An apatite U-Pb thermal history map for the northern Gawler Craton,South Australia

Apatite U-Pb thermochronology was applied to granitoid basement samples across the northern Gawler Craton to unravel the Proterozoic, post-orogenic, cooling history and to examine the role of major fault zones during cooling. Our observations indicate that cooling following the ~2500 Ma Sleaford Orogeny and ~1700 Ma Kimban Orogeny is restricted to the Christie and Wilgena Domains of the central northern Gawler Craton. The northern Gawler Craton mainly records post-Hiltaba Event(~1590 Ma) U-Pb cooling ages. Cooling following the ~1560 Ma Kararan Orogeny is preserved within the Coober Pedy Ridge,Nawa Domain and along major shear zones within the south-western Fowler Domain. The Nawa Domain samples preserve U-Pb cooling ages that are >150 Ma younger than the samples within the Coober Pedy Ridge and Fowler Domain, indicating that later(~1300 Ma) fault movement within the Nawa Domain facilitated cooling of these samples, caused by arc collision in the Madura Province of eastern Western Australia. When compared to^(40)Ar/^(39) Ar from muscovite, biotite and hornblende, our new apatite U-Pb ages correlate well, particularly in regions of higher data density. Our data also preserve a progressive younging of U-Pb ages from the nucleus of the craton to the periphery with a stark contrast in U-Pb ages across major structures such as the Karari Shear Zone and the Southern Overthrust, which indicates the timing of reactivation of these major crustal structures. Although this interpolation was based solely on thermochronological data and did not take into account structural or other geological data, these maps are consistent with the structural architecture of the Gawler Craton and reveal the thermal footprint of known tectonic and magmatic events in the Gawler Craton.

Zircon and Apatite U-Pb Geochronology and Geochemistry of the Mafic Dykes in the Shuangxiwu Area, Northwestern Zhejiang Province: Constraints on the Initial Time of Neoproterozoic Rifting in South China

Previous studies have shown that there are some ca.770–750 Ma mafic dykes at the western segment of the Neoproterozoic Jiangnan orogen(JO),and they represent post-orogenic magmatism due to orogenic collapse(Wang

Application of Detrital Apatite U-Pb Geochronology and Trace Elements for Provenance Analysis,Insights from a Study on the Yarlung River Sand

Detrital U-bearing minerals(e.g.,zircon,apatite)U-Pb ages with specific trace-element geochemistry,are frequently used in provenance analyses.In this study,we focus on the Yarlung River drainage in South Tibet,characterized by two distinct lithologic units:The Gangdese batholith to the north(mainly granitoids)and the Tethyan Himalaya(mainly sedimentary rocks)to the south,which plays a crucial role in the erosion of the Tibetan Plateau.To constrain the provenance of the Yarlung River Basin,we performed trace-element and U-Pb age analyses of detrital apatite from the river sands of the Yarlung River and its tributaries.Our findings indicate that the detrital apatite U-Pb age patterns of the north tributaries exhibit main peaks at approximately 40 and 60 Ma,consistent with the corresponding U-Pb age patterns of detrital zircon published.Further,their trace element casts fall mainly in the Type I granite region,also indicating the Gangdese arc-dominated source.However,those of the south tributaries(∼60–20 Ma)exhibit a different age distribution from the detrital zircon U-Pb groups(∼110–150,∼500,and 1100 Ma),suggesting that the detailed apatite U-Pb signals can provide excellent constraints on the provenance of igneous and metamorphic rock sources but less so for sedimentary rock sources.Combined with previous detrital zircon data in the study area,our detrital apatite information can highlight young metamorphic events from a complex background(i.e.,Niyang and Nianchu rivers),which offers additional constraints on the provenance of the Yarlung River Basin.Generally,a combination of geochemistry and geochronology of multi-detrital heavy minerals,such as zircon and apatite,can provide powerful tools for provenance analysis.

Combined garnet,scheelite and apatite U-Pb dating of mineralizing events in the Qiaomaishan Cu-W skarn deposit,eastern China

Determining the precise timing of mineralization and mineralizing events is crucial to understanding regional mineralizing and other geological events and processes.However,there are a number of mineralogical and analytical limitations to the approaches developed for the absolute dating of mineralizing systems,such as molybdenite Re-Os and zircon and garnet U-Pb,among others.This means that the precise and accurate dating of mineralizing systems that may not contain minerals suitable for dating using existing approaches requires the development of new(and ideally in situ)approaches to absolute dating.This study outlines a new in situ analytical approach that has the potential to rapidly and accurately evaluate the timing of ore formation.Our study employs a novel application of in situ scheelite U-Pb dating analysis using laser ablation-inductively coupled plasma-mass spectrometry(LA-ICP-MS)and samples from the Qiaomaishan deposit,a representative example of skarn mineralization within the Xuancheng ore district of eastern China.Our approach to scheelite dating of the deposit is verified by cross-comparison to dating of cogenetic garnet and apatite,proving the effectiveness of this approach.Our new approach to dating of scheelite-bearing geological systems is rapid,cheap,requires little sample preparation,and is undertaken in situ,allowing crucial geological and mineralogical context to be retained during analysis.The approaches outlined here not only allow the determination of the absolute timing of formation of the Qiaomaishan deposit through the U-Pb dating of scheelite[138.6±3.2 Ma,N=39,mean square weighted deviation(MSWD)=1.17],garnet(138.4±1.0 Ma,N=40,MSWD=1.3),and apatite(139.6+3.3 Ma,N=35,MSWD=0.72),but also further supports the theoretical genetic links between this mineralization and the emplacement of a proximal porphyritic granodiorite intrusion(zircon U-Pb age:139.5±1.2 Ma,N=23,MSWD=0.3).Moreover,our research indicates that the higher the concentrations of U within scheelite,the more suitable that scheelite is for U-Pb dating,with the main factor controlling the U content of scheelite seemingly being variations in oxygen fugacity conditions.This novel approach provides a potentially powerful tool,not just for the dating of skarn systems but also with potential applications in orogenic and intrusion-related gold,porphyry W-Mo,and greisen mineralizing systems as well as other scheelite-bearing geological bodies or geological systems.

Mineral Geochemistry of Apatite in the Jiama PorphyrySkarn Deposit,Tibet and its Geological Significance

The Jiama deposit,a significant porphyry-skarn-type copper polymetallic deposit located within the Gangdese metallogenic belt in Tibet,China,exemplifies a typical porphyry metallogenic system.However,the mineral chemistry of its accessory minerals remains under-examined,posing challenges for resource assessment and ore prospecting.Utilizing electron microprobe analysis and LA-ICP-MS analysis,this study investigated the geochemical characteristics of apatite in ore-bearing granite and monzogranite porphyries,as well as granodiorite,quartz diorite,and dark diorite porphyries in the deposit.It also delved into the diagenetic and metallogenic information from these geochemical signatures.Key findings include:(1)The SiO_(2) content,rare earth element(REE)contents,and REE partition coefficients of apatite indicate that the dark diorite porphyry possibly does not share a cogenetic magma source with the other four types of porphyries;(2)the volatile F and Cl contents in apatite,along with their ratio,indicate the Jiama deposit,formed in a collisional setting,demonstrates lower Cl/F ratios in apatite than the same type of deposits formed in a subduction environment;(3)compared to non-ore-bearing rock bodies in other deposits formed in a collisional setting,apatite in the Jiama deposit exhibits lower Ce and Ga contents.This might indicate that rock bodies in the Jiama deposit have higher oxygen fugacity.Nevertheless,the marginal variation in oxygen fugacity between ore-bearing and non-ore-bearing rock bodies within the deposit suggests oxygen fugacity may not serve as the decisive factor in the ore-hosting potential of rock bodies in the Jiama deposit.

Apatite Fission Track Thermochronology of Granite from the Xiazhuang Uranium Ore Field,South China:Implications for Exhumation History and Ore Preservation

Xiazhuang uranium ore field,located in the southern part of the Nanling Metallogenic Belt,is considered one of the largest granite-related U regions in South China.In this paper,we contribute new apatite fission track data and thermal history modeling to constrain the exhumation history and evaluate preservation potential of the Xiazhuang Uranium ore field.Nine Triassic outcrop granite samples collected from different locations of Xiazhuang Uranium ore field yield AFT ages ranging from 43 to 24 Ma with similar mean confined fission track lengths ranging from 11.8±2.0 to 12.9±1.9μm and Dpar values between 1.01 and 1.51μm.The robustness time-temperature reconstructions of samples from the hanging wall of Huangpi fault show that the Xiazhuang Uranium ore field experienced a time of monotonous and slow cooling starting from middle Paleocene to middle Miocene(~60-10 Ma),followed by relatively rapid exhumation in the late Miocene(~10-5 Ma)and nearly thermal stability in the Pliocene-Quaternary(~5-0 Ma).The amount of exhumation after U mineralization since the Middle Paleogene was estimated as~4.3±1.8 km according to the integrated thermal history model.Previous studies indicate that the ore-forming ages of U deposits in the Xiazhuang ore field are mainly before Middle Paleocene and the mineralization depths are more than 4.4±1.2 km.Therefore,the exhumation history since middle Paleocene plays important roles in the preservation of the Xiazhuang Uranium ore field.

Apatite Fission-Track Thermochronology in the Tamusu Area,Bayingobi Basin,NW China,and its Geological Significance

The Bayingobi basin is located in the middle of Central Asia Orogenic Belt,at the intersection of Paleo-Asian Ocean and Tethys Ocean,as well as the junction of multiple tectonic plates.This unique tectonic setting underpins the basin's intricate history of tectonic activity.To unravel the multifaceted tectono-thermal evolution within the southwestern region of the basin and to elucidate the implications of sandstone-hosted uranium mineralization,granitic and clastic rock samples were collected from the Zongnai Mts.uplift and Yingejing depression,and apatite fission track(AFT)dating and thermal history simulation analysis were performed.AFT dating findings reveal that the apparent ages of all samples fall within the range of 244 Ma to 112 Ma.In particular,the bedrock of the Zongnai Mts.and Jurassic detrital apatite fission tracks have undergone complete annealing,capturing the uplift-cooling age.Meanwhile,the AFT ages of Cretaceous detrital rocks are either equivalent to or notably exceed the age of sedimentary strata,signifying the cooling age of the provenance.A comprehensive examination of AFT ages and palaeocurrent direction analyses suggests that the Cretaceous source in the Tamusu area predominantly originated from the central and southern sectors of the Zongnai Mts.uplift.However,at a certain juncture during the Late Early Cretaceous,the Cretaceous provenance expanded to include the northern part of the Zongnai Mts.uplift.Based on the results of thermal history simulations and previous studies,it is considered that the Tamusu area has undergone four distinct tectonic uplift events since the Late Paleozoic.The first is the Late Permian to Early Triassic(260-240 Ma),which is associated with the closure of the Paleo-Asian Ocean and the accretionary orogeny within the Alxa region.The second uplift event took place in the Early Jurassic(190-175 Ma)and corresponded to intraplate orogeny following the closure of the Paleo-Asian Ocean.The third uplift event is the Late Jurassic to Early Cretaceous(160-120 Ma),which is linked to the East Asia's position as the convergence center of multiple tectonic plates during this period.The fourth uplift event is linked to the Late Early Cretaceous(112-100 Ma),driven either by the westward subduction of the eastern Pacific plate or the mantle upwelling resulting from the Bangong-Nujiang oceanic lithosphere subduction and slab break-off.The primary stress orientation for the first three tectonic uplift phases approximated a nearly SN direction,while the fourth stage featured a principal stress direction of NW.The fourth tectonic uplift event of the Late Early Cretaceous and basaltic eruption thermal event during this period likely exerted a significant influence on the formation of the Tamusu sandstone-hosted uranium deposit.

东昆仑大格勒农场南辉长岩锆石U-Pb年代学、地球化学特征及地质意义

东昆仑志留纪岩浆活动强烈,记录了东昆仑造山带原特提斯洋演化晚期大洋俯冲阶段与碰撞阶段转换地质过程。本次研究对东昆仑大格勒农场南志留纪基性侵入岩开展了详细的岩相学、岩石地球化学、锆石U-Pb年代学和Hf同位素研究,以确定其形成时代、岩石成因和构造环境。研究结果表明大格勒农场南辉长岩的结晶年龄为430.2±2.4 Ma,形成时代为中志留世。辉长岩SiO_(2)(51.40%~53.66%)含量较低,MgO(18.56%~22.16%)和FeO^(T)(7.54%~10.64%)含量高,Mg^(#)为79~82。微量元素富集Rb、Th、Ba、Cs等大离子亲石元素(LILE),亏损Nb、Ta、Ti等高场强元素(HFSE),具有高Ni(276~973μg/g)、Cr(2152~3574μg/g)和Sc(35.5~53.1μg/g)含量,低Nb/Ta值(3.23~8.68)和εHf(t)值(-7.3~-3.6)。大格勒农场南辉长岩的地球化学组成具有岛弧基性岩特征,其成因可能是流体和俯冲沉积物加入的富尖晶石橄榄岩部分熔融的结果。综合区域资料表明,大格勒农场南辉长岩形成于东昆仑原特提斯洋俯冲晚期阶段,进一步限定原特提斯洋晚期俯冲与碰撞转换时限为中志留世,随后转入碰撞造山阶段。

海南岛抱板杂岩记录的多期构造热事件:锆石和独居石U-Pb年代学的制约

抱板杂岩(抱板群)是海南岛目前已发现的最古老前寒武纪结晶基底,记录了多期构造热事件,是研究海南岛大地构造属性的重要窗口。本文通过对海南岛冲卒岭地区抱板杂岩变质沉积岩、变质基性岩和伟晶岩脉的锆石和独居石LA-ICP-MS U-Pb年代学研究,来确定抱板杂岩所经历的多期构造热事件及其所代表的构造意义。研究结果显示,抱板杂岩主要由中元古代变质沉积岩、花岗质片麻岩和变质基性岩组成,经历了中元古代晚期-新元古代早期(1.3~0.9Ga)、早古生代(470~440Ma)、三叠纪(~230Ma)等多期构造热事件的改造。中元古代晚期-新元古代早期构造热事件与罗迪尼亚超大陆的汇聚有关;早古生代构造热事件与东冈瓦纳古陆北缘的增生造山作用有关;三叠纪构造热事件是印支陆块与华南陆块碰撞拼合的远程响应。综合上述研究成果和区域对比分析,认为海南岛与印支陆块具有相似的前寒武纪结晶基底和多期构造热事件的记录,表明二者具有明显的亲缘关系。

柴达木盆地古近系下干柴沟组上段碎屑锆石U-Pb测年及盆山耦合探讨

柴达木盆地被祁连山、阿尔金山及昆仑山所环绕,盆地古近系下干柴沟组(E32)地层独特的岩性和沉积格局指示了复杂盆山体系和源区多样成因。本文选取了盆地内部不同构造带5口钻井下干柴沟组的中粗砂岩样品,利用碎屑锆石U-Pb定年等分析方法对柴达木盆地进行了构造、物源系统分析。研究结果表明,位于祁连山前的XX-1井样品下干柴沟组锆石年龄介于2692~156Ma之间,主要峰值年龄为448Ma和249Ma,L6-1井样品锆石年龄介于2693~220Ma之间,主要峰值年龄为499Ma和415Ma;位于盆地西部沉降中心内部的YIT-1井样品下干柴沟组锆石年龄介于2796~266Ma之间,主要峰值年龄为423Ma和255Ma;阿尔金山前的N-105井样品下干柴沟组锆石年龄介于2481~242Ma之间,主要峰值年龄为422Ma和259Ma,N-109井样品锆石年龄介于2638~228Ma之间,主要峰值年龄为444Ma和246Ma。通过与主要源区年龄对比可知,盆地不同构造带下干柴沟组的物源差异较大,靠近祁连山前的XX-1井、L6-1井的物源主要来自于祁连山内部;位于阿尔金山前相邻的N-105、N-109井物源主体来自于阿尔金山内部,但N-109井存在祁连山物源贡献;柴西坳陷内部YIT-1井物源受祁连山及东昆仑共同控制。物源分析结果表明祁连山在古近纪已大规模隆升,并且作为青藏高原北部边界为柴达木盆地持续提供物源;阿尔金山及昆仑山在下干柴沟组沉积时期已经形成雏形,但并未大规模隆升,造成了山前带复杂的物源体系。

激光剥蚀-扇形磁场电感耦合等离子体质谱法同时测定锆石U-Pb年龄和微量元素含量

激光剥蚀-扇形磁场电感耦合等离子体质谱(LA-SF-ICP-MS)具有高灵敏度特征,被广泛应用于锆石等含U矿物原位微区U-Pb定年研究,但磁偏转式质量分析器的使用导致该质谱仪扫描速度相对较慢,可能影响U-Pb同位素与其他关键微量元素的同时采集。本文通过优化仪器信号稳定性和实验方法,对目前常用的7种锆石U-Pb标准样品进行U-Pb定年和Ti、REEs、Hf等关键元素同时定量分析,探讨了多元素同时分析方法的可行性及对于U-Pb定年结果的影响。实验结果表明,相对于LA-SF-ICP-MS仅检测U-Pb同位素方法,同时开展多元素含量检测可能会使U-Pb同位素信号强度稳定性下降,导致单点U-Pb年龄结果误差及离散程度增大。与仅测定U-Pb同位素年龄的测定结果相比较,根据不同锆石样品中U-Pb同位素含量高低,多元素同时检测获得分析点的206Pb/238U年龄和207Pb/235U年龄变化范围不同程度地增大,其中207Pb/235U年龄受影响明显,单点207Pb/235U年龄误差从~1.5%增大至~2.0%,单点年龄的相对标准偏差(RSD)从0.5%~1.3%增大至1.2%~3.3%。尽管如此,多元素同时检测方法对于各样品最终测定年龄没有明显的影响,相对于TIMS年龄,各样品的谐和年龄和206Pb/238U加权平均年龄偏差分别小于1.0%和0.7%,完全满足U-Pb同位素地质年代学测试要求。同时测定锆石样品中的关键微量元素含与其推荐值相对误差小于10%。因此,采用LA-SF-ICP-MS可以同时准确地测定锆石U-Pb年龄和微量元素含量,该方法亦可用于其他副矿物U-Pb年龄与关键微量元素同时测定。

甘肃北山南部早古生代古亚洲洋俯冲作用:来自明舒井埃达克质侵入体锆石U-Pb年龄及地球化学的证据

甘肃北山南部具有重要的构造位置与复杂的构造演化历史,制约着北山造山带大地构造归属研究。北山明舒井埃达克质侵入体位于南部辉铜山以西地区,岩性主要为二长花岗岩、正长花岗岩、花岗闪长岩、石英闪长岩等。对明舒井侵入体中的二长花岗岩、正长花岗岩和花岗闪长岩进行LA-ICP-MS锆石U-Pb测年,定年结果分别为423.4±3.4 Ma、425.4±2.3 Ma和437.8±3.5 Ma。岩石SiO2含量多数大于56%(55.53%~64.42%),Al2O3大于15%(15.1%~17.79%),MgO多数小于3%,全部小于6%(2.07%~3.5%),Y和Yb含量均较低,同时轻稀土元素富集,Eu异常不明显,Sr含量较高,具有与埃达克岩相似的特征。综合区域地质背景,认为北山南部志留纪埃达克质侵入岩形成于活动大陆边缘火山弧环境,可能是志留纪古亚洲洋向北消减俯冲背景下岩浆作用的产物,同时发生了大规模的地壳增生。明舒井埃达克质侵入岩体的识别为北山造山带早古生代构造演化提供了重要依据。

甘肃北山铭杨镁铁-超镁铁岩体锆石U-Pb年龄、地球化学特征及其地质意义

铭杨岩体位于甘肃北山南带古堡泉-红柳园断裂北侧,侵位于敦煌岩群,为甘肃北山地区新近发现的一处铜镍矿化镁铁-超镁铁岩体,主要由辉橄岩、二辉橄榄岩、橄榄辉长岩、辉长岩等组成。全岩成分以低碱、低钛为特征,轻稀土略富集,具有明显的正Eu异常;富集大离子亲石元素(LILE)Rb、Ba、Sr和K,相对亏损高场强元素(HFSE)Th、U、Nb、Ta、Zr和Hf。岩浆演化过程中发生了橄榄石、斜长石和辉石的分离结晶作用,经历了一定程度的地壳混染,地、物、化、遥综合信息显示具有较好的铜镍成矿潜力。通过LA-ICP-MS锆石U-Pb测年,首次获得铭杨岩体中橄榄辉长岩和辉长岩结晶年龄分别为(452.9±2.4)Ma和(457.7±2.1)Ma,岩体可能为早古生代陆缘裂谷环境下的产物。北山地区早古生代含铜镍岩体的发现对区域构造演化认识具有重要意义。

江西九岭南缘古阳寨地区铍矿化伟晶岩独居石U-Pb定年及其地质意义

以江西九岭南缘古阳寨地区铍矿化伟晶岩为研究对象,选取规模较大的藏龙洞铍矿化伟晶岩脉,通过野外地质调查和LA-ICP-MS测定独居石U-Pb年龄测定,初步了解了九岭南缘古阳寨地区花岗伟晶岩地质特征。结果表明,九岭南缘古阳寨地区铍矿化伟晶岩成岩成矿年龄为(138.57±0.78) Ma,归属于早白垩世。铍矿化伟晶岩侵入于九岭南缘古阳寨中细粒含斑二云母二长花岗岩体内部,形成时代略晚于燕山期古阳寨岩体,显示两者在空间和时间上具有密切的成因联系,推测古阳寨地区铍矿化伟晶岩为古阳寨岩体二云母二长花岗岩结晶分异而成。建议针对古阳寨二云母二长花岗岩体内部和外接触带0~5 km范围内,加强调查力度,以期实现该区域内伟晶岩型铍矿找矿突破。

辽东地区赛马碱性杂岩锆石U-Pb年龄、Hf同位素组成及其对构造背景的制约

通过LA-ICP-MS测得辽宁赛马地区浅肉红色霞霓正长岩中的锆石U-Pb年龄为225.8±1.9 Ma,赛马碱性杂岩的侵位时代为晚三叠世。地球化学分析表明,霞霓正长岩SiO_(2)含量为55.87%~60.88%,Na_(2)O为0.41%~5.32%,Al_(2)O_(3)为17.81%~19.53%,K_(2)O为9.46%~11.91%,MgO为0.46%~1.36%,里特曼指数为7.54~17.01;稀土元素总量较高,高于300×10^(-6),强烈富集轻稀土元素,(La/Yb)N值大于10,个别达到100以上;亏损Nb、Ta、P等高场强元素,富集Rb、Th等大离子亲石元素,总体表现出富碱性岩石特征。锆石ε_(Hf)(t)值为-13.37~-9.30,对应的两阶段Hf模式年龄T_(DM2)为2102~1855 Ma。通过岩石成因分析和构造环境判别,赛马碱性杂岩可能形成于由俯冲挤压向陆内伸展、拉张转换的动力背景下的下地壳(或上地幔)部分熔融。赛马碱性杂岩侵位时代(225.8±1.9 Ma)可能代表了华北克拉通北缘岩石圈开始伸展减薄的时间,也是郯庐断裂形成的时间。

华北克拉通栖霞地区~2.9Ga变质基性火山岩锆石SHRIMP U-Pb定年、Hf-O同位素特征及构造意义

胶东地区是华北克拉通重要的早前寒武纪研究区之一。中太古代唐家庄岩群在形成时代、岩石成因及构造环境等方面一直少有研究。作者在栖霞地区对出露的唐家庄岩群变质表壳岩进行系统地质调查研究基础上,开展了变质基性火山岩全岩地球化学、锆石SHRIMP U-Pb和Hf-O同位素等分析研究。结果显示,变质基性火山岩岩浆锆石年龄为2907.9±6.3Ma,代表了中太古代唐家庄岩群的形成时间,并遭受新太古代早、晚期变质作用。这是~2.9Ga唐家庄岩群变质基性火山岩在胶东地区首次报道。岩石地球化学特征表现为相对富集大离子亲石元素K、Rb、Sr等,Th、Nb、Zr、Hf等高场强元素相对亏损,具有中等分异的REE配分模式。岩石中岩浆锆石具有相似的Hf、O同位素组成,εHf(t)值介于-0.68~+4.21,δ18 O值介于1.38‰~6.73‰。结合前人的工作,我们得出的主要结论如下:(1)胶东地区经历~2.9Ga岩浆事件,局部地段仍保留下了同时期的变质表壳岩;(2)唐家庄岩群是中太古代初始的洋盆环境中所形成的一套火山-沉积建造;(3)华北克拉通中太古代晚期是亏损地幔新生地壳加积的主要时期,局部地壳再循环了较老的陆源物质;(4)华北克拉通新太古代晚期经历了伸展构造背景,岩浆底侵作用使岩石发生强烈变质作用。

贵东复式岩体中东部晚期花岗质小岩体的SHRIMP锆石U-Pb年龄及其地质意义

贵东复式岩体由多期次、多类型的岩体组成,且东部盛产铀矿床,因此精确厘定该复式岩体的时代及其时序,查明复式岩体东部与中西部岩浆活动的差异性及其与铀成矿的关系,不仅有利于深入研究区域岩浆活动,而且有利于深刻认识铀的成矿规律。现有研究认为,以龟尾山断裂带为界,贵东复式岩体中西部岩基属燕山早期、东部岩基属印支早期,东部广泛发育的燕山期中基性脉岩与铀成矿关系密切。但对复式岩体中东部呈岩枝、岩株广泛出露的晚期花岗质小岩体的成岩地质时代及其分布规律尚存在争议,也有待进一步查明花岗质小岩体与铀矿床的时空关系。文章选择贵东复式岩体中东部晚期花岗质小岩体为研究对象,采用SHRIMP锆石U-Pb法厘定其成岩时代,并分析它们的时空分布及其与铀成矿的关系。测试结果显示,贵东复式岩体中东部晚期花岗质小岩体普遍存在高铀锆石,这可能是对同一岩体不同学者所获得的^(206)Pb/^(238)U加权平均年龄差别较大的主要原因。剔除高铀锆石的年龄数据,龟尾山断裂带以西的隘子、司前、陈洞岩体锆石^(206)Pb/^(238)U加权平均年龄分别为163.0±1.6 Ma、163.1±1.6 Ma、160.7±1.9 Ma,属燕山早期岩浆活动的产物;而以东的帽峰、分水坳、龟尾山岩体锆石^(206)Pb/^(238)U加权平均年龄分别为230.0±2.7 Ma、225.9±2.9 Ma和232.6±3.1 Ma,属印支期岩浆活动的产物。所以,龟尾山断裂以西和以东晚期花岗质小岩体的时代不同。且龟尾山断裂带以东的印支期花岗质小岩体空间上与铀矿化、尤其是与燕山早期的绢英岩化型等中高温热液铀矿化关系密切,是主要的储矿围岩;结合元素地球化学研究结果,该区产出的印支期花岗质小岩体也可为铀成矿提供铀源。

鄂尔多斯盆地东南部韩城地区延长组碎屑锆石U-Pb年代学特征及物源指示意义

围绕鄂尔多斯盆地东南部中晚三叠世延长组物源演化,以盆地东南部韩城薛峰川地区延长组剖面为研究对象,运用碎屑锆石U-Pb年代学探讨了韩城地区延长期的物源特征。结果表明,韩城薛峰川地区延长组自下而上不同层段碎屑锆石U-Pb年龄谱峰特征基本一致,峰值段主要集中在晚古生代晚期(250~263 Ma)、古元古宙晚期(1 689~1 774 Ma, 1 867~1 885 Ma)和古元古宙早期(2 490~2 560 Ma),太古宙年龄仅零星分布,而中新元古宙和早古生代年龄均缺失。综合物源对比认为,韩城地区延长期盆地物源主要来自于其东北部的华北克拉通内部及阴山造山带地区,而华北板块南缘及秦岭地区的南部物源特征不明显。这种物源特征与盆地西南部延长期物源复杂多变的特点形成了鲜明对比,表明鄂尔多斯盆地东南部延长期具有稳定的东北物源特征,推测其南地区在延长期仍存在分隔南部物源的深湖相沉积,该认识对探讨延长期湖盆演化具有重要意义。

东昆仑志留纪火山岩锆石U-Pb年龄及其对陆-陆碰撞时限的制约

东昆仑造山带早古生代经历了完整的洋壳形成、俯冲消减、陆-陆碰撞造山和造山后垮塌演变过程,目前对陆-陆初始碰撞时间及碰撞时限还存在较大争议。周缘前陆盆地启动引发的沉积环境突变或不整合形成时间是用来约束大陆初始碰撞时间最直接和最有效的方法之一。本文以东昆仑水泥厂地区角度不整合覆盖于石灰厂组之上的志留纪周缘前陆盆地沉积哈拉巴依沟组为研究对象,开展火山岩夹层锆石U-Pb年代学研究,为约束早古生代陆-陆初始碰撞时间与碰撞造山时限提供沉积记录证据。结果表明,水泥厂东和雪水河东哈拉巴依沟组下部流纹质凝灰岩锆石U-Pb年龄分别为443.0±3.9 Ma和441.8±1.3 Ma,结合已报道的石灰厂组火山岩锆石U-Pb年龄(450.4±4.3 Ma),可以确定东昆仑陆-陆初始碰撞发生在450~443 Ma之间。综合区域上古生代岩浆活动、变质作用、构造变形与相关沉积记录证据,认为东昆仑地区至少从450 Ma左右开始进入陆壳深俯冲及陆-陆碰撞阶段,在425 Ma左右进入碰撞后伸展阶段,碰撞造山作用至少持续了25 Ma。

复杂岩体中锆石的成因判识及其对锆石U-Pb年龄的影响:以辽河坳陷太古宇基底中的锆石为例

复杂岩体经历了长期地质演化,内部所含锆石成因十分复杂。综合前人研究成果,根据锆石外部形态、CL发光强度、内部结构以及微量元素特征,本文将锆石成因类型归纳为岩浆作用、变质作用以及热液作用3大类9小类。在锆石U-Pb定年的过程中,单颗粒锆石或锆石上不同位置的成因判识是获取高质量U-Pb年龄数据的前提。以渤海湾辽河坳陷基底复杂岩体为例,对岩体内具有核—边结构的复杂成因锆石进行了系统的研究,分别获取不同成因锆石的U-Pb年龄,进而探讨锆石成因对获取高质量U-Pb年龄的重要意义。阴极发光图像显示,锆石的核部多见岩浆成因环带结构,也可见斑杂状、海绵状及扇形分带等变质成因结构,边部呈现变质重结晶成因的扇形和冷杉叶结构。锆石核部Th/U比值(0.39~1.32)和分散的稀土元素特征,表明核部存在岩浆结晶锆石、变质锆石以及变质残余锆石,边部主要是变质重结晶作用或流体蚀变形成的增生边。基于锆石的成因类型划分,从3个样品锆石核部和边部分别获得了代表原岩形成时间的岩浆年龄和变质作用时间的变质年龄。辽河坳陷基底复杂岩体锆石U-Pb年龄结果表明,基底存在两期新太古代晚期岩浆事件,分别为2586~2583 Ma、2565~2538 Ma,变质事件主要发生在2508~2501 Ma。辽河坳陷基底岩浆事件和变质事件的获得,对于揭示华北克拉通覆盖区前寒武纪基底的形成演化具有重要意义。