Detrital zircon U–Pb ages and whole-rock geochemistry of the Neoproterozoic Paulistana and Santa Filomena complexes,Borborema Province,northeastern Brazil: implications for source area composition,provenance, and tectonic setting

The Paulistana and Santa Filomena Complexes are situated in the southern part of the Borborema Province (northeastern Brazil), in the Riacho do Pontal Orogen, and represent meta-volcano-sedimentary sequences. We present compositional variations in the metasedimentary rocks and new U–Pb detrital zircon data. Major and trace elements indicate that the metasedimentary rocks from the Paulistana and Santa Filomena Complexes are composed mostly of immature to mature sediments derived from felsic-intermediate sources with moderate to slightly high chemical weathering. The geochemical signatures of the sediment protoliths for both complexes are characteristic of continental magmatic arc settings with minor contribution from recycled sediment sources. The source area for the Paulistana Complex rocks follow the compositional trend between calc-alkaline granites and granodiorites, whereas the Santa Filomena Complex rocks have a more restricted composition trending to more granodioritic sources. For the Paulistana Complex, two main source ages were identified: (1) Tonian (ca. 950 Ma – sample RPE-58) and Tonian–Stenian (ca. 1.0 Ga – sample RPE-103). These data coupled with geochemical information suggest that the Cariris Velhos arc system was the main source area for the Paulistana Complex. Regarding the Santa Filomena metasedimentary rocks, potential source-areas include: (1) Neoarchaean rocks (~2.6 Ga) represented by the adjacent basement rocks of the Riacho do Pontal Orogen; (2) Rhyacian–Orosirian rocks (2.2–2.0 Ga) of the Riacho do Pontal Orogen and the Pernambuco–Alagoas terrain, which include an augen-gneiss with arc-related geochemical signature; (3) Statherian granites (1.7–1.6 Ga); and (4) Cariris Velhos crust (1000–920 Ma). The metasedimentary rocks of the Paulistana Complex were deposited in a rift stage (ca. 900 Ma), which is related to the break-up of the Rodinia supercontinent. The metasedimentary rocks of the Santa Filomena Complex most probably were deposited in another rift stage (ca. 750–700 Ma) and could be correlatives of the rift formation of the Canindé Domain (Sergipano Orogen).     

Reconstructing the Cryogenian–Ediacaran evolution of the Porongos fold and thrust belt,Southern Brasiliano Orogen,based on Zircon U–Pb–Hf–O isotopes

The Neoproterozoic geotectonic triad of the Brasiliano Orogen is reconstructed in southern Brazil from studies focused on the Porongos fold and thrust belt. We integrate field geology with isotopic studies of zircon U–Pb SHRIMP and Lu–Hf–O laser determinations in seven metasedimentary and three metavolcanic rock samples. The results indicate that the Porongos palaeo-basin was derived from mixed sources (3200–550 Ma), with major contributions from Rhyacian (2170 Ma) and Ediacaran (608 Ma) sources. Minor contributions from Archaean to Tonian sources are also registered. The maximum depositional age of the Porongos palaeo-basin is established by the age range of 650–550 Ma with T_DM model ages between 2.5 and 1.3 Ga. The reworked signature (ε_Hf values = ?34 to ?4) and the characteristic crustal magma reservoirs (δ¹⁸O ≥5.3 ‰) indicate that these sediments are equivalent to Neoproterozoic granites of the Dom Feliciano Belt. The episodic depositional history started in the Cryogenian (650 Ma) and lasted until the Ediacaran (most likely 570 Ma). A magmatic event of Tonian age is recorded in rhyodacite samples interleaved with the metasedimentary rocks and dated at 773, 801, and 809 Ma. The crustal evolution of the Sul-Riograndense Shield included mountain building, folding and thrusting and flexural subsidence in the foreland. An orogenic triad is revealed as the Pelotas Batholith, the Porongos fold and thrust belt and the Camaquã Basin, all part of the Dom Feliciano Belt.     

Mid to late Paleozoic shortening pulses in the Lachlan Orogen,southeastern Australia: a review

In the late Silurian, the Lachlan Orogen of southeastern Australia had a varied paleogeography with deep-marine, shallow-marine, subaerial environments and widespread igneous activity reflecting an extensional backarc setting. This changed to a compressional–extensional regime in the Devonian associated with episodic compressional events, including the Bindian, Tabberabberan and Kanimblan orogenies. The Early Devonian Bindian Orogeny was associated with SSE transport of the Wagga–Omeo Zone that was synchronous with thick sedimentation in the Cobar and Darling basins in central and western New South Wales. Shortening has been controlled by the margins of the Wagga–Omeo Zone with partitioning along strike-slip faults, such as along the Gilmore Fault, and inversion of pre-existing extensional basins including the Limestone Creek Graben and the Canbelego–Mineral Hill Volcanic Belt. Shortening was more widespread in the late Early Devonian to Middle Devonian Tabberabberan Orogeny, with major deformation in the Melbourne Zone, Cobar Basin and eastern Lachlan Orogen. In the eastern Melbourne Zone, structural trends have been controlled by the pre-existing structural grain in the adjacent Tabberabbera Zone. Elsewhere Tabberabberan deformation involved inversion of pre-existing rifts resulting in a variation in structural trends. In the Early Carboniferous, the Lachlan Orogen was in a compressional backarc setting west of the New England continental margin arc with Kanimblan deformation most evident in Upper Devonian units in the eastern Lachlan Orogen. Kanimblan structures include major thrusts and associated fault-propagation folds indicated by footwall synclines with a steeply dipping to overturned limb adjacent to the fault. Ongoing deformation and sedimentation have been documented in the Mt Howitt Province of eastern Victoria. Overall, structural trends reflect a combination of controls provided by reactivation of pre-existing contractional and extensional structures in dominantly E–W shortening operating intermittently from the earliest Devonian to Early Carboniferous.     

The lithospheric transition between the Delamerian and Lachlan orogens in western Victoria: new insights from 3D magnetotelluric imaging

The magnetotelluric (MT) method was used to image the crust and upper mantle beneath the Delamerian and Lachlan orogens in western Victoria, Australia. During the Cambrian time period, this region changed from being the extended passive margin of Proterozoic Australia into an Andean-style convergent margin that progressively began to accrete younger oceanic terranes. Several broadband MT transects, which were collected in stages along coincident deep (full crust imaging) seismic reflection lines, have now been combined to create a continuous 500 km east–west transect over the Delamerian–Lachlan transition region in the Stawell Zone. We present the electrical resistivity structure of the lithosphere using both 3D and 2D inversion methods. Additionally, 1D inversions of long-period AusLAMP (Australian Lithospheric Architecture Magnetotelluric Project) MT data on a 55 km regionally spaced grid were used to provide starting constraints for the 3D inversion of the 2D profile. The Delamerian to Lachlan Orogen transition region coincides with the Mortlake Discontinuity, which marks an isotopic discontinuity in Cenozoic basalts, with higher strontium isotope enrichment ratios in the Lachlan Orogen relative to the Delamerian Orogen. Phase tensor ellipses of the MT data reveal a distinct change in electrical resistivity structure near the location of the Mortlake Discontinuity, and results of 3D and 2D inversions along the MT profile image a more conductive lower crust and upper mantle beneath the Lachlan Orogen than the Delamerian Orogen. Increased conductivity is commonly ascribed to mantle enrichment and thus supports the notion that the isotope enrichment of the Cenozoic basalts at least partially reflects an enriched mantle source rather than crustal contamination. Fault slivers of the lower crust from the more conductive Lachlan region expose Cambrian boninites and island arc andesites indicative of subduction, a process that can enrich the mantle isotopically, and also electrically, by introducing carbon (graphite) and water (hydrogen).     

甘肃大佛寺、金佛寺花岗岩体的锆石U-Pb年龄、Hf-O同位素和全岩地球化学特征及地质意义

走廊过渡带大佛寺花岗岩为弱过铝质(A/CNK=1.03~1.06),SiO_2(76.7%~78.9%)、全碱(Na2O+K2O=7.7%~8.3%)、Rb(303×10~(-6)~383×10~(-6))、Nb(32×10~(-6)~42×10~(-6))、重稀土(Yb~8×10~(-6))含量以及和FeOT/MgO(6.3~7.6)、Ga/Al(3×10-4)、Rb/Ba(3.0~6.2)比值较高,MgO(~0.1%)、CaO(0.5%~0.6%)含量较低,Ba、Sr、Eu、Ti强烈亏损,属A型花岗岩,其源岩可能为泥质岩。大佛寺花岗岩中锆石δ18O和εHf(t)值分别为7.8‰~8.6‰(平均8.24±0.13‰)和-4.8~-2.0,Hf同位素两阶段亏损地幔模式年龄1540~1717Ma,岩浆温度达到~820℃以上。北祁连造山带北缘金佛寺花岗岩为过铝质(A/CNK=1.0~1.1),SiO_2(65.5%~75.0%)、MgO(0.6%~2.2%)、Fe2O3(1.9%~5.2%)、TiO_2(0.3%~0.8%)含量变化较大,其主量和微量元素特征与北祁连造山带的柴达诺花岗岩相似,源岩可能包括杂砂岩和角闪岩。金佛寺花岗岩的锆石δ18O为7.4%~9.7‰(平均8.03±0.36‰),εHf(t)在-0.5~+1.9之间,Hf同位素两阶段亏损地幔模式年龄为1289~1439Ma,岩浆温度达到800~900℃。走廊过渡带大佛寺花岗岩、北祁连造山带北缘金佛寺花岗岩的锆石U-Pb SIMS年龄分别为426.1±2.8Ma、424.0±1.6Ma,不同构造单元发育同时期岩浆活动以及A型花岗岩的出现,表明在~425Ma北祁连洋盆已经闭合,北祁连造山带及邻区进入到后碰撞拉伸阶段。     

江南造山带东段九岭新元古代复式花岗岩源区性质的差异:来自地球化学及锆石Hf同位素的制约

江南造山带东段九岭新元古代花岗岩据其岩石学及野外产出特征可分为3个序次的侵入体,由早到晚依次为黑云母花岗闪长岩、英云闪长岩及黑云母二长花岗岩。本次研究的黑云母花岗闪长岩和英云闪长岩中等富硅(SiO_2分别为66.05%~75.78%和67.36%~73.94%),而黑云母二长花岗岩极富硅(SiO_2为73.96%~77.83%)。三者铝饱和指数A/CNK分别为1.53、1.71和1.32,A/NK分别为2.04、2.0和1.39,均显示典型过铝质花岗岩特征;三类岩石单元主体属高钾钙碱性系列。黑云母花岗闪长岩和英云闪长岩SiO_2与MgO、TiO_2、CaO、Fe_2O_3T、Al_2O_3、MnO、V成负相关,但黑云母二长花岗岩这种相关性不明显。黑云母花岗闪长岩和英云闪长岩均富轻稀土元素,(La/Yb)N分别平均为10.1和18.7,具弱Eu负异常(δEu分别为0.11～0.88和0.30～0.72),而黑云母二长花岗岩轻重稀土分馏弱((La/Yb)N=4.70),强烈Eu负异常(δEu=0.18～0.61)。三类岩石均富集大离子亲石元素Cs、Rb、Th、U、K、Pb,明显亏损高场强元素Nb、Ta、Sr、Ti,且锆石εHf(t)变化范围极大,分别介于-6.76～9.22、-1.08～6.63和-0.64～7.96之间。研究区北西侧和南东侧岩体锆石Hf同位素组成存在明显差异,表现为岩体北西部的锆石εHf(t)变化范围高于南东部,锆石tDM2模式年龄多集中在1.6～1.8Ga。综合研究推断本区黑云母花岗闪长岩、黑云母二长花岗岩的源区分别为砂质上地壳和泥质上地壳部分熔融产物,而英云闪长岩则为砂泥质源区部分熔融产物。同时,SE侧岩浆起源深度和岩体剥蚀程度均高于NW侧,且SE侧岩体的成岩时代也略早于NW侧,这暗示了新元古代华夏板块和扬子板块碰撞后的伸展过程中,研究区SE侧岩浆起源深度较深,且形成时代较早,并逐渐向NW侧迁移。另外,花岗质岩石源区由砂质向泥质转变的过程可能也是区域陆壳伸展作用逐渐增大的结果。     

青藏高原腹地中新世从造山阶段向造高原阶段的转变及其动力学机制

通过对前人研究的综述,发现青藏高原新生代地质演化与高原东南缘构造演化密切相关.俯冲下插的印度地壳在藏南发生部分熔融并注入青藏高原中部地壳,这些塑性流变的地壳物质在高原东南缘先后沿两个通道流出高原内部：早期为印支通道,开放时间为35 Ma以前并持续到12 Ma;后期为川滇通道,开放时间为12 Ma至今.由于喜马拉雅东构造结与四川盆地之间强烈的挤压,印支通道不断变窄,并在12 Ma被关闭.两个通道的差异,通道的打开和关闭,造成高原中地壳物质流出速率在中新世发生明显变化,在23 Ma以来流出速率小于注入速率,在12 Ma流出速率最小,部分熔融的印度地壳物质不断滞留于高原地壳内部,使得地势相对平坦、面积巨大的青藏高原逐渐形成并分别向南和向北扩展.通过简单的力学分析,本文将高原腹地变形划分为两个阶段：大于35~23 Ma的造山阶段,受控于造山机制;23 Ma至今的造高原阶段,受控于造高原机制.     

赣北景德镇韧性剪切带两类剪切指向及其构造意义

景德镇韧性剪切带位于新元古代江南造山带的核部,其构造变形特征和形成时代对华南新元古代至早古生代构造演 化具有重要的制约意义。景德镇韧性剪切带呈北东向展布,全长约180 km,最大出露宽度为~7 km。通过详细的野外地质 调查和室内定向薄片鉴定,在景德镇韧性剪切带中识别出了两期韧性走滑构造变形,并研究了其运动学指向和形成时的温 压条件。早期构造变形表现为左旋韧性走滑兼逆冲作用,形成温度为420~530℃,差应力为40~300 MPa;晚期变形主要表 现为右旋走滑,形成温度为300~420℃,差应力为120~350 MPa。结合前人资料,景德镇韧性剪切带左旋走滑兼逆冲作用形 成于新元古代造山作用的晚期（810~800 Ma）,是由同造山挤压到后造山伸展调整的结果;而右旋走滑形成于早古生代,是 华南早古生代陆内造山作用的产物。     

东秦岭寨凹钼矿床辉钼矿Re-Os同位素年龄及熊耳期成矿事件

河南寨凹钼矿床位于东秦岭钼矿带,是近年来新发现的脉状钼矿床.9件辉钼矿样品Re-Os模式年龄介于1603.1±10.8～2031.9±10.2Ma,其中7件样品给出了精确的等时线年龄为1762±31Ma(1σ误差,MSWD=3.6),模式年龄的加权平均值为1753±26Ma(1σ误差,MSWD=3.2),表明寨凹钼矿形成于古元古代或熊耳期,代表着～1.76Ga左右的钼成矿事件.根据区域地质演化,认为寨凹钼矿形成于与熊耳群弧火山岩建造相当的活动大陆边缘岩浆弧背景.寨凹矿床的发现表明,熊耳期成矿事件虽遭受后期多次增生和碰撞造山作用的改造和破坏,但仍可在秦岭造山带最北部保留.     

Guandishan Granitoids of the Paleoproterozoic Lüliang Metamorphic Complex in the Trans-North China Orogen: SHRIMP Zircon Ages, Petrogenesis and Tectonic Implications

Abstract: The Paleoproterozoic Lüliang Metamorphic Complex (PLMC) is situated in the middle segment of the western margin of the Trans-North China Orogen (TNCO), North China Craton (NCC). As the most important lithological assemblages in the southern part of the PLMC, Guandishan granitoids consist of early gneissic tonalities, granodiorites and gneissic monzogranites, and younger gneissic to massive monzogranites. Petrochemical features reveal that the early gneissic tonalities and granodiorites belong to the medium-K calc-alkaline series; the early gneissic monzogranites are transitional from high-K calc-alkaline to the shoshonite series; the younger gneissic to massive monzogranites belong to the high-k calc-alkaline series, and all rocks are characterized by right-declined REE patterns and negative Nb, Ta, Sr, P, and Ti anomalies in the primitive mantle normalized spidergrams. SHRIMP zircon U–Pb isotopic dating reveals that the early gneissic tonalities and granodiorites formed at ~2.17 Ga, the early gneissic monzogranites at ~2.06 Ga, and the younger gneissic to massive monzogranites at ~1.84 Ga. Sm–Nd isotopic data show that the early gneissic tonalities and granodiorites have εNd(t) values of +0.48 to ?3.19 with Nd-depleted mantle model ages (TDM) of 2.76–2.47 Ga, and early gneissic monzogranites have εNd(t) values of ?0.53 to ?2.51 with TDM of 2.61–2.43 Ga, and the younger gneissic monzogranites have εNd(t) values of ?6.41 to ?2.78 with a TDM of 2.69–2.52 Ga.These geochemical and isotopic data indicate that the early gneissic tonalities, granodiorites, and monzogranites were derived from the partial melting of metamorphosed basaltic and pelitic rocks, respectively, in a continental arc setting. The younger gneissic to massive monzogranites were derived by partial melting of metamorphosed greywackes within the continental crust. Combined with previously regional data, we suggest that the Paleoproterozoic granitoid magmatism in the Guandishan granitoids of the PLMC may provide the best geological signature for the complete spectrum of Paleoproterozoic geodynamic processes in the Trans-North China Orogen from oceanic subduction, through collisional orogenesis, to post-orogenic extension and uplift.