华北克拉通北缘白云鄂博群和腮林忽洞群底部碎屑锆石U-Pb定年、Hf同位素分析及其地质意义

白云鄂博群位于华北克拉通北缘,由于赋存超大型REE-Nb-Fe矿而受到广泛关注。白云鄂博群形成时代有中元古代、古生代等不同认识。腮林忽洞群位于白云鄂博群的南部,与白云鄂博群的关系也有不同认识。本文报道了白云鄂博群和腮林忽洞群底部中-粗粒砂岩的碎屑锆石SHRIMP U-Pb年龄和LA-ICPMS Hf同位素组成。两个岩群碎屑沉积岩的碎屑锆石在形态和内部结构上类似,按结构特征可分为继承或捕获锆石、岩浆锆石、变质锆石和重结晶锆石等不同类型。年龄都主要分布在1.8~2.1Ga之间和2.4~2.7Ga之间,尽管年龄峰值存在一定区别。它们的Hf同位素组成也类似,εHf(t)和tDM2(Hf)变化范围分别主要在约-6.0~6.0之间和2550~2950Ma之间。结合前人研究,可得出如下结论:白云鄂博群和腮林忽洞群的物源区类似,主要由新太古代晚期和古元古代晚期岩浆岩组成,为新太古代早期陆壳物质再循环产物;部分岩石遭受新太古代晚期和古元古代晚期高级变质作用改造;碎屑物质都来自华北克拉通北缘早前寒武纪变质基底,与其形成时代相同的认识不矛盾。     

鄂尔多斯盆地东胜地区砂岩型铀矿源区及其构造背景分析——来自碎屑锆石U-Pb年龄及Hf同位素的证据

通过LA-(MC)ICP-MS碎屑锆石微区U-Pb定年和Hf同位素分析,对鄂尔多斯盆地东胜地区中侏罗统直罗组砂岩型铀矿层进行了同位素定年物源示踪研究。结果显示,四个样品的锆石年龄分布均表现出良好的一致性,总体呈现出2500～2300Ma,2000～1750Ma和450～250Ma三个主峰值年龄与2300～2000Ma、1750～1400Ma的次峰期年龄。年代学对比研究揭示,东胜地区砂岩型铀矿的物源主要来自华北克拉通西部陆块阴山地块和中部造山带北部的TTG片麻岩、麻粒岩和孔兹岩,以及海西期的大量火成岩体。碎屑锆石的εHf(t)值由负到正,变化范围较大,显示了古老地壳的再循环过程。其中,1.9Ga和2.5Ga的部分锆石其Hf分析点位于亏损地幔线附近,指示该时期有新生地壳的形成。锆石的二阶段Hf模式年龄分布范围3.8～0.7Ga,但集中于3.0～2.3Ga,在2.8～2.6Ga出现一峰值,说明华北克拉通地壳主要形成于中、新太古代。本文所获得的锆石Hf同位素模式年龄与华北克拉通西部陆块的Hf和Nd同位素模式年龄分布特征非常接近,而与东部陆块有很大差别,从而进一步证实了东、西部陆块在古元古代拼合之前是独立发展的。     

华北西部千里山地区长城系黄旗口组碎屑锆石U-Pb年龄及其地质意义

千里山地区中元古代长城系黄旗口组碎屑沉积岩保存完好,是研究华北克拉通西部长城系物质来源和沉积时代的理想对象。本文报道了千里山地区长城系黄旗口组底部的2个石英砂岩样品碎屑锆石LA-ICP-MS U-Pb定年结果。研究表明,样品20QL22最重要的碎屑锆石年龄区间为1910～2074 Ma,峰值年龄为1986 Ma。另外两个次重要的年龄段为1829～1872 Ma与2347～2486 Ma,峰值分别为1860 Ma与2387 Ma。样品20QL15碎屑锆石年龄呈现单峰分布的特征,主要集中于1733～1894Ma,峰值年龄为1820Ma。结合前人研究成果,本文认为千里山地区长城系黄旗口组碎屑沉积物质主要来自华北克拉通西部陆块内的孔兹岩带,阴山陆块与鄂尔多斯陆块也提供了部分物源。华北克拉通西部千里山地区长城系底界年龄小于1.73 Ga。     

华北西部千里山地区长城系黄旗口组碎屑锆石U-Pb年龄及其地质意义

千里山地区中元古代长城系黄旗口组碎屑沉积岩保存完好,是研究华北克拉通西部长城系物质来源和沉积时代的理想对象。本文报道了千里山地区长城系黄旗口组底部的2个石英砂岩样品碎屑锆石LA-ICP-MS U-Pb定年结果。研究表明,样品20QL22最重要的碎屑锆石年龄区间为1910～2074 Ma,峰值年龄为1986 Ma。另外两个次重要的年龄段为1829～1872 Ma与2347～2486 Ma,峰值分别为1860 Ma与2387 Ma。样品20QL15碎屑锆石年龄呈现单峰分布的特征,主要集中于1733～1894Ma,峰值年龄为1820Ma。结合前人研究成果,本文认为千里山地区长城系黄旗口组碎屑沉积物质主要来自华北克拉通西部陆块内的孔兹岩带,阴山陆块与鄂尔多斯陆块也提供了部分物源。华北克拉通西部千里山地区长城系底界年龄小于1.73 Ga。     

华北西部千里山地区长城系黄旗口组碎屑锆石U-Pb年龄及其地质意义

千里山地区中元古代长城系黄旗口组碎屑沉积岩保存完好,是研究华北克拉通西部长城系物质来源和沉积时代的理想对象。本文报道了千里山地区长城系黄旗口组底部的2个石英砂岩样品碎屑锆石LA-ICP-MS U-Pb定年结果。研究表明,样品20QL22最重要的碎屑锆石年龄区间为1910～2074 Ma,峰值年龄为1986 Ma。另外两个次重要的年龄段为1829～1872 Ma与2347～2486 Ma,峰值分别为1860 Ma与2387 Ma。样品20QL15碎屑锆石年龄呈现单峰分布的特征,主要集中于1733～1894Ma,峰值年龄为1820Ma。结合前人研究成果,本文认为千里山地区长城系黄旗口组碎屑沉积物质主要来自华北克拉通西部陆块内的孔兹岩带,阴山陆块与鄂尔多斯陆块也提供了部分物源。华北克拉通西部千里山地区长城系底界年龄小于1.73 Ga。     

内蒙古狼山巴音前达门地区黑云斜长片麻岩年代学研究及板块归属

内蒙古西部狼山地区的构造归属争议较大,一直以来没有直接证据证明狼山地区属于华北陆块。本文对内蒙古狼山巴音前达门地区(含石榴子石)黑云斜长片麻岩进行了年代学研究,利用LA- ICP- MS方法进行U- Pb同位素测年,所测试锆石均为岩浆锆石,锆石年龄为1946±9 Ma和1940±12 Ma,代表其原岩的形成年龄,说明狼山地区存在古元古代晚期岩浆作用。从锆石Hf同位素来看,εHf(t) 从-1.3~6.4,其Hf同位素源区既有当时华北克拉通基底物质,又有地幔的贡献,2442Ma的模式年龄指示源岩来源于早元古代地壳增生事件,可能与华北克拉通基底的形成有关。这进一步表明狼山地区同华北陆块中部地区一样,该地区存在有早元古代岩体。对宝音图群碎屑锆石的研究同样说明了狼山地区宝音图群与华北克拉通更具亲缘性,狼山地区在构造属性上可能属于华北陆块一部分。     

华北克拉通五台群LA-ICP-MS锆石U-Pb年龄和Hf同位素特征

通过对五台群石咀亚群金刚库组4个典型样品的LA-ICP-MS锆石U-Pb年龄和Hf同位素研究,对五台群的形成时代及华北克拉通新太古代—古元古代期间的地壳演化进行了探讨。锆石U-Pb同位素测定结果表明,侵入金刚库组中的片麻状花岗岩锆石的U-Pb年龄为2548Ma,因此五台群的上限年龄约为2.5Ga;金刚库组黑云母石英片岩和片麻状石英闪长岩的原岩锆石U-Pb年龄分别为2663Ma和2636Ma,因此五台群的下限年龄约为2.7Ga。五台群的地质年龄为2.5~2.7Ga,属于新太古代。锆石Hf同位素研究结果表明,黑云母石英片岩和片麻状石英闪长岩的二阶段Hf模式年龄(tDM2)均为2.8Ga左右,指示2.8Ga左右是五台山区乃至整个华北克拉通地壳生长的重要时期;片麻状花岗岩tDM2平均为2.57Ga,与锆石结晶年龄非常接近,表明2.5Ga左右也是华北克拉通地壳的主要增生期。地壳的增长是幕式的,2.8Ga和2.5Ga都是华北克拉通地壳生长时期。     

华北克拉通南缘太古宙地壳生长和再造:登封地区五指岭组碎屑锆石U-Pb-Hf同位素制约

对登封地区嵩山群五指岭组二云石英片岩和石英岩中碎屑锆石进行了LA-ICP-MS U-Pb年代学和原位Hf同位素分析,为探讨华北克拉通南缘太古宙地壳生长和再造提供了制约。结果显示,碎屑锆石多数呈自形–半自形,发育振荡生长环带,结合相对高的Th/U比值(0.07~1.87),暗示它们多数为岩浆成因。二云石英片岩和石英岩中碎屑锆石具有类似的年龄和Hf同位素组成,它们的207Pb/206Pb谐和年龄分别介于2879~2027 Ma和3346~1903 Ma之间,峰期年龄分别为2524 Ma和2528 Ma。~2.5 Ga锆石的εHf(t)值多数为正值,介于+0.10~+9.22之间,tDM2C变化于3028~2453 Ma之间,4颗碎屑锆石的εHf(t)值为负值,变化于-1.68~-0.03之间,tDM2C介于3132~3032 Ma之间。根据上述结果并结合相邻地区的相关研究资料,表明嵩山群沉积于古元古代晚期,五指岭组中碎屑锆石的物源主要为华北克拉通南缘~2.5 Ga具有新生地壳属性的结晶基底物质。华北克拉通南缘存在中–新太古代时期的地壳生长,同时发育中太古代古老地壳物质的再造。     

赞皇杂岩翁城地区长城系常州沟组砂岩碎屑锆石U-Pb-Hf同位素研究

常州沟组是华北克拉通太古宙-古元古代变质基底上最早的沉积盖层之一,其碎屑锆石U-Pb年代学与Hf同位素特征分析对探讨长城系形成时代、源区特征以及基底演化均具有重要的研究意义。本文对华北克拉通中部赞皇杂岩瓮城地区长城系常州沟组底部砂岩样品进行了LA-ICP-MS碎屑锆石 U-Pb定年和LA-MC-ICP-MS碎屑锆石Lu-Hf同位素分析。砂岩样品中碎屑锆石主要年龄峰值约为2500 Ma,推断其碎屑物质主要来自于华北克拉通新太古代晚期变质基底,而最年轻的碎屑锆石年龄为1822 Ma,结合赞皇杂岩变质基底普遍经历了1850~1800 Ma变质作用以及区域上上覆大红峪组火山岩中1635 Ma结晶锆石年龄,限定瓮城地区长城系常州沟组沉积时代为1 800~1 635 Ma。砂岩样品中碎屑锆石的εHf(t)值变化于-6.8~+5.2之间,相应的两阶段模式年龄峰值约为2820 Ma,结合赞皇杂岩已发表的2900~2700 Ma岩浆锆石和碎屑锆石Hf同位素结果,进一步表明2900~2700 Ma为赞皇杂岩地壳生长最主要的时期。综合太行山中南部地区已发表的长城系常州沟组的沉积学与新的年代学数据,推测赞皇杂岩瓮城地区长城系常州沟组沉积于陆内裂谷盆地。     

内蒙古武川西乌兰不浪地区早前寒武纪变质基底锆石SHRIMP定年及Hf同位素组成

本文报道了华北克拉通西部武川西乌兰不浪地区太古宙变质基底的锆石SHRIMP年龄和Hf同位素组成。一个片麻状奥长花岗岩样品的锆石具核边结构,核部岩浆锆石和边部变质锆石的207Pb/206Pb加权平均年龄分别为2692±17Ma和2528±16Ma。对9个样品进行了锆石Hf同位素分析。新太古代早期(2692～2697Ma)片麻状奥长花岗岩(2个样品)的岩浆锆石的εHf(t)、tDM1(Hf)和tDM2(Hf)分别为4.78～8.83、2646～2780Ma和2632～2845Ma;新太古代二辉麻粒岩(2个样品)中的捕获锆石的εHf(t)、tDM1(Hf)和tDM2(Hf)分别为-2.30～8.62、2543～2954Ma和2529～3189Ma;新太古代变质深成岩(4个样品)的岩浆锆石的εHf(t)、tDM1(Hf)和tDM2(Hf)分别为-2.60～8.09、2529～2880Ma和2538～3089Ma;古元古代蓝晶石榴长英质片麻岩(1个样品)的碎屑锆石的εHf(t)、tDM1(Hf)和tDM2(Hf)分别为1.52～6.59、2432～2774Ma和2498～2925Ma。结合前人研究结果,可得出如下结论和认识:1)该区存在新太古代早期片麻状奥长花岗岩,太古宙岩石在新太古代晚期普遍遭受高级变质作用影响;2)新太古代早期为该区地壳形成主要时期,新太古代晚期则主要表现为陆壳物质再循环;3)作为阴山地块的典型代表,固阳-武川地区与华北克拉通东部太古宙基底十分类似,可能表明华北克拉通在新太古代晚期已成为统一的整体。     

广东三水盆地沉积体系研究

通过大量钻井和露头资料的沉积学研究,确认了白垩纪—古近纪三水盆地存在冲积扇、扇三角洲、河流(辫状河)、三角洲、湖泊五大沉积体系,并详细描述了它们的特征和时空分布规律。根据五大沉积体系在纵向上的叠置关系,把三水盆地分为①早白垩世底部粗碎屑进积阶段;②晚白垩世初始湖泛阶段;③古新世—早始新世湖泊细碎屑加积阶段:④中始新世—晚始新世顶部粗碎屑填积阶段。最后,根据沉积演化过程中的生储盖匹配关系,指出盆地西部宝月地区为最有利的油气勘探区块,最有利的层位为古近系怖心组,最有利的沉积体系为发育在怖心组大岗段之上的冲积扇、扇三角洲和三角洲。     

广东三水盆地沉积体系研究

通过大量钻井和露头资料的沉积学研究,确认了白垩纪-古近纪三水盆地存在冲积扇、扇三角洲、河流(辫状河)、三角洲、湖泊五大沉积体系,并详细描述了它们的特征和时空分布规律.根据五大沉积体系在纵向上的叠置关系,把三水盆地分为①早白垩世底部粗碎屑进积阶段;②晚白垩世初始湖泛阶段;③古新世-早始新世湖泊细碎屑加积阶段:④中始新世-晚始新世顶部粗碎屑填积阶段.最后,根据沉积演化过程中的生储盖匹配关系,指出盆地西部宝月地区为最有利的油气勘探区块,最有利的层位为古近系怖心组,最有利的沉积体系为发育在怖心组大岗段之上的冲积扇、扇三角洲和三角洲.     

Influences of the unsaturated,saturated, and riparian zones on the transport of nitrate near the Merced River,California, USA

Transport and transformation of nitrate was evaluated along a 1-km groundwater transect from an almond orchard to the Merced River, California, USA, within an irrigated agricultural setting. As indicated by measurements of pore-water nitrate and modeling using the root zone water quality model, about 63% of the applied nitrogen was transported through a 6.5-m unsaturated zone. Transport times from recharge locations to the edge of a riparian zone ranged from approximately 6 months to greater than 100 years. This allowed for partial denitrification in horizons having mildly reducing conditions, and essentially no denitrification in horizons with oxidizing conditions. Transport times across a 50–100-m-wide riparian zone of less than a year to over 6 years and more strongly reducing conditions resulted in greater rates of denitrification. Isotopic measurements and concentrations of excess N₂ in water were indicative of denitrification with the highest rates below the Merced River. Discharge of water and nitrate into the river was dependent on gradients driven by irrigation or river stage. The results suggest that the assimilative capacity for nitrate of the groundwater system, and particularly the riverbed, is limiting the nitrate load to the Merced River in the study area.     

Crustal Shortening on the Margins of the Tien Shan,Xinjiang, China

We present the results of mapping selected cross-sections across the margins of the Chinese Tien Shan, an intracontinental mountain belt that formed in response to the India-Eurasia collision. This belt contains significant lateral variation in topography, structure, and stratigraphy at all scales, and our estimated rates of shortening also reveal a distribution of shortening that varies laterally. At the largest scale, it consists of two major high mountain ranges in the west that merge eastward into a complex, single high mountain belt with several distinct ranges, then separates farther eastward into several low mountain ranges in the south and a single narrow high mountain range in the north. Active fold-and-thrust belts along parts of the north and south flanks of the Tien Shan involve only Mesozoic and Cenozoic sedimentary cover, which varies in both stratigraphy and structure from east to west. The southern fold-and-thrust belt decreases in width and complexity from west to east and ends before reaching Korla. The northern belt begins near the longitude where the southern belt ends, and increases in width and complexity from west to east. Within these two fold-and-thrust belts are both E-W and N-S variations in stratigraphy at the scale of the fold-and-thrust belts and across individual structures. All these variations make it very difficult to generalize either structure or stratigraphy within the Tien Shan or within local areas.

Four maps and cross-sections, two across each of the northern and southern fold-and-thrust belts, imply different magnitudes of shortening. In the eastern part of the northern belt, a cross-section along the southern part of the Hutubi River yields shortening of 6.2 km, and a section to the north across the Tugulu anticline yields shortening of 5.5 km. The two parts of the cross-section cannot be added because the Tugulu anticline lies 20 km west of the Hutubi River, and diminishes greatly in amplitude toward the Hutubi River. In the western part of the northern belt, cross-sections require 4.6 to 5.0 km of shortening at Tuositai and 2.12 to 2.35 km across the Dushanzi anticline. The Tuositai structure lies south of the Dushanzi anticline, but shortening in these two areas also cannot be summed, because they seem to be separated by a N-trending strike-slip fault. In the western part of the southern fold-and-thrust belt, an incomplete cross-section along the Kalasu River suggests shortening of 12.1 to 14.1 km. If the estimated shortening of 6 to 7 km in the Qiulitage anticline, which we did not map, is added, the total shortening in this cross-section would be ～18 to 21 km. To the east, a complete cross-section at Boston Tokar yielded shortening of 10.3 to 13.0 km.

Calculating long-term shortening rates from these four cross-sections is difficult, because the time of initiation of deformation is poorly known. In the Kalasu River area of the southern belt, there is evidence that limited shortening of 2 to 4 km occurred in the early Miocene, if major thickness changes in deposition of conglomerate unit 3b are interpreted to be growth strata. Geological evidence suggests that most of the shortening began in both belts after the beginning of the deposition of the thick conglomerate unit shown as lower Quaternary on Chinese geological maps. Strata within the middle part of these conglomerates were deposited during the growth of the folds. Presence of Equus near the base of similar conglomerates indicates a Quaternary age, but the fossil localities are far from most of our cross-sections, and the contemporaneity of the rocks remains in question. The beginning of conglomerate deposition may be controlled by climate change, and if so, the beginning of conglomerate deposition may be generally contemporaneous throughout the region at ～2.5 Ma. Deformation began at some time after the onset of conglomerate deposition, but this time is not well constrained. Thus we have calculated shortening rates for 2.5, 1.6, and 1.0 Ma that should bracket maximum and minimum slip rates. These calculations yield the following ranges in the northern fold-and-thrust belt: southern Hutubi River = 2.5 to 6.2 mm/yr; Tugulu anticline = 2.1 to 5.5 mm/yr; Tuositai anticline = 1.8–2.0 to 4.6–5.0 mm/yr; and Dushanzi anticline = 0.8 to 2.1–2.4 mm/yr; and in the southern fold-and-thrust belt: Kalasu River = 4.6–5.6 (including the Qiulitage anticline = 7.2–8.4) to 12.1–14.1 (including Qiulitage anticline = 18–21) mm/yr; and at Boston Tokar = 4.1–5.2 to 10.3–13.1 mm/yr. If 2 to 4 km of shortening occurred in the Kalasu River section during early Miocene time, the long-term rates for Quaternary time are 3.2–4.8 (including Qiulitage anticline = 5.6–7.6) to 8.1–12.1 (including Qiulitage anticline = 14–19) mm/yr.

Calculation of the shortening rate across the entire width of the Tien Shan is difficult because of the rapid lateral variations in structure and because of active deformation within the range, which we have not studied. The cross-sections at Boston Tokar in the south and Tuositai in the north lie along the same longitude. Adding the shortening rates in these areas would yield a minimum range (using 2.5 Ma as the initiation time) of 5.7 to 7.2 mm/yr. If deformation began at 1.6 or 1.0 Ma, the range of shortening rates would be 10–11.2 mm/yr to 14.9–18.1 mm/yr, respectively. Because the first indication of structural growth with the mapped areas occurs above the base of the conglomerates at the top of the stratigraphic succession, a minimum shortening rate greater than 5.7 to 7.2 mm/yr is more likely.

Both the marginal fold-and-thrust belts have a thin-skinned geometry with the drcollement at -6 to 10 km and within Mesozoic and Cenozoic sedimentary rocks. Toward the interior of the range the decollement must pass into the Paleozoic basement rocks and steepen beneath the flanks of the range. The structural style is similar to that in the Laramide Rocky Mountains and the California Transverse Ranges. The highest parts of the Tien Shan are adjacent to areas of active shortening. Such a relation might suggest that the major uplift of the Tien Shan is very young, mostly latest Cenozoic or Quaternary in age. The shortening across the Tien Shan is inhomogeneous and spatially distributed.     

Depth of the base of the Jackson aquifer, based on geophysical exploration, southern Jackson Hole, Wyoming, USA

 A geophysical survey was conducted to determine the depth of the base of the water-table aquifer in the southern part of Jackson Hole, Wyoming, USA. Audio-magnetotellurics (AMT) measurements at 77 sites in the study area yielded electrical-resistivity logs of the subsurface, and these were used to infer lithologic changes with depth. A 100–600 ohm-m geoelectric layer, designated the Jackson aquifer, was used to represent surficial saturated, unconsolidated deposits of Quaternary age. The median depth of the base of the Jackson aquifer is estimated to be 200 ft (61 m), based on 62 sites that had sufficient resistivity data. AMT-measured values were kriged to predict the depth to the base of the aquifer throughout the southern part of Jackson Hole. Contour maps of the kriging predictions indicate that the depth of the base of the Jackson aquifer is shallow in the central part of the study area near the East and West Gros Ventre Buttes, deeper in the west near the Teton fault system, and shallow at the southern edge of Jackson Hole. Predicted, contoured depths range from 100 ft (30 m) in the south, near the confluences of Spring Creek and Flat Creek with the Snake River, to 700 ft (210 m) in the west, near the town of Wilson, Wyoming. Received, May 1997 · Revised, February 1998 · Accepted, April 1998     

内蒙古鄂尔多斯高原古冰缘遗迹科学考察研究进展

冰缘遗迹（特别是冷生楔形构造及融冻褶皱）是重建古气候及第四纪晚期多年冻土环境的重要证据。内蒙古鄂尔多斯高原是我国北方地区冰缘现象最为发育的地区之一。为准确了解鄂尔多斯高原冰缘遗迹类型及其分布特征、区域冻土演化历史等,中国科学院西北生态环境资源研究院和荷兰自由大学共同组成科研小组,于2018年5—6月组织了“鄂尔多斯高原冰缘遗迹科学考察”。考察区域涉及靖边—城川—乌审旗—鄂尔多斯东胜区一带约12 000 km²的范围。考察内容主要包括鄂尔多斯高原冰缘遗迹类型及特征、分布区域、各类型冰缘遗迹所指示的气候条件的初步推断等。结果表明：冻融褶皱和冷生楔体构造是鄂尔多斯高原主要存在的两大类冰缘遗迹。基于本次考察中关于冰缘遗迹的分布与特征等新发现,并综合前人研究成果,初步推断：在气温极低、多年冻土非常发育的时段,有利于形成各类冷生楔状构造,如冰楔假形和大型原生砂楔等;在气候转暖、多年冻土退化,但还没有全部融化完阶段,可能形成融冻褶皱;区域性大面积分布和成群出现的融冻褶皱一般反映较暖气候环境下,多年冻土层上部已退化到一定程度。基于光释光（OSL）年代测试结果,结合冰缘遗迹的特征及其所指示的古气候环境,初步重建了鄂尔多斯5万年以来的冻土环境变化序列。区内多年冻土在多年冻土最大期（LPM,25~19 ka BP）时最发育,以大面积连续多年冻土为主;之后,随气温转暖,总趋势呈退化状态,多年冻土分布逐渐变为片状→岛状→零星斑状,直至现今全部融完变为深季节冻土区。     

云南昭通毛坪铅锌矿床同位素地球化学性质研究

云南昭通毛坪铅锌矿床是滇东北铅锌成矿带中一个典型的中-大型矿床,文章在分析矿区地质特征的基础上,通过对矿床的硫、铅、碳、氢、氧五种同位素的组成特征及其地球化学性质的研究,探讨了成矿流体的性质和来源以及矿床可能的形成方式等问题.     

东川-易门式铜矿床成矿作用研究的几个问题

从宏观基础地质入手,按矿床学的一些基本概念,针对东川-易门铜矿床地质地球化学特征,探讨了一些存在争议的重要问题。研究认为:狮山段是绿汁江组下部独立存在的地层层位;东川-易门式铜矿床属沉积-改造成因,其中的层状铜矿属沉积成岩成因,不是"热液成矿";所谓东川-易门式矿床(稀矿山除外)为"喷流沉积成矿"或"岩浆叠加",尚依据不足;刺穿体是构造作用产物,对成矿有利,是良好的找矿标志,其中的角砾岩主要是沉积角砾岩与构造角砾岩,或沉积-构造角砾岩,不足以冠名"隐爆角砾岩(筒)"。     

基于DEM数据的古沉积面的重建方法 ——以青藏高原东北缘青海贵德盆地为例

广泛使用的数字高程模型（DEM）数据使得古沉积面的恢复成为可能。以青藏高原东北缘的青海贵德盆地为例,分析对比了前人获取代表古沉积面地表露头样本数据的几种方法．提出了插值样本应选择露头中代表原始沉积地层的顶面点的优选方法,并提取了更新统地表露头顶面点的样本数据。通过分析样本的特征、比较插值的结果,选择了自然邻点法进行插值预测,重建了贵德盆地更新统的古沉积面。正确样本,最的提取加上合适插值算法的选择．优化了重建的古沉积面。     

A discussion on the Genesis of the Jiama Copper-Polymetallic Deposit,Maizhokungger,Xizang

A DISCUSSION ON THE GENESIS OF THE JIAMA COPPER-POLYMETALLIC DEPOSIT, MAIZHOKUNGGER, XIZANG