长江中下游中生代花岗岩类源区的壳—壳混源性质

长江中下游地区中生代花岗岩类形成于大别造山带碰撞后岩石圈物质的调整演化过程。Ｓｒ、Ｎｄ、Ｐｂ同位素组成数据表明，早、晚阶段花岗岩类具有相似的壳－壳混合源区性质，其主要源岩端员可能分别相当于以大别杂岩为代表的深变质岩系和中、新元古界底侵（ｕｎｄｅｒｐｌａｔｉｎｇ）基性物质与部分古元古界沉积－火山－侵入岩系组成的扬子陆块下地壳岩石。这两种成分不同的下地壳物质在这里呈指状穿插体结构。长江中下游地区下地壳在碰撞造山过程中曾是大别地块与扬子地块之间的深部构造混杂带。本文主要根据各类已有的Ｓｒ、Ｎｄ、Ｐｂ同位素组成资料讨论花岗岩类的源区性质问题     

扬子地块南缘晚古生代洋壳存在的Nd同位素证据

总结我国扬子地块南缘新元古代—早中生代沉积岩目前已发表的Ｎｄ同位素资料发现,这些沉积岩具有随时间变化而其Ｎｄ同位素组成发生漂移的现象。在绝大多数时间里,它们具有２０００Ｍａ左右的Ｎｄ模式年龄,但在１０００～７００Ｍａ的新元古代和＜４００Ｍａ的晚古生代—早中生代时间段中,Ｎｄ同位素模式年龄急剧降低,反映在此时间段内,新生地幔物质已经进入沉积物的物源区。１０００～７００Ｍａ期间的Ｎｄ同位素变化归因于晋宁期的碰撞造山作用而晚古生代－早中生代沉积岩的Ｎｄ同位素变异起因于海盆发育阶段洋壳的出现。即扬子地块南缘在晚古生代—早中生代期间曾经存在过洋壳,且该洋盆可能是古特提斯大洋分支的一部分。     

东北亚与日本的地体增生和大陆生长

东北亚是由古生代中期至早中生代时期的大陆碰撞及其后晚中生代时期沿太平洋边缘出现的地体增生与左行走滑断层作用共同形成的。西伯利亚、中朝与扬子陆块的碰撞时代尚有争议;一些地质学家基于古地磁资料与生物古地理资料认为中朝陆块与扬子陆块是在早中生代时期沿秦岭缝合带碰撞对接的,而其他地质学家更趋向于中晚古生代碰撞。     

大别造山带的构造演化

大别地块是扬子地块北缘中晚元古代古岛弧的一部分，加里东期，它作为扬子地块北部陆缘的水下隆起，与华北地块南缘的早古生代古岛弧碰撞拼合，古洋壳消失，完成了南北两大陆块的对接，开始进入漫长的陆内俯冲时期，大别造山带就是扬子地块，大别地块和华北地块在陆内俯冲作用下，依次叠覆的结果，印支期是大别山的主变形期和高压动力变质时期，燕山期是主要的造山期，基底剪切引起地壳重熔，导致大范围的热流变质作用。大别地块的降     

秦岭造山带早中生代花岗岩成因探讨

秦岭造山带历经新元古代陆块汇聚与裂解、古生代沿商丹带俯冲增生与碰撞,以及中生代沿勉略带南北两大陆块最终碰撞造山,成为一多期次构造演化而成的复合型大陆造山带.其中,最为显著的是中生代早期伴随最终碰撞造山秦岭发生强烈构造岩浆事件,在陕西商州市以西的东、西秦岭地区乃至扬子地块西北缘形成了巨量的花岗岩体,构成秦岭巨大花岗岩带.     

扬子大陆的陆内俯冲与大陆的缩小

本文简要论述了白云母花岗岩是陆内俯冲的岩石学记录。华南大陆与天水－雅江地带广泛分布中生代二云母花岗岩侵入体，已有的同位素年龄范围为２４５－１２２Ｍａ，与此同时，它们两侧的扬子大陆发育的陆褶皱带，这种成对性及其构造配置表明，扬子大陆华击大卢松潘－甘孜褶皱带发生的过陆内俯冲作用，基于二云母花岗岩带的总宽度，估算扬子大陆最小的总俯冲量至少为６５０ｋｍ，扬子大陆现今宽度的６８０ｋｍ，这样，扬子大陆在中生代     

秦巴及邻区构造研究的新进展和新认识

重点论述了秦岭—大巴山及邻区构造研究方面取得的主要新进展和新认识:(1)从地质、地球物理和区域成矿规律等方面论证了本区没有真正的古大洋,而是“洋盆化”的多期次裂陷海槽;扬子陆块与华北陆块是同一个岩石圈板块。(2)对本区重新划分构造(成矿)区,划分出11个板内裂陷—增生带和5个裂陷边缘过渡带。其中最重要的古秦岭裂陷—增生带等分别生成于元古代和早古生代。(3)秦岭构造带在不同地史阶段有不同的板内俯冲碰撞带,从早元古代到早中生代共有7条。其中商丹断裂带只是晚加里东期碰撞带,而礼县—麻沿河—山阳断裂带则是扬子陆块与华北陆块在早—中三叠纪最后一次碰撞的碰撞带。因此秦岭带是板内多旋回裂陷—增生一拼合碰撞的重叠造山带。     

江南隆起上的下古生界缺失带──华南加里东前陆褶冲带的标志

华南的主造山事件发生在加里东期。由于中生代同一方向薄皮冲断作用的叠加和改造，早古生代的碰撞构造格局已不清楚。江南隆起核部存在一下古生界缺失带，它平行隆起走向线状分布，空间上分开了西北的扬子型地层和东南的江南型地层区，晚古生代浅海碳酸盐平缓超覆其上。由于早古生代时江南隆起位于扬子陆块东南的大陆斜坡部位，当时曾普遍接受沉积，上述线状地层缺失带应属造山变形产物，可能标示着加里东期造山带的前陆褶冲带的位置。     

东秦岭陡岭古岛弧和武当古弧后盆地及其地质意义

丹凤—信阳蛇绿混杂带作为秦岭—大别碰撞造山带主缝合带，其南部属于扬子板块北部大陆边缘。研究区域位于东秦岭南翼，是扬子板块北部大陆边缘的一部分。①晚元古—中震旦世，扬子板块北缘（东秦岭段）为活动型大陆边缘，发育有陡岭岛弧和武当弧后盆地；②晚震旦—早古生代，扬子板块北缘转为被动型大陆边缘，陡岭古岛弧构成边缘地块，武当古弧后盆地演化为边缘盆地；③早古生代晚期，华北板块南缘的秦岭岛弧首先与扬子板块北缘的陡岭边缘地块（古岛弧）碰撞，造成武当边缘（古弧后）盆地的闭合，并形成刘岭前渊和二峪沟前陆盆地；④由于岛弧—边缘地块碰撞加之弧后和边缘盆地的存在，因此在早古生代末期，秦岭—大别山并未大规模隆起，造山带只具雏形。直至中生代早期，华北与扬子两个板块间进一步的陆内俯冲作用才使秦岭—大别山大规模隆起。陡岭古岛弧和武当古弧后盆地的确认合理地解释了秦岭—大别碰撞造山带“加里东碰撞不造山，印支造山不碰撞”的“矛盾”现象。     

论鲁东造山带成因

鲁东造山带是由扬子陆块与胶辽古陆碰撞带隆起形成的。碰撞带形成于晋宁期，隆起开始于晋宁末期，结束于中生代印支燕山期。     

北亚克拉通和造山带金属成矿作用及其相关的地球动力学研究

“北亚克拉通和造山带金属成矿作用、石油资源及地球动力学”国际研讨会上各国地质学家发表了各自的北亚地区金属成矿作用、石油资源及地球动力学观点,对早前寒武纪、西伯利亚克拉通、造山带、板内裂谷等成矿作用及其相关的地球动力学等方面进行了广泛、深入的研讨,基本反映了近些年来北亚地区在金属成矿作用及其有关的地球动力学方面研究现状和取得的进展。西伯利亚克拉通和褶皱造山带有明显的区别。前者演化历史可以分为前寒武纪—早中生代增生和中—新生代裂谷作用两个阶段,早前寒武纪成矿作用主要受区域深大断裂多期拉张和挤压、克拉通内古断裂的形成、古断裂中火山岩喷出或花岗岩类侵入等地球动力学控制,中生代金属成矿作用主要受深部地壳动力学过程控制。造山带包括了新元古代、古生代及中生代不同时期的大洋,主要有大洋、岛弧、大陆边缘、汇聚碰撞、碰撞后五大成矿地球动力学环境,各环境的金属成矿作用特色明显有差异     

东北新开岭地区晚中生代花岗岩类时代、成因及地质意义

小兴安岭西北部新开岭地区4个花岗岩岩体锆石U-Pb年龄为：大头山石英闪长岩体(187.7±1.4) Ma,大平山二云母二长花岗岩体(170.7±1.3) Ma,大平北山黑云母二长花岗斑岩(128.0±1.1) Ma以及黑云母花岗斑岩岩脉(120.6±0.6) Ma。结合前人年龄资料,该区中生代花岗质岩浆活动可分为早中侏罗世（188~164 Ma）和早白垩世（128~106 Ma）两个阶段,这与中国东北地区和俄罗斯远东地区早中侏罗世和早白垩世花岗岩可以对比。从早中侏罗世到早白垩世,花岗岩质岩石显示明显的演化趋势,由准铝质－弱过铝质高钾钙碱性（或者与钙碱性过渡类型）的I型花岗岩,演变到弱过铝质高钾钙碱性－钾质高分异I型花岗岩;Sr/Y值也较低,锆石的ε_Hf(t)值略有升高。这显示由挤压增厚地壳的下部熔融形成的早期以壳源为主的花岗岩,演变为由相对伸展减薄环境下有年轻幔源加入形成的晚期高分异I型花岗岩。从花岗岩浆的演变特点分析,结合区域上构造演化,表明该时期研究区发生了由相对挤压增厚到伸展减薄的转换,这种转换的时间大致在160 Ma。     

Metallogenesis related to Mesozoic Granitoids in the Nanling Range, South China and Their Geodynamic Settings

Affected by the compressive stress from the South-Central （Indo-China） Peninsula, the Indosinian orogenesis, characterized by collision, thrust and uplifting, took place inside the South China Plate during 250-230 Ma. The ages of the Indosinian granitoids in the Nanling Range and vicinity areas are mostly 240-205 Ma, indicating that they were emplaced in both late collision and post-collision geodynamic environments. No important granite-related metallogenesis occurred in this duration. A post-orogenic setting started at the beginning of the Yanshanian Period, which controlled large-scale granitic magmatism and related metallogenesis. This paper makes the first attempt to divide the Yanshanian Period into three sub-periods, i.e. the early, middle and late Yanshanian Periods, based mainly on the features of magmatism, especially granitoids and related metallogenesis and their geodynamic environments. The magmatic association of the Early Yanshanian （about 185-170 Ma） comprises four categories of magmatism, i.e. basalt, bimodal volcanics, A-type granite and intraplate high-K calc-alkaline （HKCA） magmatism, which indicates an extension-thinning of lithosphere and upwelling of mantle material to a relative small and local extent. Pb-Zn, Cu and Au mineralizations associated with HKCA magmatism represents the first high tide of Mesozoic metallogenesis in the Nanling Range area. During the middle Yanshanian, the lithosphere was subjected to more extensive and intensive extending and thinning, and hence mantle upwelling and basaltic magma underplating caused a great amount of crust remelting granitoids. This period can be further divided into two stages. The first stage （170-150 Ma） is represented by large-scale emplacement of crust remelting granites with local tungsten mineralization at its end. The second stage （150-140 Ma） is the most important time of large-scale mineralizations of non-ferrous and rare metals, e.g. W, Sn, Nb-Ta, Bi, Mo, Be, in the Nanling Range area. The late Yanshanian （140-65 Ma） was generally characterized by full extension and breakup of the lithosphere of South China. However, owing to the influence of the Pacific Plate movement, the eastern part of South China was predominated by subduction-related compression, which resulted in magmatism of calc-alkaline and shoshonite series and related metallogeneses of Au, Ag, Pb-Zn, Cu and （Mo, Sn）, followed by extension in its late stage. In the Nanling Range area, the late Yanshanian magmatism was represented by granitic volcanic-intrusive complexes and mafic dikes, which are genetically related to volcanic-type uranium and porphyry tin deposits, and the mobilization-mineralization of uranium from pre-existing Indosinian granites.     

东昆仑造山带花岗岩及地壳生长

东昆仑造山带是青藏高原内可与冈底斯相媲美的又一条巨型构造岩浆岩带。该带内的花岗岩形成可以划分为4个时段,分别与4个造山旋回相对应：前寒武纪（元古宙）;早古生代;晚古生代—早中生代;晚中生代—新生代。其中,以晚古生代—早中生代（或称华力西—印支旋回）、特别是三叠纪的花岗岩最为发育。东昆仑造山带基底主要形成于古元古代晚期。其早古生代构造-岩浆事件序列与北祁连造山带可以对比,属祁连—东昆仑加里东造山系统的一部分。到晚古生代—早中生代时东昆仑卷入古特提斯构造体制,属于古特提斯造山系统的北缘。华力西—印支是一个完整的造山旋回,与西南“三江”古特提斯的演化历史相似。昆南缝合带是当时中国南北大陆的主要构造分界线。新生代印度—欧亚大陆的碰撞,使东昆仑造山带又卷入了青藏大陆碰撞造山系统,但对东昆仑的影响是一种远程效应。 　　东昆仑造山带大陆地壳主要形成于古元古代晚期,但在显生宙还有新生地壳 （juvenile crust） 产生,与兴蒙、冈底斯、安第斯等造山带相似。东昆仑花岗岩带中丰富的幔源岩浆底侵作用与壳-幔源岩浆混合作用的证据,以及花岗岩类的Nd、Sr同位素成份（87Sr/ 86Sr初始值多数小于0.710;εNd（t ）值变化于－9.2和＋3.6之间）,说明 地幔物质的注入及其与地壳物质的混合,对显生宙地壳的形成演化起着重要作用,是显生宙东昆仑地壳生长的重要方式。根据花岗质寄主岩、镁铁质暗色微粒包体（MME）及底侵辉长岩的锆石SHRIMP U-Pb定年,东昆仑造山带在显生宙发生过两次大规模的底侵作用与岩浆混合作用,一次在早-中泥盆世（394~403 Ma）,另一次在中三叠世（239～242 Ma）,分别相当于加里东旋回、华力西-印支旋回的俯冲结束/碰撞开始阶段。     

满洲里-额尔古纳地区中生代花岗岩的锆石U-Pb年代学与岩石组合：对区域构造演化的制约

本文对满洲里地区灵泉盆地、包格德乌拉盆地及额尔古纳地区上护林盆地和恩和盆地及周边的原确定为古生代和中
生代的花岗质岩石进行了岩石学和锆石LA-ICP-MS U-Pb 年代学研究,以便揭示研究区中生代的构造演化历史。研究区内
12 个代表性花岗岩中的锆石均呈自形-半自形晶,显示出典型的岩浆生长环带,结合其较高的Th/U比值（0.31~3.63）,暗
示其为岩浆成因。测年结果表明,该区中生代花岗质岩浆活动可划分成以下三期：（1）中三叠世岩浆活动,可进一步划分
成241 Ma 和229 Ma 两期岩浆事件,241 Ma 黑云母正长花岗岩和229 Ma 正长花岗岩的存在可能与古亚洲洋闭合后的伸展环
境有关;（2）早- 中侏罗世岩浆事件,可进一步划分成（180±5）Ma 和（171±2）Ma 两期岩浆事件,黑云母二长花岗岩-
正长花岗岩组合,结合其斑岩型Mo 矿的存在,反映研究区处于活动陆缘的构造背景,可能与蒙古- 鄂霍茨克洋的俯冲作用
有关;（3）早白垩世早期岩浆活动,可进一步划分成（140~150）Ma 和（134±2）Ma 两期岩浆事件,前者与区域内发育的
吉祥峰组火山岩形成时代相近,后者的火口充填型产状表明它们应是该期岩浆事件演化晚期的产物,该期岩浆事件在松辽
盆地以东地区的缺乏暗示它们形成于伸展环境,并与蒙古-鄂霍茨克缝合带的演化有关。     

Geochronology and geochemistry of early Mesozoic magmatism in the northeastern North China Craton: Implications for tectonic evolution

This paper reports geochronological, geochemical, zircon U–Pb and Hf–O isotopic data of the Late Triassic and Early Jurassic intrusive rocks in the northeastern North China Craton (NCC), with the aim of reconstructing the tectonic evolution and constraining the spatial–temporal extent of multiple tectonic regimes during the early Mesozoic. Zircon U–Pb ages indicate that the early Mesozoic magmatism in the northeastern NCC can be subdivided into two stages: Late Triassic (221–219 Ma) and Early Jurassic (180–177 Ma). Late Triassic magmatism produced mainly granodiorite and monzogranite, which occur as a NE–SW-trending belt parallel to the Sulu–Jingji Belt. Geochemically, they are classified as high-K calc-alkaline and metaluminous to weakly peraluminous granitoids, and are enriched in large-ion lithophile elements (LILEs) and light rare earth elements (LREEs), and depleted in high-field-strength elements (HFSEs; e.g., Nb, Ta, Ti, and P) and heavy rare earth elements (HREEs), indicating an affinity to adakite. Combined with their ε_Hf(t) values (−17.9 to −3.2) and two-stage model ages (2387–1459 Ma), we conclude that the Late Triassic granitoid magma in the northeastern NCC was derived from partial melting of the thickened lower crust of the NCC and was related to deep subduction and collision between the NCC and the Yangtze Craton (YC). The Early Jurassic magmatism is composed mainly of monzogranites, which are classified as metaluminous, high-K calc-alkaline, and I-type granite. Their ε_Hf(t) values and two-stage model ages are −16.7 to −4.2 and 2282–1491 Ma, respectively. Compared with the Late Triassic granitoids, the Early Jurassic granitoids have relatively high HREE contents, similar to calc-alkaline igneous rocks in an active continental margin setting. These Early Jurassic granitoids, together with the coeval calc-alkaline volcanic rocks and gabbro–diorite–granodiorite association in the northeastern (NE) Asian continental margin, comprise a NNE–SSW-trending belt parallel to the NE Asian continental margin, indicative of the onset of Paleo-Pacific Plate subduction beneath Eurasia.     

Neoproterozoic,Paleozoic, and Mesozoic granitoid magmatism in the Qinling Orogen,China: Constraints on orogenic process

The Qinling Orogen is one of the main orogenic belts in Asia and is characterized by multi-stage orogenic processes and the development of voluminous magmatic intrusions. The results of zircon U–Pb dating indicate that granitoid magmatism in the Qinling Orogen mainly occurred in four distinct periods: the Neoproterozoic (979–711 Ma), Paleozoic (507–400 Ma), and Early (252–185 Ma) and Late (158–100 Ma) Mesozoic. The Neoproterozoic granitic magmatism in the Qinling Orogen is represented by strongly deformed S-type granites emplaced at 979–911 Ma, weakly deformed I-type granites at 894–815 Ma, and A-type granites at 759–711 Ma. They can be interpreted as the products of respectively syn-collisional, post-collisional and extensional setting, in response to the assembly and breakup of the Rodinia supercontinent. The Paleozoic magmatism can be temporally classified into three stages of 507–470 Ma, 460–422 Ma and ∼415–400 Ma. They were genetically related to the subduction of the Shangdan Ocean and subsequent collision of the southern North China Block and the South Qinling Belt. The 507–470 Ma magmatism is spatially and temporally related to ultrahigh-pressure metamorphism in the studied area. The 460–422 Ma magmatism with an extensive development in the North Qinling Belt is characterized by I-type granitoids and originated from the lower crust with the involvement of mantle-derived magma in a collisional setting. The magmatism with the formation age of ∼415–400 Ma only occurred in the middle part of the North Qinling Belt and is dominated by I-type granitoid intrusions, and probably formed in the late-stage of a collisional setting. Early Mesozoic magmatism in the study area occurred between 252 and 185 Ma, with the cluster in 225–200 Ma. It took place predominantly in the western part of the South Qinling Belt. The 250–240 Ma I-type granitoids are of small volume and show high Sr/Y ratios, and may have been formed in a continental arc setting related to subduction of the Mianlue Ocean between the South Qinling Belt and the South China Block. Voluminous late-stage (225–185 Ma) magmatism evolved from early I-type to later I-A-type granitoids associated with contemporaneous lamprophyres, representative of a transition from syn- to post-collisional setting in response to the collision between the North China and the South China blocks. Late Mesozoic (158–100 Ma) granitoids, located in the southern margin of the North China Block and the eastern part of the North Qinling Belt, are characterized by I-type, I- to A-type, and A-type granitoids that were emplaced in a post-orogenic or intraplate setting. The first three of the four periods of magmatism were associated with three important orogenic processes and the last one with intracontinental process. These suggest that the tectonic evolution of the Qinling Orogen is very complicated.     

中蒙边境中段花岗岩时空分布特征及构造和找矿意义

本文精确地厘定了中蒙边境中段白乃庙片麻状石英闪长岩(459-454 Ma)、锡林浩特代托吉卡山中粒晶洞正长花岗岩(268±6.9 Ma)、镶黄旗巴音察汗灰白色中细粒角闪黑云母花岗闪长岩(261.7±6.1 Ma)、镶黄旗二长花岗岩(262.7±6.0 Ma)、镶黄旗哈达庙黑云母石英闪长岩(277.2±2.9 Ma)、锡林浩特白音锡勒中细粒正长花岗岩(231.1±7.6 Ma)、苏尼特左旗(东苏)二长花岗岩(216.9±5.4 Ma)、苏尼特左旗沙尔塔拉碱长花岗岩(152.1±2.5 Ma)的时代。并在前人工作的基础上, 总结了本地区花岗岩的时空分布规律: 区内花岗岩空间上呈3条近东西向的条带分布, 时间上可划分为5个重要期次:早-中古生代(490-387 Ma)、石炭纪(342-302 Ma)、二叠纪(282-257 Ma)、三叠纪(249-204 Ma)和晚中生代(152-118 Ma), 峰期间隔约为40 Ma, 并存在两条巨型碱性花岗岩带(东乌珠穆沁旗一带的二叠纪碱性岩带、华北板块北缘的晚三叠世碱性正长岩带), 岩浆活动呈现不对称性。结合区域地质、岩石、年代学等证据说明, 北部贺根山蛇绿岩与南部索伦山-西拉木伦蛇绿岩代表两个洋盆体系, 贺根山洋闭合早于中二叠世, 而索伦山-西拉木伦缝合带所代表残留古亚洲洋关闭, 中朝板块与西伯利亚板块最终碰撞拼合的时代应在晚二叠世-早三叠世。同时, 区内与花岗岩有关的矿产发育, 包括铜、钨、锌等矿种, 多产于造山后伸展或岩石圈拆沉, 区域大规模伸展环境。     

秦岭显生宙地幔组成及其演化

通过对秦岭造山带及扬子克拉通北缘显生宙时期 3个含地幔捕虏体的煌斑岩、钾镁煌斑岩、碱性玄武岩以及 11个不含捕虏体的辉石岩、辉长岩、玄武岩出露点的岩石地球化学对比研究 ,揭示出研究区地幔演化经历了自古生代的OIB亏损地幔到中生代的高度富集地幔再到中生代末期 -新生代的OIB MORB的亏损地幔的两次明显变更。制约这种变更的主要因素是熔融岩浆时源区发生的层圈相互作用类型。鉴于大陆岩石圈软流层体系的特征 ,有必要划分出岩石圈 /软流层相互作用带(过渡带 ) ,它是大陆岩浆作用的重要源区。     

Detrital zircon and apatite fission track data in the Liaoxi basins: Implication to Meso-Cenozoic thermo-tectonic evolution of the northern margin of the North China Craton

Detrital zircon and apatite fission track (ZFT and AFT) data of the sandstones collected from the Liaoxi basins served as a significant probe to study the Meso-Cenozoic thermo-tectonic reactivation events in the northern margin of the North China Craton. All sandstones show wide ZFT and AFT age spectrum and most of ZFT and AFT ages are younger than depositional age of respective host rocks, which suggest widespread track resetting of the host rocks in the Liaoxi basins after deposition. This hot geothermal status in the Liaoxi basins deduced from ZFT and AFT data is temporal consistent with the lithospheric evolution of the North China Craton, which implies that the lithosphere under the northern margin of the North China Craton underwent similar thermo-tectonic destruction process as the intracratonic Bohai Sea. The young ZFT peak age, which ranges from ∼50 Ma to 20 Ma, to some extend, provides a temporal constraint on the time that lithosphere significantly thinned and following reverse of the Liaoxi basins and uplift of the eastern part of the Yan-Liao Orogenic Belt. Exhumation of 1.5–2 km can be estimated in the eastern part of the Yan-Liao Orogenic Belt since ∼30 Ma to 10 Ma.