安徽大别山团岭花岗岩体岩石学特征及成因

团岭花岗岩体侵位于大别山南部超高压变质带变质表壳岩中, 由细粒少斑二长花岗岩和中粒少斑二长花岗岩组成。通过岩石学、岩石化学、地球化学的研究, 确定其为Ｓ 型花岗岩, 源岩可能来自大别山变质杂岩。结合同位素资料, 认为其属燕山期花岗岩, 侵位机制为底辟式强力就位。     

多工况下汉源二蛮山滑坡机理数值模拟

利用FLAC3D软件对四川省雅安市汉源县二蛮山滑坡坡体进行建模,模拟降雨滑坡过程,并进行应力应变特征及稳定性计算分析,从而为深入研究地震及降雨诱发再次滑坡及防灾减灾提供可靠依据。研究中假设地震工况,对边坡进行详细的动力分析,得到了各监测点动力特征曲线;通过降雨工况下坡体稳定性系数分析得到了不同强度折减安全系数。研究结果表明,滑源区相对特殊的地形条件和地质构造以及不利的结构面组合是滑坡的基础;前期强降雨期间饱水加载以及大量雨水沿斜沟张裂结构面的下渗软化作用,是诱发滑坡发生的关键因素。      

依托科技创新 实现找矿突破

安徽矿产资源自然秉赋良好,已发现矿种138种,资源潜在总值居全国第十位。建国以来,安徽地质科技不断创新,找矿成果不断扩大,奠定了我省矿产资源大省地位。随着工业强省战略的深入实施,为缓解矿产资源瓶颈制约,必须进一步加大科技创新力度,加强基础地质研究、加强重点区带地球动力学与成矿预测研究、加强深部探测技术方法研究、加强资源高效利用和循环利用技术研究、加强地质科技创新机制研究,多找矿、找好矿、找大矿,真正实现地质找矿新的突破。     

延边八家子镇上南沟“大理岩”地质地球化学特征及地质意义

传统观点认为,延边八家子镇上南沟"大理岩"为碳酸盐岩地层经过区域变质作用形成。通过详细的野外和镜下观察,发现该"大理岩"并不发育层理等典型沉积岩的特征,而主要呈岩株和岩墙产出,与围岩新东村岩组片岩、片麻岩呈港湾状侵入式接触;且其中发育大量围岩捕虏体,"大理岩"局部还发育有冷凝边;除上南沟"大理岩"外,在上南沟及周边地区并没有碳酸盐岩地层的发育。分析显示,上南沟"大理岩"具有与火成碳酸岩相似的微量元素和稀土元素组成特征,C、O同位素组成处于火成碳酸岩受低温蚀变的演化趋势之内。因此,初步认为延边八家子上南沟"大理岩"并不是由碳酸盐岩地层经区域变质作用形成,其成因可能存在以下2种解释:一种是上南沟"大理岩"为火成碳酸岩,很可能是华北克拉通破坏事件在北缘的响应;另一种可能是大规模富含CO2流体运移的产物,是大规模流体运移成矿的典型范例。     

Geological, geochemical characteristics and isotope systematics of the Longqiao iron deposit in the Lu-Zong volcano-sedimentary basin, Middle-Lower Yangtze (Changjiang) River Valley, Eastern China

The Middle-Lower Yangtze (Changjiang) River Valley metallogenic belt is located on the northern margin of the Yangtze Craton of eastern China. Most polymetallic deposits in the Changjiang metallogenic belt are clustered in seven districts where magmatism of Mesozoic age (Yanshanian tectono-thermal event) is particularly extensive. From west to east these districts are: E-dong, Jiu-Rui, Anqing-Guichi, Lu-Zong, Tong-Ling, Ning-Wu and Ning-Zhen. World-class iron ore deposits occur in the Lu-Zong and Ning-Wu ore clusters, which are mainly located in continental fault-bound volcanic-sedimentary basins. One of these deposits is the Longqiao iron deposit, discovered in the northern part of the Lu-Zong Basin in 1985. This deposit consists of a single stratabound and stratiform orebody, hosted in sedimentary carbonate rocks of the Triassic Dongma'anshan Formation. A syenite pluton (Longqiao intrusion) is situated below the deposit. The iron ore is massive and disseminated and the ore minerals are mainly magnetite and minor pyrite. Wall rock alteration mostly consists of skarn minerals, such as diopside, garnet, potassic feldspar, quartz, chlorite, phlogopite and anhydrite. Thin sedimentary siderite beds of Triassic age occur as relict laminated ore at the top and the margin of the magnetite orebody. These sideritic laminae are part of Triassic evaporite-bearing carbonate deposits (Dongma'anshan Formation).Sulfur isotopic compositions show that the sulfur in the deposit was derived from a mixture of magmatic hydrothermal fluids and carbonate–evaporite host rocks. Similarly, the C and O isotopic compositions of limestones from the Dongma'anshan Formation indicate that these rocks interacted with magmatic hydrothermal fluids. The O isotopic compositions of the syenitic rocks and minerals from the deposit show that the hydrothermal magnetite and skarn minerals were formed from magmatic fluids. The Pb isotopic compositions of sulfides are similar to those of the Longqiao syenite. Phlogopite coexisting with magnetite in the magnetite ores yielded a plateau age of 130.5 ± 1.1 Ma (2σ), whereas the LA-ICP MS age of the syenite intrusion is 131.1 ± 1.5 Ma, which is slightly older than the age of phlogopite.The Longqiao syenite intrusion may have crystallized from a parental alkaline magma, generated by partial melting of lithospheric mantle, during extensional tectonics. The ore fluids were probably first derived from magma at depth, later emplaced in the sedimentary rocks of the Dongma'anshan Formation, where it interacted with siderite and evaporite-bearing carbonate strata, resulting in the formation of magnetite and skarn minerals. The Longqiao iron deposit is a skarn-type stratabound and stratiform mineral system, genetically and temporally related to the Longqiao syenite intrusion. The Longqiao syenite is part of the widespread Mesozoic intracontinental magmatism (Yanshanian event) in eastern China, which has been linked to lithospheric delamination and asthenospheric upwelling.     

基于贡献权重叠加法的滑坡风险区划

贡献权重叠加法是对滑坡本底因子和承灾体因子在滑坡发育中的贡献率进行统计后,通过贡献率均值化、规一化处理,利用权重转换模型计算出每一个因子内部的权重——自权重和因子相互之间的权重——互权重。将滑坡因子、承灾体因子和两者的自权重、互权重分别相乘叠加,得到滑坡危险度和易损度区划结果,再将2项结果相乘得出滑坡风险区划结果。     

塔里木盆地下奥陶统蓬莱坝组白云岩成因及储层主控因素分析——以巴楚大班塔格剖面为例

寒武系-下奥陶统白云岩是塔里木盆地非常重要的勘探接替领域,但由于白云岩埋藏深度大,勘探和研究程度低,目前的认识程度无法满足勘探的需求,尤其是白云岩储层成因和分布的认识。本文以巴楚地区大班塔格剖面蓬莱组白云岩的精细解剖为例,测制解剖剖面9条,采集样品195块,系统的开展了岩石薄片、物性及地球化学特征分析,取得了两个方面的新的认识。1)是塔里木盆地蓬莱坝组发育粉晶、细晶、中晶和粗晶四种白云岩,主要形成于早-中埋藏期与海源流体有关的白云石化作用中,局部受到热液改造,其晶粒大小与原岩结构的粗细及孔隙空间的大小有关,原岩结构粗,形成的白云石晶粒就粗,原岩孔隙空间大,白云石晶粒就大。2)是白云岩储层的分布具成层性和旋回性,孔隙发育段总体位于向上变浅旋回的顶部,与高频旋回的暴露面有关,其载体以细-粗晶白云岩为主,孔隙主体来自原岩孔隙的继承和再调整,少量来自埋藏(热液)溶蚀作用,而并不是传统观点所认为的白云石化作用建造孔隙,这一认识对塔里木盆地深层白云岩有效储层预测具重要的指导意义。     

Association of Late Paleozoic Adakitic Rocks and Shoshonitic Volcanic Rocks in the Western Tianshan, China

The late Paleozoic adakitic rocks are closely associated with the shoshonitic volcanic rocks in the western Tianshan Mountains, China, both spatially and temporally. The magmatic rocks were formed during the period from the middle to the late Permian with isotopic ages of 248-268 Ma. The 87Sr/86Sr initial ratios of the rocks are low in a narrow variation range (-0.7050). The 143Nd/144Nd initial ratios are high (-0.51240) with positive εND(t) values (+1.28-+4.92). In the εNd(t)-(87Sr/86Sr)i diagram they fall in the first quadrant. The association of the shoshonitic and adakitic rocks can be interpreted by a two-stage model: the shoshonitic volcanic rocks were formed through long-term fractional crystallization of underplated basaltic magma, while the following partial melting of the residual phases formed the adakitic rocks.     

通化地区老岭群花山组与珍珠门组平行不整合的发现及意义

通化地区珍珠门组并非老岭群的顶部层位,其上确实存在花山(大栗子)组、临江组．并且与珍珠门组呈平行不整合接触。这一发现,为重新厘定集安岩群、老岭群的地层层序以及区域地层对比．提供了直接的地质依据,也为老岭群的古地理再造以及地质构造演化研究提供了新资料;同时也为在这一地区寻找古岩溶型矿产提供了重要线索。