Chronology of landscape evolution and soil development in the upper Flinders River area,Queensland, based on isotopic dating of Cainozoic basalts

Victorian granites containing more than 750 ppm Ba are almost entirely confined to the region between a line from Geelong to Swan Hill and the Wonnangatta Fault Zone. Granite Ba contents normalised to 70% SiO₂ range from 620 to 733 ppm in western Victoria, 719 to 1560 ppm in central Victoria and 493 to 689 ppm in eastern Victoria. Melting of Ba-rich (meta)sedimentary rocks in the lower – middle crust is implicated in the petrogenesis of central Victorian S types, at least. Thus, granite geochemistry supports the concept of some sort of (largely concealed) Ba-rich Selwyn Block beneath central Victoria, although the boundaries that have been proposed for the block are modified here. There is a strong possibility that the Selwyn Block is an exotic terrane emplaced by northwest-directed strike-slip movement during the Bindian Orogeny. Such movement appears to have been controlled by the previously postulated Baragwanath Transform and another fundamental fault here called the Ulrich Transform. Asthenospheric upwelling related to movement on the Ulrich and Baragwanath Transforms may be the explanation for the twin belts of 400 Ma plutonism occurring to the west of the former and to the east of the latter. The southern extension of the Ulrich Transform may be the Tamar – Tiers structure in Tasmania. Plate-tectonic models suggesting Ordovician – Silurian subduction in Victoria need to be carefully revisited given the possibility of Siluro-Devonian exotic terrane emplacement.     

Geochronological constraints on early volcanic evolution of the Pilbara Block,Western Australia

U‐Pb isotopic systems of zircons from the Boobina and Spinaway Porphyries from the Precambrian Pilbara Block of Western Australia indicate ages of 3307± 19 Ma and 2768 ± 16 Ma, respectively. The Boobina Porphyry intrudes upper members of the Archaean greenstones of the Warrawoona Group. The Spinaway Porphyry intrudes basal units of the unconformably overlying volcanics and sediments of the Mt Bruce Supergroup. The age of the Boobina Porphyry, together with previous zircon U‐Pb and whole rock Sm‐Nd age determinations on stratigraphically older units, indicate that early Archaean volcanism in the Pilbara took place between 3560 Ma and 3300 Ma. On the basis of the age determination of the Spinaway Porphyry, and the chronometric definition of 2500 Ma for the Archaean—Proterozoic boundary, by the International Subcommis‐sion on Precambrian Stratigraphy (James H. L. 1978, Precambrian Res. 7, 193–204), the lower units of the Mt Bruce Supergroup should now be assigned to the Archaean.     

The parnell quartz monzonite: A proterozoic zoned pluton in the archaean pilbara block,Western Australia

The Parnell Quartz Monzonite in the Pilbara Block of Western Australia is a Proterozoic (1731 ± 14 Ma) pluton characterized by high modal K‐feldspar and a greater abundance of hornblende relative to biotite, as is typical of Phanerozoic monzonitic rocks in eastern Australia. The only geochemical features reflecting its setting in an Archaean terrain are high Na2O, Ni and Cr. The pluton is zoned, with an increase in K‐feldspar, quartz and biotite and a decrease in plagioclase and hornblende from margin to core. Chemically, this zoning is reflected by systematic variation of CaO, K₂O, Na₂O, Sr and Rb, but ferromagnesian elements have irregular trends, implying preferential extraction of feldspars relative to mafic minerals during differentiation of the magma. The unusual geochemical trends are explained by a model involving ‘in situ’ feldspar fractionation of a K‐rich residual liquid from a mafic crystalline mush.

A parent magma similar to the average rock composition of the pluton is deduced because high ferromagnesian trace element abundances preclude extensive fractionation of mafic minerals. Geochemical and isotopic constraints suggest that the ultimate source was chemically similar to a shoshonitic basaltic andesite, that must have been emplaced beneath the eastern margin of the Pilbara Block in the Early Proterozoic. Subsequent partial melting of this postulated underplated source at ～ 1700 Ma to produce the Parnell Quartz Monzonite was probably associated with tectonism in the Gregory Range Complex.     

Provenance of lateritic bauxite deposits in the Wuchuan–Zheng’an–Daozhen area,Northern Guizhou Province,China: LA-ICP-MS and SIMS U–Pb dating of detrital zircons

The provenance of the large and super-large scale bauxite deposits developed in the Wuchuan–Zheng’an–Daozhen (WZD) alumina metallogenic province in the Yangtze Block of South China is poorly understood. LA-ICP-MS and SIMS U–Pb dating of detrital zircons from bauxite ores and the underlying Hanjiadian Group in the WZD area provide new constrains on the provenance of the WZD bauxite and provide new insight on the bauxite ore-forming process. The ages of the detrital zircons in the bauxites and the zircons in the Hanjiadian Group are similar suggesting that the bauxites are genetically related to the Hanjiadian sediments. The detrital zircon populations of the four samples studied show four primary age peaks: 2600–2400 Ma, 1900–1700 Ma, 1300–700 Ma and 700–400 Ma. The age distribution of detrital zircons indicates that they are probably derived from various sources including Neoproterozoic, Mesoproterozoic, Paleoproterozoic, Archean and some minor Paleozoic sources. The most abundant age population contains a continuous range of ages from 1300 to 700 Ma, ages consistent with subduction-related magmatic activities (1000–740 Ma) along the western margin of the Yangtze Block and the worldwide Grenville orogenic events (1300–1000 Ma). Thus, it is suggested that the main provenances of the WZD bauxite and the Hanjiadian Group are the Neoproterozoic igneous rocks in the western Yangtze Block and the Grenville-age igneous rocks in the southern Cathaysia Block. In addition, this work verifies that the global Grenville orogenic events and subduction-related magmatic activities associated with the Yangtze Block had a significant influence on the formation of the WZD bauxite deposits.     

拉萨地体东南缘始新世早期变质作用及其构造意义

本文对位于青藏高原拉萨地体东南缘林芝杂岩中的片麻岩进行了岩石学和锆石U-Pb年代学研究.所研究的样品包括正片麻岩和副片麻岩,它们经历了中压角闪岩相变质作用.岩石地球化学分析结果表明,所研究的正片麻岩的原岩具有钙碱性岛弧岩浆岩的特征.锆石U-Pb年代学分析结果表明,副片麻岩中的碎屑锆石核部为岩浆成因,它们给出的206Pb/238U年龄范围为3012～ 522Ma,其锆石的增生边给出了～51Ma的变质年龄.在正片麻岩中,黑云母片麻岩给出了～67Ma的原岩结晶年龄和～ 55 Ma的变质年龄;石榴石角闪黑云斜长片麻岩给出了～58Ma的原岩结晶年龄和～54Ma的变质年龄.因此,所研究的林芝杂岩并不能代表拉萨地体中的前寒武纪变质基底,而是古生代的沉积岩和晚白垩纪至早新生代的岩浆岩在始新世早期变质而成.这一时期,表壳岩和侵入岩一起经历的中压角闪岩相变质作用很可能跟新特提斯洋俯冲导致的地壳增生、加厚有关.     

华北深部岩石圈存在弱的新元古代热活动的同位素年代学信息：证据及意义

人们普遍认为华北区别于华南的主要特征在于缺少广泛的新元古代岩浆活动,但原因是什么还不清楚。本文汇总了华北四个地区深源岩石包体中有这样同位素年龄的结果,并就它们所反映的华北当时在Rodinia超大陆裂解中心的位置和可能的岩石圈厚度进行了讨论。这些深源岩石包体分别是辽宁复县古生代金伯利岩中的基性麻粒岩、河北涉县碳酸岩化金伯利岩中石榴石辉石岩、河南信阳中生代火山岩中的橄榄岩及河北汉诺坝新生代玄武岩中橄榄岩。所记录的新元古代年龄信息包括:复县基性麻粒岩锆石0.61Ga的下交点年龄,涉县石榴石辉石岩全岩-单矿物的0.76GaSm-Nd内部等时年龄、信阳橄榄岩锆石的新元古代(>0.64Ga)年龄以及汉诺坝橄榄岩硫化物0.9～0.6Ga的Re-Os年龄。与华南广泛发育新元古代岩浆活动不同,华北有限的新元古代年龄信息(包括地表出现的)可能反映着它们当时在Rodinia超大陆的位置有所不同,即华南更靠近于超大陆裂解的中心、而华北可能远离该中心(如边缘)。位置的差别也预示着当时华南岩石圈的可能比较薄、而华北具巨厚的岩石圈。因此,我们认为弱的热事件和巨厚的岩石圈可能是造成华北新元古代热活动不明显的原因。     

华北地块南部断裂体系新构造活动特征

根据野外观察、测量与分析,特别是综合华北地块南部断裂体系第四纪活动性质的构造和地貌标志,表明现今华北地块南部NWWNW向断裂活动最为显著,主要表现为左旋走滑性质;在前新生代构造基础上发育的三门峡-鲁山-舞阳断裂带和新构造期发育的新乡-商丘断裂带是具有走滑性质的新生代壳内活动断裂。地球物理资料表明,在介休-新乡-溧阳和巴东-泉州-台湾地震带西北部的深部存在两个NW向构造带,在地幔可能汇聚为一条构造带。综合这些断裂及其所控断陷盆地的展布特征,明确了该区的NE向、NW向及近EW向断裂的运动学关系。即在应力应变基底格局的制约下,两个NW向构造带强烈的左旋走滑拉分运动作用下导致华北地块南部发育拉分盆地,NW向新断裂的形成和先存NNE、NW及近EW向断裂的复活,控制了新生代复杂的断裂或断块构造格局的形成。     

武夷地块中古元古代镁铁质-超镁铁质岩石的发现——剖面介绍及岩石学、岩相学、年代学特征

通过1:250 000衢州区域地质调查,在武夷地块浙西南地区发现古元古代镁铁质-超镁铁质岩石。该套岩石在金华、龙游-带呈面状分布,金华张村出露最为完整,主要由辉石角闪石岩、角闪石岩、斜长阳起石岩、斜长辉石岩和斜长角闪岩等组成。对辉石角闪石岩与阳起石岩开展了LA-ICP-MS锆石U-Pb测年分析,分别获得其成岩年龄为1 834±14 Ma(MSWD=0.23,N=16)、1 839±17 Ma(MSWD=0.22,N=11),暗示这套镁铁质-超镁铁质岩石为古元古代岩浆活动的产物。这一发现表明,约1 830 Ma武夷地块处于板内伸展构造环境,同时该时期武夷地块已经具备足够的刚性,以致产生大规模的脆性破裂以及可能由地幔对流作用引发的基性岩浆活动,推测在约1.83 Ga武夷地块已经具有克拉通的性质。     

拉萨那林拉卡断裂带晚第四纪古地震研究

拉萨地区最主要的一条晚更新世活断层为那林拉卡断裂带,是走向NWW、倾向SSW、高陡倾角的左旋逆走滑断层,全长33km。通过对该断裂带的研究,发现其从晚更新世以来有明显的活动,并在地表保留了断错地貌现象。其中,在次角林西沟及谢村最为明显,断层错断河流、山脊、阶地等地质体,形成断头沟、断层陡坎等断错地貌,并且两处晚更新世以来的水平位错分别为54～87m和20～67m。通过对断裂带上4个探槽的研究,发现距今约7万年以来,沿那林拉卡断裂带可能发生了5次古地震事件,各次事件的大致发生年龄为距今68.53,54.40,<41.23,21.96,9.86ka,事件平均复发间隔为14.67ka。由于探槽有限,并且各探槽揭露出的地震事件有限,没有一个探槽能完全揭露5次事件,因此文中对一些事件上下限年龄的确定存在一定的不确定性