic rim, and is also excluded from the following calculation. With the exception of these three problematic spots, all other analyses give a weighted average U–Pb age of 385.0±3.3 Ma (n = 12, MSWD = 0.56; Fig. 9c, d). This age represents magma emplacement prior to metamorphism.
For amphibolite sample DJ81, most zircon grains have narrow metamorphic rims (mostly <10 μm, with bright CL image; Fig. 10a). The weakly oscillatory zoned zircon combined with sector zoning pattern is replaced on the rim by a thin metamorphic envelope. It was not possible to obtain a U–Pb age for this metamorphosed zircon rim due to its very narrow width (mostly <5 μm, rarely up to 20 μm). It was also difficult to avoid the metamorphic zircon rim completely in performing SHRIMP analyses in some cases. For example, one weakly oscillatory zoned zircon (Fig. 10b, inserted CL image) is replaced by a thin metamorphic rim (<3 μm); this weakly oscillatory zoned zircon was dated at 369.7 Ma, while another analysis next to this spot produced a younger U–Pb age of 359.6 Ma. The younger age may have been contaminated by the narrow metamorphic rim.
Zircons have Th/U ratios ranging from 0.25 to 0.91 with apparent U–Pb ages of 382–342 Ma (Table 1). SHRIMP analyses give a weighted average U–Pb age of 363.3±3.1 Ma (n = 25, MSWD = 0.69; Fig. 10b, c), excluding two spots (–5.1 and –17.1 with obviously younger ages of 348.0±7.9 Ma and 341.9±7.2 Ma, respectively). The younger U–Pb age could be interpreted as a maximum age of metamorphism. It probably represents a mixture between igneous zircon and a relatively large amount of metamorphic rim. All other analyses may represent mixtures of igneous zircon and the metamorphic rim, with the volume of the metamorphic rim being variable from one spot to another. Thus, the obtained weighted average U–Pb age of 363.3±3.1 Ma probably does not have an accurate geological meaning as the metamorphic zircon rim could not be excluded completely during SHRIMP analysis.
6. Geochemistry
6.a. Trace element geochemistry of clinopyroxene and garnet
Clinopyroxene in metagabbro (Table 2) is depleted in light REE ((Ce/Yb)N = 0. 23–0.32; Fig. 11a). Depletions of Rb, Ba, Th, Ta and Nb are apparent in primitive-mantle-normalized plot, while Nd, Hf, Ti and heavy REE show enrichments (Fig. 11b). Concentrations of Ce, Rb, Nb and Pb are highly variable. Clinopyroxene in garnet amphibolite (Table 3) can be divided into two groups based on REE contents (Fig. 11c): one is depleted in light REE or shows a flat REE pattern and another shows a convex-upwards chondrite-normalized REE pattern with a weak depletion of light REE and negative Eu anomalies (Eu/Eu* = 0.51–0.96). Clinopyroxene in garnet amphibolite is characterized by apparent depletions in Rb–Ba, Ta–Nb, Pb–Sr and Ti with highly variable contents of Cs, Rb and Ba (Fig. 11d). Such different geochemical behaviours are consistent with the studied clinopyroxene types; clinopyroxene in metagabbro is magmatic and clinopyroxene in garnet amphibolite is metamorphic in origin.
Garnet in amphibolite is enriched in heavy REE (Table 4) and strongly depleted in light REE relative to chondrite (Fig. 12a). Garnet shows a typical chondrite-normalized REE pattern with a strong light REE depletion ((Ce/Yb)N < 0. 004) and variable but mostly insignificant Eu anomalies. Garnet is strongly depleted in Ba, Nb, La, Ce and Sr in a primitive-mantle-normalized plot (Fig. 12b). The contents of Cs, U, Pb, Nd, Zr and Hf in garnet are similar to the primitive-mantle values.
6.b. Geochemistry of metagabbro, amphibolite and lherzolite
Trace elements of representative samples of metagabbro and amphibolite in the Baikouquan region were measured with ICP-MS (Table 5, Fig. 13). REE contents are very low in metagabbro samples with flat patterns and strongly positive Eu anomalies (Eu/Eu* = 1.5–5.6; Fig. 13a). Trace elements are highly variable in primitive-mantle-normalized plots with strong enrichments of Cs, Rb, Ba and Sr ((Ba/Yb)N = 10.8–426; Fig. 13b and Table 5). Amphibolite samples from the Baikouquan region show flat REE distribution patterns (Fig. 13c). Most elements (except Ba for some samples; (Ba/Yb)N = 0.06–7.25) show flat patterns in primitive-mantle-normalized diagrams, with insignificant depletion of Ta, Nb, Zr and Hf (high-field-strength elements or HFSE, (Zr/Yb)N = 0.67–1.22; Fig. 13d, Table 5).
* MG – metagabbro; G-amp – garnet amphibolite; Amp – amphibolite
Trace elements of representative lherzolite, amphibolite and metagabbro samples collected from the Baijiantan region are listed in Table 6. The REE patterns for metagabbro samples are highly variable with (Ce/Yb)N values from 0.64 to 1.76. Three samples (Klm20, Klm24 and J-129) show similar patterns with strongly positive Eu anomalies (Eu/Eu* = 1.56–2.70; Fig. 14a); two other samples (Klm28 and Klm37) show similar REE patterns with a slight enrichment in light REE. Enrichments of Cs, Rb, Ba and Sr are apparent in primitive-mantle-normalized plots ((Ba/Yb)N = 3.1–15; (Sr/Yb)N = 1.3–14), while other trace elements are highly variable for different samples ((Zr/Yb)N = 0.5–2.0; Table 6). The flat REE patterns with positive Eu anomalies (Fig. 14a) and insignificant depletion of HFSE relative to the primitive mantle (Fig. 14b) suggest a mid-ocean-ridge basalt (MORB) origin for metagabbro in both the Baijiantan and Baikouquan regions. Their different REE contents and Eu anomalies may have been caused by magmatic differentiation and metamorphism. For example, magma differentiation may cause the accumulation of Ca-rich plagioclase, and thus show positive Eu anomalies. Once such gabbro undergoes metamorphism, Ca-rich plagioclase is replaced by zoisite+albite±garnet±ilmenite±chlorite and positive Eu anomalies will be reduced in the REE distribution pattern due to the decomposition of the Ca-rich phase that is host to most of the Eu. Compared to the Baikouquan metagabbro, metagabbro in the Baijiantan region is characterized by a higher content of REE, Zr, Hf and Y (Fig. 14b). The amphibolite sample Klm27 shows a flat REE pattern (Fig. 14c) and a primitive-mantle-normalized plot (Fig. 14d) shows a flat pattern with slight depletion of Th and Ta. The flat REE patterns and insignificant depletions of HFSE imply that both metagabbro and amphibolite originated from MORB-type magmatism. Clinopyroxene in metagabbro still shows a magmatic signature, even though it was partly replaced by amphibole.
Lherzolite samples have similar REE distribution patterns, showing obvious depletion of light REE without Eu anomalies (Fig. 15a). Total REE contents in these samples vary from 1.89 ppm to 3.71 ppm with (Ce/Yb)N of 0.11–0.75. The Cs, Rb, Ba, Th and Sr enrichments are apparent in primitive-mantle-normalized plots (Fig. 15b); the U, La, Ce and Nd contents are highly variable with obvious depletions of La, Ce and Nd.
The Sr–Nd isotopic compositions of representative lherzolite and metagabbro samples are listed in Table 7. Four lherzolite samples define one isochron, which gives an isochron age of 474±38 Ma (MSWD = 0.18; Fig. 16a) with ɛ Nd(t) of +8.9. One Rb–Sr isochron for metagabbro samples in the Baijiantan region indicates an isochron age of 335±10 Ma (MSWD = 1.4; Fig. 16b) with an initial 87Sr/86Sr ratio of 0.704597±0.000011. These metagabbro samples have positive ɛ Nd(t) values of +5.9 to +11.0 and initial 87Sr/86Sr ratios of 0.70447–0.70458. Seven metagabbro samples collected from the Baikouquan region give an Sm–Nd isochron age of 379±31 Ma (MSWD = 0.3; Fig. 16c), with ɛ Nd(t) of +9.4. These metagabbro samples have similar ɛ Nd(t) values (+9.3 to +9.5) and initial 87Sr/86Sr ratios of 0.7045–0.7054. Six Rb–Sr isotopic analyses (except for sample BK13) form one isochron which provides an age of 333±12 Ma (MSWD = 4.0; Fig. 16d) with an initial 87Sr/86Sr ratio of 0.705336±0.000032. The Sm–Nd isotopic isochron age (379 Ma) of metagabbro samples in the Baikouquan region likely represents a magmatic event. Their Rb–Sr isochron age (333 Ma) may record a metamorphic event, as the Rb–Sr isotopic system can be easily reset while that of the Sm–Nd isotopic system may remain stable during metamorphism.
Lherzolite samples are characterized by high positive ɛ Nd(t) and low initial 87Sr/86Sr values, different from the metagabbro samples which have higher initial 87Sr/86Sr ratios (Supplementary Figure 5, available at http://journals.cambridge.org/geo). The lherzolite samples with ɛ Nd(t) values of +8.8 to +9.1 and initial 87Sr/86Sr ratios of 0.7037–0.7040 are rather homogeneous in Sr–Nd isotopic compositions, whereas metagabbro samples have a relatively wide Sr–Nd isotopic compositional range; the ɛ Nd(t) values fall within a small range (+9.3 to +11.0) except for sample Klm24, which has a ɛ Nd(t) value of +5.9. High positive ɛ Nd(t) values for metagabbro samples suggest a depleted mantle origin, while their high initial 87Sr/86Sr ratios suggest interaction with Sr sourced from continental material or marine water during metamorphism.
7. Discussion
7.a. Metamorphic P–T conditions for garnet amphibolite
We used the PERPLE_X computer software package (Connolly, Reference Connolly2005; Massonne, Reference Massonne2009) to calculate the phase relations of garnet amphibolite. The thermodynamic dataset of Holland & Powell (Reference Holland and Powell1998; updated in 2002) for numerous mineral end-members (file hp02ver.dat) was applied. The following solid-solution series, which are compatible with the above dataset, were selected from this file: amphibole (GlTrTsPg, a mixture of glaucophane, tremolite, tschermakite, pargasite and corresponding Fe2+ end-members); biotite (Bio(HP): phlogopite, eastonite, corresponding Fe2+ and Mn2+ end-members); clinopyroxene (Omph(HP): diopside, hedenbergite and jadeite); garnet (Gt(HP): almandine, grossular, pyrope and spessartine); and ilmenite (IlGkPy: ideal mixture of ilmenite, geikielite and pyrophanite end-members).
Thermodynamic calculations for garnet amphibolite (sample K26, for its composition see Supplementary Table 6 available at http://journals.cambridge.org/geo) were started at 400°C and 8 kbar (Fig. 17a). Plagioclase does not occur in this P–T pseudosection whereas garnet and amphibole are present at all P–T conditions; quartz occurs only at low temperature (<510°C). The mineral phases in the studied samples include amphibole, garnet, zoisite, chlorite, clinopyroxene, biotite, ilmenite, sphene, rutile and quartz. Quartz, biotite and rutile mostly occur as inclusions in garnet (Fig. 7b–g). This mineral assemblage is consistent with evolution from F1 to F2 in the P–T pseudosection (Fig. 17a), where the mineral assemblage of biotite–chlorite–clinopyroxene–epidote–amphibole–garnet–sphene–quartz (F1) transformed to the mineral assemblage of biotite–chlorite–epidote–amphibole–garnet–sphene–quartz–H2O (F2) with isobaric temperature increase, during which period clinopyroxene disappeared and an H2O phase formed. Rutile growth started with a further temperature increase at F3 and formed a mineral assemblage of biotite–chlorite–epidote–amphibole–garnet–sphene–rutile–H2O without quartz. We suggest that the metamorphism recorded in sample K26 reached the P–T conditions of F3 (c. 15 kbar, 520–560°C).
The P–T path for garnet amphibolite started from F1 to F2, entered F3 isobarically and finally reached the amphibolite grade (F4; Fig. 17b) with pressure decrease. The P–T environment of stage F4 is based on the amphibole composition, estimated using the program developed by Gerya et al. (Reference Gerya, Perchuk, Triboulet, Audren and Sez'ko1997); amphibole analyses are listed in Supplementary Table 5 (available at http://journals.cambridge.org/geo). The P–T values based on amphibole compositions of sample K26 are 566–633°C and 4–6 kbar; sample K20 corresponds to 583–630°C and 4–6 kbar; sample K21 is 580–656°C (4.2–7.7 kbar); and sample K24 is 580–645°C (4–7 kbar). The overlap of these estimates determined the P–T environment of F4.
The mineral assemblage of garnet amphibolite records progressive metamorphism (from F1 to F3) which was followed by retrograde metamorphism (from F3 to F4). The P–T path could therefore be clockwise (Fig. 17b), reflecting a subduction condition in which gabbro (the original rock of the studied amphibolite) was first subducted and then exhumed.
7.b. Age constraints and tectonic implications
Zircon SHRIMP analyses give a weighted average U–Pb age of c. 385 Ma for metagabbro (Fig. 9) and 363 Ma for amphibolite (Fig. 10). The Sm–Nd isotopic analyses of metagabbro samples indicate an isochron age of 379 Ma (Fig. 16c). We consider that the U–Pb age of 385 Ma represents magma intrusion time, whereas the other two ages may be affected by metamorphism. The youngest U–Pb age (342 Ma; spot –17.1 for amphibolite sample DJ81; Table 1) probably corresponds to the peak metamorphic stage (F3). Retrograde metamorphism reached the P–T environment of F4 at c. 333 Ma based on the Rb–Sr isotopic isochron (Fig. 16b, d). This implies that the gabbro in the Junggar oceanic floor was subducted, underwent metamorphism in a subduction zone (at c. 342 Ma) and was exhumed to shallow depths (c. 5 kbar) at c. 333 Ma (Fig. 17c).
The Sm–Nd isochron age of 474 Ma (Fig. 16a) might record a partial melting event of depleted mantle that produced MORB-type magma and formed oceanic floor. This age is consistent with the microfossils separated from abyssal radiolarian chert in the Baijiantan region, which indicates that the palaeo-ocean closed during Late Ordovician time (He et al. Reference He, Liu, Zhang and Xu2007). The blueschist lenses in the Tangbale ophiolite mélange were dated at 458–470 Ma (Zhang, Reference Zhang1997). The similarity in ages as well as in the geological records of these ophiolitic mélanges (Feng, Reference Feng1986; Zhang & Huang, Reference Zhang and Huang1992; Zhu et al. Reference Zhu, Xu, Chen and Xue2008) support the suggestion that the Tangbale ophiolite mélange was connected with the Baijiantan–Baikouquan ophiolitic mélanges (the TBB belt; Fig. 1c). This huge TBB ophiolitic belt is also similar in age to the TTKH ophiolitic belt. The Kujibai ophiolitic mélange in the TTKH, extending west to Kazakhstan and connecting with the Tarbahatai ophiolitic belt, was dated at 478 Ma by zircons separated from metagabbro (Zhu & Xu, Reference Zhu and Xu2006).
Two Ordovician ophiolitic belts could therefore be identified in west Junggar: the TTKH belt located on the south boundary of the Chingiz–Tarbahatai arc, and the TBB belt located south of west Junggar (Fig. 1c). The Darbut–Sartohay ophiolitic belt, which is located between the TTKH and TBB Ordovician ophiolitic belts, was formed during the Early Devonian period. In such a tectonic scheme (Fig. 18) the TTKH was an accretionary terrane added to the south edge of the Chingiz–Tarbahatai arc then intruded by granitic rocks at 422–405 Ma (Chen, Han & Ji, Reference Chen, Han and Ji2010), and the TBB was an accretionary terrane amalgamated to the Junggar plate. The Darbut–Sartohay ophiolitic belt contains relics of the palaeo-oceanic floor.
Both the TTKH and TBB represent relics of Ordovician oceanic floor which subducted to the north under the Chingiz–Tarbahatai arc and to the south under the Junggar plate, respectively. Spreading of the Junggar oceanic floor probably did not stop until the Early Devonian period, as recorded by the Darbut ophiolitic belt located between the TTKH and TBB ophiolitic belts (Fig. 18a–c). The Kazakhstan–Junggar plate finally formed during the Early Devonian period, following closure of the Junggar ocean. The widespread early Carboniferous volcanic-sedimentary basins, filled by volcanic rocks, tuffaceous sandstone and siltstone intercalated with chert both in Chingiz–Tarbahatai and west Junggar, may have been part of this process.
8. Conclusion
The early Palaeozoic oceanic floor in west Junggar, represented by the Ordovician ophiolitic belts of TTKH and TBB, subducted to the north under the Chingiz–Tarbahatai arc and to the south under Junggar plate, respectively. The Baijiantan–Baikouquan ophiolite mélanges, representing the major part of the TBB, consist of serpentinized lherzolite, spinel-bearing serpentinite, metagabbro, garnet amphibolite, dolomite marble, pillow basalt and abyssal radiolarian chert. Metagabbro and garnet amphibolite show geochemical features of N-MORB with ɛ Nd(t) > 5.9 and 87Sr/86Sr(t) ratios of 0.7045–0.7054. These rock units underwent metamorphism at different P–T conditions; garnet amphibolite recorded a P–T path starting from blueschist conditions, isobarically entering garnet amphibolite conditions and finally passing through a P–T environment of amphibolite stability based on thermodynamic calculations. The clockwise P–T path suggests that the Baijiantan–Baikouquan ophiolitic mélanges were recycled via a subduction zone; the gabbro formed at >385 Ma, was subducted, underwent metamorphism at c. 342 Ma in the subduction zone and was finally exhumed at c. 333 Ma.
Supplementary material
To view supplementary material for this article, please visit http://dx.doi.org/10.1017/S0016756814000168
Acknowledgements
We would like to express our gratitude to Dr Réjean Hébert (Université Laval, Canada) and Professors Baofu Han and Guoqi He (Peking University) for their critical comments during this work. Professor Massonne H.-J. (Stuttgart University) introduced YZ to the PERPLE_X computer software package during a visit to Germany. Dr Phil Leat and two anonymous reviewers provided detailed critical comments and suggestions, which helped us to greatly improve this paper. Our gratitude is also extended to Dr Jeffrey Hedenquist and Phil Leat for correcting grammatical and syntax errors. Financial support for this study was provided by NSFC (Grant No. 41121062, 41372062, 41072041) and the International Science & Technology Cooperation Program of China (Grant No. 2010DFB23390).