松辽盆地南部深层火山岩、火山机构和火山岩相地质-地震综合识别

松辽盆地南部深层发育2套火山岩,分布在下白垩统营城组下部和上侏罗统火石岭组中上部。东岭地区营城组为酸性岩,岩相以爆发相为主,占73%;火石岭组为中基性岩,可分为上下两段,岩相以喷溢相为主(上段占67%,下段占59%)。酸性岩在地震剖面上主要表现为透镜状、丘状反射特征,顶面为中强反射,内部为中强或弱反射,低频、杂乱、断续分布,具有明显的穿时现象。中基性岩在地震剖面表现为眼球状、丘状反射特征,顶部为强反射,与围岩呈超覆关系,内部为弱反射、蠕虫状、杂乱、低频、断续反射。利用拟声波曲线反演方法识别火山岩,其结果表明东岭地区火石岭组火山岩厚度受断层F₁控制,在F₁东侧薄,西侧厚,在SN109井区域最厚。利用构造趋势面分析和三维体切片技术可识别火山机构的火山锥。在东岭地区火石岭组发现2个火山锥发育区(以中部区域为主),该区火山锥面积为56 km²,最大幅度为547 m。利用倾角属性方法结合火山机构物理模型可识别出火山通道相和侵出相,波形分类方法可识别爆发相和喷溢相,结合两种方法可以准确地识别出火山岩相;其结果表明东岭地区火石岭组在中部区域喷溢相上部亚相和火山通道相发育。火山锥发育的区域是火山岩储层厚度发育的区域,同时岩相预测结果表明该区也是储层物性好的区域,所以东岭地区中部火山岩是勘探的有利目标区。     

Alkaline Lavas in the Volcanic Front of the Western Mexican Volcanic Belt: Geology and Petrology of the Ayutla and Tapalpa Volcanic Fields

The Plio-Quaternary Ayutla and Tapalpa volcanic fields in thevolcanic front of the western Mexican Volcanic Belt (WMVB) containa wide variety of alkaline volcanic rocks, rather than onlycalc-alkaline rocks as found in many continental arcs. Thereare three principal rock series in this region: an intraplatealkaline series (alkali basalts and hawaiites), a potassic series(lamprophyres and trachylavas), and a calc-alkaline series.Phlogopite-clinopyroxenite and hornblende-gabbro cumulate xenolithsfrom an augite minette lava flow have orthocumulate textures.The phlogopite-clinopyroxenite xenoliths also contain apatiteand titanomagnetite and probably formed by accumulation of mineralsfractionated from an augite minette more primitive than thehost. The intraplate alkaline series is probably generated bydecompression melting of asthenospheric mantle as a result ofcorner flow in the mantle wedge beneath the arc. Alkaline magmasmay be common in the WMVB as a result of prior metasomatism(during Tertiary Sierra Madre Occidental magmatism) of the Mexicansub-arc mantle. Generation of the more evolved andesites anddacites of the calc-alkaline series is due to either combinedassimilation and fractional crystallization (AFC) or magma mixing.The preponderance of alkaline and hydrous lavas in this regiondemonstrates that these lava types are the norm, rather thanthe exception in western Mexico, and occur in regions that arenot necessarily associated with active rifting. KEY WORDS: arc basalt; subduction; alkali basalt; minette; hawaiite; metasomatism     

The Cold Bay Volcanic Center,Aleutian Volcanic arc

The widespread abundance of Hi-Alumina Basalt (HAB) lavas in most volcanic arcs has been suggested by some as evidence for a primary, parental HAB magma generated by the high pressure melting of subducted oceanic crust (quartz eclogite). Others suggest a parental, mantle-derived olivine tholeiite magma which produces HAB magmas through fractionation of olivine, clinopyroxene, chrome-spinel +/– plagioclase. The petrology and geochemistry of seven HAB lavas from the Aleutian Cold Bay Volcanic Center have been studied in order to specifically address these two possibilities. All lavas show mineralogical and compositional features typical of most Aleutian HAB lavas. Coexisting opx and cpx in a closely associated basaltic-andesite indicate a minimum pre-eruption temperature of 1,110° C. A comparison of the observed (plag-tmag-olivcpx) and experimentally determined crystallization sequences yields a minimum pre-eruption pressure estimate of 7 kb and estimated H₂O contents of 0.7 wt.%. Maximum pre-eruption f _{o 2} values have been estimated at NNO+0.6 log units.Mass balance calculations demonstrate that the HAB compositions are satisfied by the fractionation of olivine, clinopyroxene +/– plagioclase from a primitive (Mg-# > 65) parental tholeiite. Plagioclase accumulation does not play a significant role in their origin. Many of the same compositional characteristics are also satisfied by high pressure melting of altered ocean ridge tholeiite +5 v.% pelagic sediment (quartz eclogite). The available HAB phase equilibria data do not support a fractionation origin but do support an origin involving high pressure melting of quartz eclogite. The lack of compositional zonation in the HAB phenocrysts, and the complete absence of disequilibrium MgO-rich mafic phenocrysts further argue against a tholeiite fractionation origin.Consideration of all these features indicates that the geochemical data are permissive in their interpretation. A process involving tholeiite fractionation successfully predicts the compositions of the HAB lavas but is at odds with the mineralogical and phase equilibria evidence. With some exceptions (notably Ni, Cr and Sr abundances), a process of high pressure quartz eclogite melting is consistent with the compositional, mineralogical and phase equilibria characteristics of these HAB lavas. When the relative merits of both origins are weighed it is apparent that a quartz eclogite source satisfies more of important features of these HAB lavas.Extrusive rocks have been grouped on a basis of SiO₂ content into basalt (<52 wt.%), basaltic-andesite (52–56 wt.%) and andesite (>56 wt.%) after Ewart (1982)     

The Cold Bay Volcanic Center,Aleutian Volcanic Arc

The Cold Bay Volcanic Center has experienced two major stages of eruptive activity. Early (M-Series) acitivity produced bimodal Hi-Alumina basalt and calc-alkaline andesite lavas while later (FPK-Series) activity produced only calc-alkaline andesite. The spectrum of basalt compositions is believed to be due to high pressure (8 kb) fractionation at or near the base of the crust. Abundant mineralogical and geochemical evidence support a lower pressure mixing origin for all andesites. Inspection of the mineralogical data has shown that the earliest (M-Series) andesites were produced by mixing of basalt (<53 wt% SiO₂) and silicic andesite (60.5 to 62.5 wt%) while later (FPK-Series) andesites resulted from the mixing of basaltic-andesite (53 to 56 wt%) and less silicic andesite (58.5 to 60.0 wt%). The major element and trace element geochemical data are consistent with a low pressure fractionation origin for the silicic endmember magmas and support the temporal variations in both mafic and silicic endmember compositions. The complete lack of crustal inclusions in all lavas is taken as evidence for a minimal crustal melting and/or assimilation role in the origin of the silicic endmembers. Many of the features of all andesites, including the important long term convergence of endmember magma compositions, are consistent with the process of liquid fractionation, accompanied by large scale magma mixing. A deduced upper limit of 62.5 wt% SiO₂ for the silicic endmember magmas suggests that liquid fractionation, in the absence of major crustal melting, cannot produce more silicic magmas. A possible explanation is the presence of a rheological barrier, based on the concept of critical crystallinity (Marsh 1981), which prohibits more silicic liquids from being extracted from a crystal-liquid suspension.     

Volcanic evolution in eastern Papua

Late Mesozoic and Cenozoic volcanic rocks in eastern Papua record a complex series of volcanotectonic events which reflect interaction between the Indo-Australian and Solomon sea plates. Basement formations of Upper Cretaceous and Eocene submarine basalt are comparable to those characteristic of sea floor spreading centers and are thought to have originated during volcanic activity associated with spreading in the Coral Sea basin. Arc-trench type andesitic volcanism was prominent during the late Cenozoic but shows no clear relationship to a subduction event. An alternative explanation links the development of thickened crust and consequent crust/mantle interaction with the generation of andesitic magmas. The tectonic environment of eastern Papua during the late Cenozoic was one of block faulting and uplift associated with crustal tension. The presence of Quaternary peralkaline rhyolites suggests that this environment is now being replaced by active rifting.     

GIS and Volcanic Risk Management

Volcanic catastrophes constitute a majorproblem in many developing and developed countries. Inrecent years population growth and the expansion ofsettlements and basic supply lines (e.g., water, gas,etc.) have greatly increased the impact of volcanicdisasters. Correct land-use planning is fundamental inminimising both loss of life and damage to property.In this contribution Geographical Information Systems(GIS), linked with remote sensing technology andtelecommunications/warning systems, have emerged asone of the most promising tools to support thedecision-making process. Some GIS are presented fortwo volcanic areas in Italy, Mt. Etna and Vesuvius.GIS role in risk management is then discussed, keepingin mind the different volcanic scenarios of effusiveand explosive phenomena. Mt. Etna system covers alarge area (more than 1,000 km²) potentiallyaffected by effusive phenomena (lava flows) whichcause damage to both houses and properties in general.No risk to life is expected. The time-scales of lavaflows allow, at least in principle, modification ofthe lava path by the building of artificial barriers.Vesuvius shows typically an explosive behaviour. Inthe case of a medium size explosive eruption, 600,000people would potentially have to be evacuated from anarea of about 200 km² around the Volcano, sincethey are exposed to ruinous, very fast phenomena likepyroclastic surges and flows, lahars, ash fallout,etc. Ash fallout and floods/lahars are also expectedin distal areas, between Vesuvius and Avellino,downwind of the volcano. GIS include digital elevationmodels, satellite images, volcanic hazard maps andvector data on natural and artificial features (energysupply lines, strategic buildings, roads, railways,etc.). The nature and the level of detail in the twodata bases are different, on the basis of thedifferent expected volcanic phenomena. The GIS havebeen planned: (a) for volcanic risk mitigation (hazard,value, vulnerability and risk map assessing), (b) toprovide suitable tools during an impending crisis, (c)to provide a basis for emergency plans.     

The Discovery of Late Pleistocene Daliuchong Volcanic Conduit in th Tengchong Volcanic Field

正Objective The Tengchong volcanic field is situated along the southeastern margin of the Tibetan Plateau and adjacent to the border area of western Yunnan Province of China and Myanmar.Affected by the intense tectonic stress of subduction of the Indian plate to Eurasian plate,this volcanic field has experienced strong volcanism,frequent     

Volcanic passive margins

Compared to non-volcanic ones, volcanic passive margins mark continental break-up over a hotter mantle, probably subject to small-scale convection. They present distinctive genetic and structural features. High-rate extension of the lithosphere is associated with catastrophic mantle melting responsible for the accretion of a thick igneous crust. Distinctive structural features of volcanic margins are syn-magmatic and continentward-dipping crustal faults accommodating the seaward flexure of the igneous crust. Volcanic margins present along-axis a magmatic and tectonic segmentation with wavelength similar to adjacent slow-spreading ridges. Their 3D organisation suggests a connection between loci of mantle melting at depths and zones of strain concentration within the lithosphere. Break-up would start and propagate from localized thermally-softened lithospheric zones. These ‘soft points’ could be localized over small-scale convection cells found at the bottom of the lithosphere, where adiabatic mantle melting would specifically occur. The particular structure of the brittle crust at volcanic passive margins could be interpreted by active and sudden oceanward flow of both the unstable hot mantle and the ductile part of the lithosphere during the break-up stage. To cite this article: L. Geoffroy, C. R. Geoscience 337 (2005).     

福建浦城—三都澳火山喷发带早白垩世火山地层划分对比

本文根据浦城—三都澳火山喷发带早白垩世火山活动产物及其所组成的火山构造的解剖研究，在肯定或重新厘定各火山机构内的火山地层层序基础上，建立火山机构一火山岩相－火山地层模式，进行横向对比，阐明火山活动基本特征。     

火山岩中囊状体的特征及其鉴别

熔岩和火山碎屑岩是两类最主要的火山岩,分别代表了两种不同的火山喷发方式和成岩过程,是火山岩分类命名中首先要注意区分的。囊状体具有与浆屑很相似的形态和结构,但对其研究还相当不足,易导致富含囊状体的流纹质—英安质熔岩与富含浆屑的熔结凝灰岩相混淆,产生熔岩与火山碎屑岩分类上的错误。本文首次介绍囊状体的基本特征并分析其与浆屑之区别。囊状体由矿物集合体(结晶内带)和外围脱玻体(脱玻外带)构成,因形态总体似囊状而得名,可呈条带状、透镜状,两端呈撕裂状或须状等,有时也呈斑块状消光和脱玻褪色体;它们是火山岩中微小的高温气相或液相长英质组份结晶、并释热诱发周围玻璃质脱玻形成的一种原生岩石结构。正确区分囊状体和浆屑对火山岩的分类命名及成因研究有重要作用,并避免火山碎屑岩的人为扩大化。     

火山活动的气候影响及其冰芯记录研究进展

系统地总结了不同时间尺度内火山活动影响气候的机理,回顾了不同区域冰芯记录火山喷发物质沉积信号的研究历史,阐述了不同气候模式对火山活动影响气候的数值模拟结果,并指出了相关研究中存在的不确定性.结果表明:火山活动通过释放大量的火山物质气溶胶影响气候波动,在年际至年代际时间尺度上,这种影响是显著的;然而,在更长的时间尺度上这种影响是否仍然存在,尚需更多研究的证实.冰芯中火山喷发物质沉积记录为研究历史时期火山活动及其气候影响提供了必要的参考资料,相关的气候模式利用该沉积记录较好地模拟了火山活动对区域乃至全球尺度气候的影响,为我们认识火山活动影响气候变化的机理提供了重要的理论支持,同时也为研究未来火山活动对气候的可能影响提供了参照.但是,冰芯中火山喷发物质沉积记录研究及数值模式模拟结果中尚存在诸多的问题和不确定性.     

火山岩的分类和命名(熔岩部分)

一、问题的提出 国际地质科学联合会火成岩分类学分会推荐了QAPF图解的分类方案(A.Streckeisen,1979)。这一方案的长处是:各类火山岩的平均成分投影点基本上落在相应的分区内;各区火山岩的名称可以同侵入岩相对     

火山喷发及其环境效应

火山活动是地球内能和热量释放的一种形式,火山喷发对人类生存环境的影响包括两个方面,即：灾害效应和资源效应。一方面,火山喷发是一种自然灾害,它不仅对人类产生直接危害,而且还会诱发次生灾害或对人类的生存环境造成长期的危害。其中对人类生命财产构成严重威胁的火山灾害有熔岩流、火山碎屑流、火山泥流和火山海啸。另一方面,火山活动为人类提供了丰富的矿产资源、地热资源和旅游资源。     

长白山火山活动历史、岩浆演化与喷发机制探讨

广义的长白山火山在我国境内包括著名的天池火山、望天鹅火山、图们江火山和龙岗火山,是我国最大的第四纪火山岩分布区。图们江火山和望天鹅火山活动都始于上新世,喷发活动分别介于上新世—中更新世（5.5~0.19 Ma）和上新世—早更新世（4.77 ~2.12 Ma）。天池火山和龙岗火山属于第四纪火山,喷发活动从早更新世（~2 Ma）持续到全新世。图们江火山岩为溢流式喷发的拉斑玄武岩,望天鹅火山、天池火山和龙岗火山母岩浆都是钾质粗面玄武岩,但经历了不同的演化过程。天池火山和望天鹅火山都经历了钾质粗面玄武岩造盾、粗面岩造锥和晚期碱性酸性岩浆（碱流岩和碱性流纹岩）的喷发;龙岗火山来自地幔的钾质粗面玄武岩浆则未经演化和混染直接喷出地表。图们江火山岩以溢流式喷发的拉斑玄武岩为主,少量玄武质粗安岩等。天池火山造盾之后,地壳岩浆房和地幔岩浆房具互动式喷发特点,来自地幔的钾质粗面玄武岩浆一方面在天池火山锥体内外形成诸多小火山渣锥,另一方面持续补给地壳岩浆房发生岩浆分离结晶作用和混合作用,分别导致双峰式火山岩分布特征和触发千年大喷发。火山岩微量元素和Sr-Nd-Pb同位素示踪揭示,长白山东（图们江火山、望天鹅火山和天池火山）、西（龙岗火山）两区显示地幔非均一性,东区岩浆源区具有软流圈地幔与富集岩石圈地幔混合特征,西区岩浆源区具有相对亏损的较原始地幔特征。西太平洋板块俯冲—东北亚大陆弧后引张是长白山火山活动的动力学机制。