吉林龙岗第四纪火山活动分期

在约1700km^2的龙岗火山区内分布100多个玄武质岩浆爆破成因的火山渣锥和射气岩浆成因的低平火山口－龙湾，最新喷发距今约1500－1600年。本文在火山地质研究基础上，测定了龙岗第四纪火山活动形成的熔岩台地、火山渣锥、低平火山口、火山碎屑席等不同火山地质体的31个火山岩K－Ar年龄和2个岩化木与与泥炭层的^14C年龄，厘定了龙岗第四纪3期火山活动的时间：小椅山期（早更新世：2．15－0．75Ma）、龙岗期（中－晚更新世：0．68－0．05Ma）和金龙顶子期（全新世：1600－1500a.BP）。     

内蒙东部晚第四纪火山活动与新构造

本文所指的晚第四纪包括晚更新世和全新世。内蒙东部晚第四纪火山活动强烈,北起大兴安岭北部的鄂伦春诺敏河火山群、经阿尔山-柴河、锡林浩特-阿巴嘎火山群,南抵察右后旗乌兰哈达火山群,断续延伸约1000km,分布着约390余座大小不一、形态各异的火山,构成了内蒙东部壮观的北北东向第四纪火山喷发带。火山类型包括玛珥式、夏威夷式、斯通博利式、亚布里尼式和冰岛式,以斯通博利式最为发育。爆破式火山作用包括射汽、射汽-岩浆爆发和岩浆爆发。火山岩类型主要为碱性玄武岩及其火山碎屑物(岩),火山岩具初期裂谷构造属性。火山活动主体受北北东向基底断裂控制,但就具体火山群而言,又多处于北东和北西向基底深断裂交会处。区内新构造与火山活动密切相关,深部岩浆的上侵,可能是控制本区新构造活动的主因。尤其是全新世火山的空间展布,显示了内蒙东部新构造的活动性。     

吉林省龙岗火山群南龙湾第四纪火山碎屑颗粒特征研究

爆炸性火山喷发形成的碎屑颗粒的粒度、分选性、表面结构和内部结构等特征与火山喷发的机制、岩浆与水作用的程度、搬运过程等有着重要的联系。本文以此为线索,研究了龙岗火山群南龙湾火山的一个剖面,以探讨其喷发类型和特征。在该剖面上采集了不同层位火山碎屑颗粒样品,然后进行显微形貌观测、粒度分析和扫描电镜形貌观测。显微镜下观测表明,射汽爆发、射汽岩浆爆发和岩浆爆发的碎屑颗粒具有不同的成分和形貌特征。粒度分析结果显示,粒度与喷发类型之间存在很好的对应关系,不同的爆发类型具有不同的分维值D范围。SEM分析可以提供有关火山喷发特征对火山碎屑颗粒的影响。本文的研究结果表明,南龙湾火山喷发为爆炸式喷发,包括早期的射汽岩浆爆发,到岩浆爆发至晚期以射汽爆发为主的射汽岩浆爆发的不同阶段,该区火山喷发的不同时期,水参与喷发的程度不同。     

大兴安岭哈拉哈河-绰尔河第四纪火山分期: K-Ar年代学与火山地质特征

大兴安岭中部哈拉哈河-绰尔河第四纪火山区分布有34座火山,这些火山总体呈北东向带状分布,火山岩分布面积约400 km2,岩性主要为碱性橄榄玄武岩.根据火山地质特征,结合火山岩K-Ar测年结果,哈拉哈河-绰尔河第四纪火山可进一步划分为早、中、晚更新世和全新世4期.早更新世火山岩,由于被后期火山岩覆盖,主要分布于火山区周边和出露在河谷中.中更新世火山活动最强,不论火山数量(27座)还是熔岩流规模都超过该区第四纪火山的一半以上.晚更新世时期火山活动趋弱,火山活动范围缩小,只局限于小范围区域.全新世火山活动又进入新的高峰期,强爆破式喷发和规模宏大的熔岩流,以及保存完好的熔岩流地貌是全新世火山之特点.     

内蒙古达里诺尔晚新生代火山群喷发特征研究

达里诺尔火山群有近百座晚新生代单成因火山,其地质地貌形态各异,喷发形式多样。这些火山既有爆破式喷发,如:夏威夷式喷发,斯通博利式喷发,强斯通博利式喷发和射汽岩浆喷发;也有溢流式喷发,如盾状火山;还有岩浆缓慢侵出,如大黑山。火山群内典型火山机构表明,不同的喷发方式穿插于火山喷发过程:早期火山活动多以侵出和溢流为主,逐渐转变为岩浆爆破式喷发(强斯通博利式,斯通博利式),晚期又过渡为溢流式喷发,喷发过程大体经历一个爆破强度弱-强-弱的转变。射汽岩浆型的火山则是以剧烈的射汽岩浆爆炸开始,后期逐渐转弱为岩浆爆破喷发和溢流喷发。火山喷发过程中火山产物出现牛顿流体,宾汉流体,层流,颗粒流,涌流,空降等不同类型的运动形式,自火口向远源运动,形成差异化的火山产物。岩浆的输送速率、上升速度,以及围岩的类型,可能是造成达里诺尔火山群多样化喷发的主要因素。     

吉林省龙岗火山群地质构造特征研究

本文就龙岗火山群的区域地质构造、火山体分布、喷发活动时代、岩石类型及岩石化学特征等,进行概略的论述。火山群分布面积约1170km~2,共有大、小火山167个,它们主要受北东和北西走向断裂的控制,火山口处于上述二组断裂的交汇点上。按其喷发时代由老至新分为四期:①中更新世中期(大椅子山组),有33个火山锥体,分布于龙湾—龙泉湾断裂以西地区,喷发物由火山熔岩、火山集块岩、火山弹组成:②晚更新世(新开岭组),喷发活动集中在东部的新开岭—四海一带,共有134个火山锥,喷发物为玄武质火山熔岩:③全新世早期(四海组),它是早期火山的又一次复活,以火山熔渣堆积为主;④全新世末期(金龙顶子组),它分布较小,且喷发强度亦大为减弱,以溢出相玄武岩流为主。     

龙岗火山喷发特征与火山岩化学初步研究

龙岗火山是中国少数几个近代仍有喷发的活动火山区之一,在1700多平方千米火山区内形成100多个玄武质岩浆爆炸成因的火山锥和低平火口湖(龙湾),并有约1600 a BP喷发的金龙顶子活火山。龙岗火山岩是单一的粗面玄武岩,具有一致的化学成分,表明岩浆上升过程中很少演化,推测龙岗火山岩来自同源地幔岩浆。     

吉林省新生代龙岗火山群期次划分及火山喷发类型特点

吉林省龙岗地区龙岗火山群,新生代火山活动可划分为5个火山喷发期次,由老至新为：船底山期、小椅子山期、大椅子山期、金龙顶子期、四海期。根据对各期火山岩相的研究,确定了它们的火山喷发类型。     

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。     

大兴安岭哈拉哈河—淖尔河地区第四纪火山活动初步研究

大兴安岭中部哈拉哈河-淖尔河地区受基底断裂控制,发育28座第四纪火山,这些火山总体呈北东向带状分布。研究区第四纪火山岩分布面积约1000km^2,岩性主要为碱性玄武岩。根据喷发时代和火山地质特征,这里的火山大体可分为更新世和全新世两期。按照火山作用方式不同,区内火山可分为岩浆成因和射汽岩浆成因两类：前者活动产物主要包括火山碎屑锥、碎屑席、熔岩流,其中发育结壳熔岩、渣状熔岩、块状熔岩,以及喷气锥、熔岩冢等火山地质现象;后者产物主要是射汽岩浆喷发形成的基浪堆积物,其中发育大型平行层理及交错层理。不同的火山作用形成了火山口湖、低平火山口湖、火山堰塞湖和塌陷熔岩湖四种不同规模与形态特征的湖泊,这种水火相容的火山地质现象为阿尔山火山温泉国家地质公园增添了景观。     

Geoheritage values of one of the largest maar craters in the Arabian Peninsula: the Al Wahbah Crater and other volcanoes (Harrat Kishb, Saudi Arabia)

Al Wahbah Crater is one of the largest and deepest Quaternary maar craters in the Arabian Peninsula. It is NW-SE-elongated, ～2.3 km wide, ～250 m deep and surrounded by an irregular near-perpendicular crater wall cut deeply into the Proterozoic diorite basement. Very few scientific studies have been conducted on this unique site, especially in respect to understanding the associated volcanic eruption processes. Al Wahbah and adjacent large explosion craters are currently a research subject in an international project, Volcanic Risk in Saudi Arabia (VORiSA). The focus of VORiSA is to characterise the volcanic hazards and eruption mechanisms of the vast volcanic fields in Western Saudi Arabia, while also defining the unique volcanic features of this region for use in future geoconservation, geoeducation and geotourism projects. Al Wahbah is inferred to be a maar crater that formed due to an explosive interaction of magma and water. The crater is surrounded by a tephra ring that consists predominantly of base surge deposits accumulated over a pre-maar scoria cone and underlying multiple lava flow units. The tephra ring acted as an obstacle against younger lava flows that were diverted along the margin of the tephra ring creating unique lava flow surface textures that recorded inflation and deflation processes along the margin of the post-maar lava flow. Al Wahbah is a unique geological feature that is not only a dramatic landform but also a site that can promote our understanding of complex phreatomagmatic monogenetic volcanism. The complex geological features perfectly preserved at Al Wahbah makes this site as an excellent geotope and a potential centre of geoeducation programs that could lead to the establishment of a geopark in the broader area at the Kishb Volcanic Field.     

火山活动与构造气候旋回

火山活动是一种重要的地质现象,它的发生总是与构造运动相关联,构造运动有强有弱,持续时间有长有短,具有旋目性,火山活动同样也具有旋回性。大规模的火山喷发往往会对气候变化产生影响,而影响的程度取决于火山所处的位置和喷发的性质及程度。强烈的火山喷发将造成局部地区乃至全球气温下降,由此人们推测火山喷发多发生在冰期,然而统计资料表明,绝大多数火山喷发发生在间冰期,此时的构造运动也比较活跃,而在冰期时很少有火山喷发。至于火山喷发后在短时间内造成的降温与长时间的冰期不能相提并论。火山活动有旋回性,它影响的气候变化也具备有旋回性,这是构造气候旋回的一种表现形式。     

Widespread transport of pyroclastic density currents from a large silicic tuff ring: the Glaramara tuff, Scafell caldera, English Lake District, UK

The Glaramara tuff presents extensive exposures of the medial and distal deposits of a large tuff ring (original area >800 km²) that grew within an alluvial to lacustrine caldera basin. Detailed analysis and correlation of 21 sections through the tuff show that the eruption involved phreatomagmatic to magmatic explosions resulting from the interaction of dacitic magma and shallow-aquifer water. As the eruption developed to peak intensity, numerous, powerful single-surge pyroclastic density currents reached beyond 8 km from the vent, probably >12 km. The currents were strongly depletive and deposited coarse lapilli (>5 cm in diameter) up to 5 km from source, with only fine ash and accretionary lapilli deposited beyond this. As the eruption intensity waned, currents deposited fine ash and accretionary lapilli across both distal and medial regions. The simple wax–wane cycle of the eruption produced an overall upward coarsening to fining sequence of the vertical lithofacies succession together with a corresponding progradational to retrogradational succession of lithofacies relative to the vent. Various downcurrent facies transitions record transformations of the depositional flow-boundary zones as the depletive currents evolved with distance, in some cases transforming from granular fluid-based to fully dilute currents primarily as a result of loss of granular fluid by deposition. The tuff-ring deposits share several characteristics with (larger) ignimbrite sheets formed during Plinian eruptions and this underscores some overall similarities between pyroclastic density currents that form tuff rings and those that deposit large-volume ignimbrites. Tuff-ring explosive activity with such a wide area of impact is not commonly recognized, but it records the possibility of such currents and this should be factored into hazard assessments.     

Porewater pressure increases in soil and rock from underground chemical and nuclear explosions

A review and analysis of chemical and nuclear explosive-induced porewater pressure increases and induced rise in groundwater table elevations (groundwater mounding) is presented. Our analysis indicates that residual pore pressure increases and groundwater mounding can be induced by underground chemical and nuclear explosions to scaled distances of 879 m/(kt)^1/3. This relationship is linear over seven orders of magnitude of explosive energy ranging from a 0.01 kg chemical explosion to a 100 kt nuclear explosion and is valid for a wide variety of saturated geological profiles. Underground chemical explosions, and probably underground nuclear explosions have the potential to induce liquefaction of water-saturated soils to scaled distances of about 260 m/(kt)^1/3.     

Sur le mécanisme des éruptions basaltiques sous-marines à faibles profundeurs et la genèse d'hyaloclastites associées

A basaltic eruption occurring in relatively shallow waters looks drastically different from the same occurring on land.

1. Explosive phenomena are exceptionally violent (height several times the height reached in subaerial basaltic eruptions); 2) frequency of explosions very much higher (20 to 90 explosions per minute vs 0.1 to 10); 3) proportion of pyroclasts much higher too, reaching up to 99% of the total outpour; 4) pyroclasts much finer than that of land basaltic eruptions, having a granulometry similar to that of acid pyroclasts.

According to the author, these differences are due to series of phreatic (steam) explosions rapidly following each violent magmatic (gas phase) event. By magmatic event, we mean actual explosion as well as the violent mashing of the upper part of the lava column; the necessary condition being an initial fragmentation of the lava enabling a comparatively large area of very high temperature material being put into contact with water to produce a first steam explosion; this phreatic explosion shatters the fragments from the magmatic explosion, letting new incandescent surfaces to be put into contact with water, thus producing a 2 d steam explosion; this brings former fragments to smaller shatters still, and so on. This process enables a very quick transformation of the heat content of a given volume of lava into kinetic energy, explaining the specific characteristics observed, as well as their absence when only quiet effusive flows (or lava lake) occurs under-water, where no initial magmatic explosion happens to expose large enough area of high temperature lava.     

The genesis of pyroclasts and the mechanism of submarine eruption of Naozhou Island in Guangdong,South ChinaSCIEI北大核心CSCD

水下火山喷发作用机制不同于陆地环境喷发,随着水参与程度的变化,喷发机制趋向复杂。本文以雷琼火山群的湛江硇洲岛作为研究对象,聚焦浅海火山产物的判断依据和水下火山喷发机制。硇洲岛是我国最大的第四纪火山岛,其上的那晏湾剖面保留了完整的火山喷发堆积序列。在那晏湾剖面的凝灰岩中,主要有三类火山成因的大粒径原生碎屑(2-5mm):塑变熔岩碎屑、碎玄玻璃及玄武玻璃,推断为不同程度水-岩浆相互作用的产物,根据水的参与程度大致排序为:碎玄玻璃>玄武玻璃>塑变熔岩碎屑。通过对硇洲岛水-火山作用机制研究,发现水-岩浆混合质量比(Mwater/Mmelt)是控制爆炸强度和火山碎屑粒度的关键因素。火山喷发序列分析表明,硇洲岛的喷发过程总体可分为三期,早期是冰岛苏特塞式喷发的浅水环境蒸汽爆炸与“火喷泉”喷发;中期过渡转为“火喷泉”喷发,伴随陆上的射汽岩浆喷发;最终以岩浆溢流式喷发结束。