Thermal history of granitic rocks from western Victoria: A fission‐track dating study

Fission‐track ages have been determined on sphene and apatite from 28 granitic intrusions across the western half of Victoria. The sphene ages compare closely with independent K‐Ar biotite ages for the same intrusions, where these are available, and are invariably older than apatite ages by 35 to 135 m.y. This is in accord with the effective geological track annealing temperatures for these two minerals which are estimated to be 260 ± 20°C and 80 ± 10°C respectively. Both sphene and apatite ages decrease from west to east across western Victoria, the sphenes ranging from 470 ± 28 to 355 ± 19 m.y. The Wando Vale granodiorite and Dergholm granite from the Dundas Tableland of far‐western Victoria have sphene ages of 470 ± 28 m.y. and 452 ±16 m.y. respectively, clearly suggesting a relationship to the Ordo‐vician granitic rocks of southeastern South Australia. Fission‐track ages from the numerous post‐tectonic granites in the Ballarat Trough fall into two distinct groups. Rocks from the western area have sphene ages in the relatively narrow range 393 ± 14 m.y. suggesting emplacement in the Early Devonian time whereas those in the east have sphene ages of 362 ± 7 m.y. (near the Devonian‐Carboniferous boundary). Over the temperature interval recorded by sphene‐apatite pairs, cooling of the granitic rocks was very slow ranging from 0.8 to 5.3°C/m.y. Cooling in this range was probably controlled by uplift and erosion of overburden during a long period of post‐tectonic relaxation. Corresponding uplift rates are estimated to be 0.03 to 0.18 km/ m.y. assuming a normal continental geothermal gradient of 30°C/km. Below 80°C average cooling and uplift rates were probably about l°C/m.y. and 0.03 km/m.y. respectively so that cooling was essentially complete within about 80 m.y. of the apatite ages.     

Response of U‐Pb Zircon and Rb‐Sr total‐rock and mineral systems to low‐grade regional metamorphism in proterozoic igneous rocks,mount Isa,Australia

A detailed Rb‐Sr total‐rock and mineral and U‐Pb zircon study has been made on suites of Proterozoic silicic volcanic rocks and granitic intrusions, from near Mt Isa, northwest Queensland. Stratigraphically consistent U‐Pb zircon ages within the basement igneous succession show that the oldest recognized crustal development was the outpouring of acid volcanics (Leichhardt Metamorphics) 1865 ± 3 m.y. ago, which are intruded by coeval, epizonal granites and granodiorites (Kalkadoon Granite) whose pooled U‐Pb age is 1862 ⁺²⁷ _‐21 m.y. A younger rhyolitic suite (Argylla Formation) within the basement succession has an age of 1777 ± 7 m.y., and a third acid volcanic unit (Carters Bore Rhyolite), much higher again in the sequence, crystallized 1678 ± 1 m.y. ago.

All of these rocks are altered in various degrees by low‐grade metamorphic events, and in at least one area, these events were accompanied by, and can be partly related to, emplacement of a syntectonic, foliated granitic batholith (Wonga Granite) between 1670 and 1625 m.y. ago. Rocks that significantly predate this earliest recognized metamorphism, have had their primary Rb‐Sr total‐rock systematics profoundly disturbed, as evidenced by 10 to 15% lowering of most Rb‐Sr isochron ages, and a general grouping of many of the lowered ages (some of which are in conflict with unequivocal geological relationships) within the 1600–1700 m.y. interval. Such isochrons possess anomalously high initial ⁸⁷Sr/⁸⁶Sr ratios, and some have a slightly curved array of isotopic data points. Disturbance of the Rb‐Sr total‐rock ages is attributed primarily to mild hydrothermal leaching, which resulted in the loss of Sr (relatively enriched in ⁸⁷Sr in the Sr‐poor (high Rb/Sr) rocks as compared with the Sr‐rich rocks).     

A Rb-Sr whole rock isochron date on an igneous rock-body from the Stavanger area,South Norway

The Ormakam-Moldhesten granite, from the Stavanger area, South Norway, has been dated by the Rb-Sr whole rock method. The isochron ages obtained (1180 m.y., 1243 ±160m.y. and 1534±125 m.y.) show that the granite complex is of Precambrian age. The 1543 m. year age is thought to refer to a period of early granulite facies metamorphism, the 1180 m.y. isochron age is taken as the crystallisation age of a later intrusion of biotite granite. This is within the limits of error of the 1160 m.y. metamorphic event shown earlier to have affected the paragneisses in the area. The results demonstrate clearly the allochthonous position of the gneisses and granitic intrusives overlying the fossiliferous Cambrian beds in the Stavanger area. The tectonostratigraphic succession in this area is thus consistent with the observation of Precambrian nappes to the north (Hardangervidda-Ryfylke area).     

Radiometric evidence for the age of emplacement and cooling of the Murrumbidgee Batholith

Most of the rocks of the Murrumbidgee Batholith have a Rb‐Sr age of 424 ± 2 m.y. This is considered to be the time of emplacement. A small difference in the ages (4 ± 2 m.y.) between the northern and southern parts of the batholith is attributed to thermal effects caused by a slightly later time of emplacement of some of the intrusions or to a short cooling interval. Final intrusive activity ended by 414 ± 4 m.y. Younger mineral ages for some intrusions are related to later local meta‐morphic effects.     

New and recalculated radiometric data supporting a carboniferous age for the emplacement of the Bathurst batholith,New South Wales

The Bathurst batholith is a complex of massive granitic intrusions cutting across deformed early and middle Palaeozoic rocks of the Lachlan Fold Belt of New South Wales. An adamellite from Dunkeld, near the western edge of the batholith, has yielded K‐Ar ages of 304 ± 4 m.y. (total‐rock) and 301 ± 6 m.y. (biotite).

Recalculated radiometric ages on rocks from the eastern end (Hartley) and northern edge (Yetholme), together with the new data from the western end (Dunkeld) of the Bathurst batholith yield a mean age of emplacement of 310 m.y. (8 values, standard deviation = 6.8 m.y.). This age is supported by Re‐Os data from molybdenite at Yetholme. As yet these data do not allow establishment of temporal relationships between separate intrusive phases of the Bathurst batholith, although the Durandal Adamellite at Yetholme appears to be the oldest phase yet dated.     

Isotopic U-Pb ages of monazites and zircons from the crust-mantle transition and adjacent units of the ivrea and ceneri zones (Southern Alps,Italy)

The Ivrea zone forms a part of the Southern Alps and is composed of basic rocks interfingered with granulite facies acidic rocks. According to geophysical evidence, this zone represents the transition between crust and uplifted and overthrusted mantle. Towards the Ceneri zone the metamorphic grade changes to amphibolite facies. Paragneisses, migmatites and anatectic gneisses dominate, within which postmetamorphic granites occur. Concordant monazite U-Pb ages of 275+2 m.y. were obtained from paragneisses of the Ivrea zone. The apparent zircon ages are discordant indicating a minimum age of 1900 m.y. for the oldest population and an apparent lead loss of 99 to 85 % about 285–300 m.y. ago. The zircons show features such as rounded habitus, low trace element contents and well ordered crystal lattices characteristic for detrital, recrystallised populations. Monazite from the neighbouring Ceneri zone migmatite yielded concordant U-Pb ages at 295±5 m.y. The discordant zircon age pattern indicates a time of formation of 450 m.y., similar to other newly formed zircons in anatectic rocks of the Ceneri zone, and an episodic or continuous lead loss at, or until 300 m.y. ago. The majority of the zircons are euhedral and have elevated trace element contents, features typical for zircons formed in the present-day host rocks. Concordant, 295±5 m.y. old monazite dates the formation of the postmetamorphic Mont' Orfano granite. Again zircon fractions yielded discordant ages, pointing in contrast to the above discordancies to a recent or continuous lead loss. The concordant ages of the monazites demonstrate the usefulness of this mineral for dating purposes in metamorphic and granitic rocks and contrast with the discordant age patterns of all zircon suites. From the general agreement between the monazite ages and the time of lead loss inferred from the zircon age patterns as well as from the geological relationships of the rocks and their metamorphic grade it is concluded that 295±5 m.y. is the minimum age for the regional granulite to upper amphibolite facies metamorphism of the Ivrea zone and that the uplift and overthrust of the upper mantle started prior to 295 m.y. ago, and that the basic rocks of the Ivrea zone are synmetamorphic intrusions. The decrease from 310–320 m.y. to 170–200 m.y. of the K-Ar and Rb-Sr mineral ages from the Ceneri towards the Ivrea zone is accompanied by decreases from 450 m.y. to 295 m.y. and on to 275 m.y. in the U-Pb ages of monazites. The zircon age pattern also shows a decrease from 450 m.y. to approximately 300 m.y. The main lowering of the ages occurs approximately at the petrographic boundary between the two zones and is related to the Hercynian uplift and overthrust of the mantle which may have started as early as 450 m.y. ago. The Insubric line which terminates the Ivrea zone towards the North must therefore be of pre-Alpine age, or a precursor of the Insubric line must have existed at the time of the mantle uplift.     

Discussion: Palaeomagnetism,radiometric age and geochemistry of an adamellite at Yetholme,N.S.W.

Volcanic rocks, mainly of intermediate composition, occupy several basins within the rift zone along which the Yangtze River flows in its lower reaches. Potassium‐argon (K‐Ar) age measurements on minerals and whole rock samples from lavas and syenitic intrusives in the Lujiang‐Tzungyang volcanic basin range from 131 to 123 m.y., and biotites from two lavas in the Nanjing‐Wuhu basin have measured ages of 127 and 130 m.y. Incremental heating experiments by the ⁴⁰Ar/³⁹Ar method on biotite from two volcanic rocks, one from each basin, yield simple age spectra with plateau ages of 129 to 130 m.y. These data provide evidence that the two biotites have remained undisturbed since crystallisation. The combined results show that volcanism was contemporaneous within the two basins in the Early Cretaceous. Vol‐canism in the Yangtze Volcanic Zone is thought to be related to adjustments within the Eurasian plate as a consequence of collision between the earlier Pacific (Kula) plate and the Eurasian plate.     

Pb isotopic dating of some Precambrian rocks from North China—An ensuing discussion on Precambrian Geochronological Scale of China

Pb isotopic ages of some Precambrian rocks from North China were determined. New data from the Chuanlinggou Formation of the Great Wall Group in the Yanshan region, together with published data, show that their whole-rock Pb-Pb isochron age is 1,922±92 (δ) m.y. Thus, 2,000±100 m.y. as the lowest age of the Sinian Geochronological Scale of China is important. In view of the fact that the whole-rock Pb-Pb isochron age from the Liaohe Group in Liaoning Province is estimated to be 1,977±49 (δ) m.y., which is in agreement with the possible maximum deposition age calculated from Rb?Sr data, we prefer to consider the Liaohe Group to be Sinian rather than pre-Sinian in age. Zircon, apatite and other minerals from the Tiejiashan granitic gneiss at Anshan, Liaoning Province, lie on two U-Pb discordant lines with ca. 3,300 and 2,800 m.y. respectively. Zircon, on the discordia with 3,300 m.y., is non-magnetic and free from dark inclusions. Apatite with common Pb isotopic composition, lying on the line of older age, is close to the concordia, indicating that it has not undergone any geological thermal events since it was formed. Zircon and apatite with inclusions and magnetism lie on the discordia of younger age. A U-Pb age of ca. 3,300 m.y. for the Tiejiashan granitic gneiss seems to be possible. However, it is necessary to examine the ages of these rocks with Rb?Sr and other methods in the future. A precursory Precambrian Geochronological Scale of China is propsed based on the Sinian Geochronological Scale of China published in 1977^[1] as well as on new data from this study.     

新疆准噶尔北缘玉勒肯哈腊苏铜(钼)矿区韧性剪切变形时代——来自白云母和黑云母Ar-Ar年龄的约束

玉勒肯哈腊苏斑岩铜(钼)矿主要赋存于闪长玢岩中,少量在北塔山组火山岩及似斑状石英二长岩中。矿化呈细脉状、细脉-浸染状和浸染状。成矿过程经历了斑岩期、剪切变形期和表生期。矿区发育韧性剪切变形带,中泥盆统北塔山组、下石炭统姜巴斯套组、岩体及矿体均发生了剪切变形作用。沿剪切面发育黑云母和白云母新生矿物。白云母的坪年龄和等时线年龄分别为283.8±1.5Ma和285.4±3.1Ma,黑云母的坪年龄和等时线年龄分别为277.0±2.0Ma和277.0±4.0Ma,在误差范围内基本一致,限定矿区韧性剪切变形时间在早二叠世(284～277Ma),与区域额尔齐斯-玛因鄂博断裂活动时间一致。主要成矿作用形成于斑岩期,成矿时代为中泥盆世(374Ma),早二叠世的韧性剪切变形作用只对铜(钼)矿化进行改造。     

吐哈盆地砂岩型铀矿U-Pb同位素地质特征

吐哈盆地十红滩砂岩型铀矿主要成矿年龄为48±2Ma、28±4Ma。盆地西南部蚀源区觉罗塔格山片麻状花岗岩的形成年龄为422±5Ma、斑状花岗岩的形成年龄为268±23Ma。赋矿地层西山窑组(J2x)砂体碎屑锆石U Pb等时线年龄为283±67Ma ,证实花岗岩侵入体是含矿砂体的主要物质来源。含矿层位的富铀沉积砂体及蚀源区富铀的岩体、石炭系碎屑岩以及火山碎屑岩等 ,构成铀成矿铀源。     

北祁连山白山子花岗闪长岩成岩时代

寒山大型金矿是近年来在北祁连山西段发现的与侵人岩有关的构造蚀变岩型金矿。笔者首次利用锆石U-Pb方法测得白山子花岗闪长岩的形成年龄为370±25 Ma，属于华力西期。寒山金矿的成矿主要在213.95~339 Ma间。在多期热液叠加，多期成矿作用中，早期成矿的热液很可能是白山子花岗闪长岩（370±25 Ma) ,寒山辉长岩(347.1±6. 4 Ma）共同提供的。由于该区有较多的中酸性岩体存在，它们可能为金的主要来源，因而，确定这些侵入体的形成年龄，对于在该区寻找蚀变岩型金矿不仅有重要的理论意义，而且有重要的现实意义。     

Pre-Alpine history of the pennine zone in the Tauern Window,Austria: U-Pb and Rb-Sr geochronology

Zircon ages from major lithologies of the Zentralgneis suggest that much of the Variscan magmatism in the Tauern Window is older than previously suggested. In the southeast Tauern Window a tonalite has been dated at 314±7 m.y. and a granodioritic biotite augen gneiss at 313±10 m.y. Two granodiorites from the Granatspitzkern yielded zircon data consistent with a similar age. These zircon data require re-interpretation of some previously published Rb-Sr whole rock ages and raise the possibility that Alpine metamorphism caused more widespread disturbance of Rb-Sr whole rocks than commonly supposed. Rb-Sr data on fabric-forming white micas from two banded gneisses give ages close to 220 m.y., indicating the foliation in these rocks is pre-Alpine and has not been greatly affected by Alpine recrystallisation.     

Dating of granulites involved in the hercynian fold-belt of Europe: An example taken from the granulite-facies orthogneisses at La Picherais,Southern Armorican Massif,France

Situated within the crystalline metamorphic complex of Champtoceaux NE of Nantes, the orthogneiss of La Picherais (near St Mars-du-Désert, Loire Atlantique, France) show relicts of a granulite facies paragenesis. Comparison with other granulitic rocks in the Hercynian fold-belt suggest possible ages ranging from Lower Proterozoic to Phanerozoic. The Rb-Sr whole rock method yields an errorchron of 570±110 m.y. for the Picherais orthogneiss, whereas the U-Pb zircon method indicates an upper intersection on Concordia at 1,880±120 m.y. and a lower intersection at 423±10 m.y. Several interpretations are possible for these data: the granite emplacement age was (1) 1,900 m.y. ago. (2) more likely Upper Proterozoic — Lower Palaeozoic. The zircons concordant at 1,900 m.y. were either present in the granitic magma at its time of origin or were introduced into the magma during emplacement. These zircons could be derived from sedimentary horizons such as found in the Lower Ordovician sandstones of the Armorican massif whose zircon age data are presented here.     

Mineral-chemical and isotopic studies of Namaqualand granulites,South Africa: A grenville analogue

The northwestern part of South Africa and southern South-West Africa/Namibia is amongst the most extensive granulite terranes in Africa. This work reports the results of electron microprobe studies of minerals from two-pyroxene, cordieriteorthopyroxene (-gedrite) (-sapphirine) and garnet and/or cordierite parageneses from Namaqualand, in the N.W. Cape Province of South Africa. Determined PT conditions of prograde metamorphism based on thermodynamic calculations are 800°–900° C and ca. 6–7 Kb; and it is argued that rocks of unusual composition, notably cordierite-orthopyroxene rocks, are restites after the extraction of granitic liquid from former argillites. This interpretation is consistent with previously published data on similar rocks, and with McCarthy's (1976) suggestion of extensive partial melting in the quartzofeldspathic rocks in the area. U-Pb isotopic studies of some 50 zircon fractions have been carried out and confirm an age of 1,200 m.y. for the high-grade regional metamorphism; but certain zircon populations record inherited ages greater than 1,700 m.y. Garnet-sillimanite rocks that contain retrograde kyanite reflect PT conditions of 550°–650° C and ca. 7–8 Kb; and constituent biotite has yielded a K-Ar age of ca. 950 m.y. These data, the regional stratigraphy and structure, and the mineralisation are compared with data from the Grenville Province of Canada. Notable similarities are the possible basement-cover relationships, and the calendar of tectonothermal events, while differences include the important stratiform base-metal mineralisation in the supracrustal sequence in Namaqualand, and the Cu-mineralisation in hypersthenebearing intrusives, emplaced some 1,100 m.y. ago, that are areally, and believed to be genetically, related to the granulite facies metamorphic regime.     

K–Ar ages of granitoids unravel the stages of Neo-Tethyan convergence in the eastern Pontides and central Anatolia,Turkey

K–Ar dating of mineral separates extracted from various granitoid rock units of the eastern Pontides and central Anatolia, Turkey, has provided some new insights unravelling various stages of the Neo-Tethyan convergence system, which evolved with northward subduction between the Eurasian plate (EP) to the north and the Tauride-Anatolide platform (TAP) to the south along the İzmir-Ankara-Erzincan suture (IAES) zone. Arc-related granitoid rocks are only encountered in the eastern Pontides and yield K–Ar cooling ages of both Early Cretaceous (138.5 ± 2.2 Ma) (early arc), and Late Cretaceous, ranging from 75.7 ± 0.0 to 66.5 ± 1.5 Ma (mature arc), respectively. The multi-sourced granitoids of the eastern Pontides, with a predominant mantle component and K–Ar ages between 40 and 50 Ma, are considered to be a part of post-collisional slab break-off magmatism accompanied by tectonic denudation of pre-Late Cretaceous granitoid rocks following juxtaposition of the EP and the TAP around 55–50 Ma in the eastern Pontides. The K–Ar cooling ages of collision-related S-, I- and A-type granitoids in central Anatolia reflect good synchronism between 80 and 65 Ma, suggesting a coeval genesis in a unique geodynamic setting but with derivation from various sources—namely, purely crustal, purely mantle and/or of mixed origin. This sort of simultaneous generation model for these S-I-A-type intrusives seems to be consistent with a post-collisional lithospheric detachment related geodynamic setting. I-type granodioritic to tonalitic intrusives with K–Ar cooling ages ranging from 40 to 48 Ma in east-central Anatolia are interpreted to have been derived from a post-collisional, within-plate, extension-related geodynamic setting following the amalgamation of the EP and the TAP in east-central Anatolia.     

Isotopic geochronology of mesozoic acid volcanic rocks in Zhejiang Province,China

Volcano-sedimentary series of the Upper Jurassic to the Lower Cretaceous are extensively developed in Zhejiang Province. But ages and stratigraphic correlation concerning these rocks have long been a controversial problem. Systematic sampling was made of volcanic rocks of the Laocun, Huangjian, Shouchang and Moshishan Formations in western Zhejiang considered thus far as the Late Jurassic. Isotopic age determinations show that U-Th-Pb zircon ages are approximately concordant with Rb-Sr isochron ages, whereas K-Ar biotite ages and K-Ar isochron ages are all slightly lower. It can therefore be established that the ages of volcanic rocks mentioned above range from 134±6 to 122±2 m.y., corresponding to the “transitional period” from Jurassic to Cretaceous. It can also be concluded that the rocks have not undergone apparent epigenetic metamorphism. The initial⁸⁷Sr/⁸⁶Sr ratio is about 0.7089–0.7121, on the basis of which it may be postulated that the volcanic magma seems to have originated from the upper mantle with contamination by sialic materials subsequent to differentiation. For age determinations of such acid volcanic rocks Rb-Sr isochron method is considered more suitable in view of its following advantages: the high reliability of results; wide applicability to different samples; smaller sample requirement and the possibility for further studies involving petrogenesis by use of initial⁸⁷Sr/⁸⁶Sr ratio.     

K‐Ar dating of Permian and Tertiary igneous activity in the Southeastern Sydney Basin,New South Wales

The southern part of the Sydney Basin of New South Wales is comprised mainly of Permian and Triassic marine to freshwater clastic sedimentary rocks. Within this sequence there are six latite extrusive units, several medium‐sized monzonite intrusions and a large number of small to medium‐sized basic to intermediate intrusions. Thin basaltic flows were extruded onto the Tertiary topographic surface. All of these rocks are relatively undeformed.

Radiometric (K‐Ar) dating has previously been carried out on Mesozoic and Tertiary intrusions and flows of the southwestern portion of the Sydney Basin. However, relatively few Permian, and no post‐Permian, K‐Ar dates have been published for the southeastern portion of the basin. The present investigation provides nine K‐Ar dates from the latter area.

Four extrusive and intrusive units have been confirmed as Permian in age (238 ± 6; 241 ± 4; 245 ± 6; and 251 ± 5 m.y.). Five post‐Permian (on stratigraphic criteria) intrusions yielded Tertiary ages (26.2 ± 3.0; 47.9 ± 2.5; 49.0 ± 4.0; 49.4 ± 2.0; and 58.8 ± 3.5 m.y.). The Permian ages agree with previously published K‐Ar data from the southeastern Sydney Basin, and the Tertiary ages complement and extend the data from the southwestern portion of the basin. However, no Mesozoic K‐Ar dates were obtained from the southeastern Sydney Basin. The Tertiary intrusions may have been emplaced as a result of rifting between Australia and New Zealand, or between Australia and Antarctica, or both.     

The Origin of Associated Basic and Acid Rocks in the Lebombo--Nuanetsi Igneous Province, Southern Africa, as implied by Strontium Isotopes

Whole rock Rb–Sr measurements were made on associatedbasic and acid intrusives and extrusives from the northern andsouthern ends of the Lebombo monocline with a view to determineif the acid rocks came from the mantle or from the crust. Inthe south, in Swaziland (now called Ngwame) and Zululand, rhyolitesand granophyres (age 202 14 m.y.) have an initial Si⁸⁷–Sr⁸⁶ratio of 0.7042 0.0005; in the north, in the Nuanetsi syncline,rhyolites (age 206 13 m.y.) and granites from ring complexes(age 177 7 m.y.) have initial ratios of 0.7081 0.0008 and0.7085 0.0007, respectively. The initial ratios of the basicrocks, basalts and gabbros, vary in both areas and have a rangefrom 0.7042 to 0.7125 which can be explained by crustal contamination.The low initial ratios and isotopic homogeneity of the acidmagmas over long distances (160 km) in Swaziland and Zululandare interpreted as implying that they were derived from themantle.     

Origin and timing of the post-Variscan gabbro–granite complex of Porto (Western Corsica)

The post-Variscan complex of Porto consists of metaluminous to slightly peraluminous A-type biotite granites mingled with gabbro-dioritic rocks, and late dykes with basaltic to trachyandesitic composition. U-Pb zircon dating by LA-ICP-MS on two mafic intrusive samples constrains the time of the gabbro–granite crystallisation at 281 ± 3 Ma and 283 ± 2 Ma. Hornblende ⁴⁰Ar-³⁹Ar ages from a late trachyandesite dyke date the dyking event at 280 ± 2 Ma, which is within error the U-Pb zircon ages of the intrusives. Biotite granites show variable major and trace element compositions and similar initial ε_Nd (−0.3 to +0.9). Whole rock chemistry variations and trace element compositions of plagioclase and allanite indicate that the granites are genetically linked, essentially through fractional crystallisation of feldspars and minor allanite. On the basis of whole-rock chemistry e.g. initial ε_Nd +4.9 to +1.7 and trace element clinopyroxene compositions, we have ascertained that the mafic intrusives and basic dykes formed from isotopically depleted mantle source-derived melts with similar trace element signature. These basic melts experienced slightly different evolutionary histories, controlled by fractional crystallisation and crustal contamination, mainly by the acid magma that gave rise to the associated biotite granites, but also by the enclosing older Variscan granitoids. U-Pb zircon data suggest that the Porto complex was affected by hydrothermal fluid circulation at 259 ± 9 Ma.     

U–Pb TIMS age constraints on the evolution of the Neoproterozoic Meatiq Gneiss Dome,Eastern Desert,Egypt

Ages are used to constrain the temporal evolution of the Meatiq Gneiss Dome, Eastern Desert, Egypt, by dating (ID-TIMS) pre-, syn-, and post-tectonic igneous rocks in and around the dome. The Um Ba’anib Orthogneiss, comprising the deepest exposed structural levels of the dome, has a crystallization age of 630.8 ± 2 Ma. The overlying mylonites are interpreted to be a thrust sheet/complex (Abu Fannani Thrust Sheet) of highly mylonitized metasediments (?), migmatitic amphibolites, and orthogneisses with large and small tectonic lenses of less-deformed intrusives. Two syn-tectonic diorite lenses in this complex have crystallization ages of 609.0 ± 1.0 and 605.8 ± 0.9 Ma, respectively. The syn-tectonic Abu Ziran diorite, cutting across the tectonic contact between mylonite gneisses of the Abu Fannani Thrust Sheet and a structurally overlying thrust sheet of eugeoclinal rocks (“Pan-African nappe”), has a magmatic emplacement age of 606.4 ± 1.0 Ma. Zircons from a gabbro (Fawakhir ophiolite) within the eugeoclinal thrust sheet yielded a crystallization age of 736.5 ± 1.2 Ma. The post-tectonic Fawakhir monzodiorite intrudes the ophiolitic rocks and has an emplacement age of 597.8 ± 2.9 Ma. Two other post-tectonic granites, the Arieki granite that intrudes the foliated Um Ba’anib Orthogneiss, and the Um Had granite that cuts the deformed Hammamat sediments, have emplacement ages of 590 ± 3.1 and 596.3 ± 1.7 Ma, respectively. We consider formation of the Meatiq Gneiss Dome to be a young structural feature (<631 Ma), and our preferred tectonic interpretation is that it formed as a result of NE–SW shortening contemporaneous with folding of the nearby Hammamat sediments around 605–600 Ma, during oblique collision of East and West Gondwana.