大陆弧火成岩爆发的前兆:美国科罗拉多州圣胡安山脉的早期中心火山

IF 1.7 3区 地球科学 Q3 GEOSCIENCES, MULTIDISCIPLINARY
Geosphere Pub Date : 2023-12-20 DOI:10.1130/ges02691.1
P. Lipman, M. Zimmerer, A.K. Gilmer
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引用次数: 0

摘要

我们新近获得并发表的有关圣胡安山脉东北部早期中等构造中心火山的地图、地质年代和组合位置数据,为我们深入了解新生代中期南落基山火山区(SRMVF)大型大陆弧点火岩浆爆发的广泛岩浆前兆提供了帮助。作为北美科迪勒拉山系美国段中新生代岩浆活动向南发展的区域性趋势的一部分,最初的火山活动大约在 40-29 Ma 年间从科罗拉多州中部迁移到新墨西哥州北部。圣胡安地块是 SRMVF 保存下来的最大侵蚀遗迹,也是喷发活动最剧烈的地方,在圣胡安地块内,新的 40Ar/39Ar 和 U-Pb 锆石年龄显示,许多单个建筑物的喷发几乎是同时开始的,时间约为 35 Ma,活动高峰期为 34 Ma。35 Ma,活动高峰期为 34-32 Ma。大体相似的前驱喷出火山活动是美国西部海岸山脉大陆弧火成岩岩浆活动的其他主要地点的特征,但这些地点都没有记录到像科罗拉多州圣胡安地点那样数量巨大、空间广泛、暴露良好或成分多样的早期火山活动。早期的圣胡安火山活动在体积上大于后来的点火岩,约占喷发总量的三分之二。早期的熔岩和角砾岩沿着圣胡安山脉被侵蚀的侧面露出地面,厚度达 700-900 米;钻孔穿透的部分厚达 2600 米。这种火山活动被广泛解释为由来自地幔的玄武岩岩浆引发的,但在圣胡安地点几乎不存在新生代中期的玄武岩--据推断,不存在玄武岩的原因是广泛的低地壳同化和分馏。早期火山岩呈钙碱性,是典型的高K大陆弧火山活动;从圣胡安地点向东北进入科罗拉多州中部,火山岩的碱性略有增强,并富含微量元素,如轻稀土元素、Zr、Nb和Th。这种变化可能反映了地壳的同步增厚和更深层次的原生岩浆生成,与此同时,上地壳岩浆体也在集结,可以支持大型燃爆岩的喷发。然而,早期火山的生长历史仍然存在很大的不确定性,这是因为火山建筑物的下部尚未暴露,上部受到侵蚀,而且能够可靠测定年代的矿物相有限。虽然早火山广泛分布在SRMVF内,但许多都集中在随后的火成岩破火山口的位置。据推断,这些前驱火山记录了整个平流层浴石规模岩浆系统建造过程中的孕育阶段。岩浆生成、积聚、分馏和凝固的长期递增过程间歇性地产生了足够的液体来喷发大型火成岩。在圣胡安山脉的一些中心,集中喷发和侵入的成熟期较长,在最终形成火成岩之前需要5 m.y.或更长的时间。一些大体积的火成岩和相关的火山口,包括约 5000 千立方米的鱼峡谷凝灰岩和相关的拉加里塔火山口,比相关前火山的高峰期晚几百万年才形成,记录了一个持续的喷发活动减弱期,因为岩浆库的体积增大,并演变成更多的硅质成分,能够支持随后的大体积火成岩喷发。SRMVF 中几乎同时活跃的早期火山的堤坝构造各不相同,有的呈放射状对称分布,有的呈平行分布。据推断,这些截然不同的堤坝几何形状可能记录了区域应力从压缩到微弱伸展的多次波动,与此同时,之前的平板板块构造不稳定,引发了新生代中期沿北美板块科迪勒拉边缘的火烧云爆发。这些明显的区域应力波动发生在南落基山地区出现大量伸展应变之前;SRMVF 的外流火烧云片在格兰德河断裂的后续地角和堑壕结构中扩散,但没有出现厚度互补变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Precursors to a continental-arc ignimbrite flare-up: Early central volcanoes of the San Juan Mountains, Colorado, USA
Our newly acquired and recently published map, geochronologic, and com- positional data for early intermediate-composition central volcanoes in the northeastern San Juan Mountains provide insights about the broad magmatic precursors to the large continental-arc ignimbrite flare-up in the mid-Cenozoic Southern Rocky Mountain volcanic field (SRMVF). Initial volcanism migrated from central Colorado to northern New Mexico ca. 40–29 Ma, as part of a more regional trend of southward-progressing mid-Cenozoic magmatism in the U.S. segment of the North American Cordillera. Within the San Juan locus, which represents the largest preserved erosional remnant of the SRMVF and site of most intense eruptive activity, new 40Ar/39Ar and U-Pb zircon ages show that eruptions at many individual edifices began nearly concurrently, at ca. 35 Ma, with peak activity at 34–32 Ma. Broadly similar precursor effusive volcanism characterizes other major loci of continental-arc ignimbrite magmatism along the western American cordilleras, but none of these sites records early volcanism as voluminous, spatially widespread, well exposed, or compositionally diverse as the San Juan locus in Colorado. Early San Juan volcanism was larger in volume than the later ignimbrites, constituting about two thirds the total erupted. Early lava and breccias are as much as 700–900 m thick where exposed along eroded flanks of the San Juan Mountains; drill holes have penetrated sections as thick as 2600 m. The early volcanoes were dominantly andesitic, with lesser dacite and minor rhyolite. Such volcanism is widely interpreted as initiated by basaltic magma from the mantle, but mid-Cenozoic basalt is almost nonexistent at the San Juan locus—an absence inferred to be due to extensive lower-crustal assimilation and fractionation. The early volcanic rocks are calc-alkaline and typical of high-K continental-arc volcanism; they become modestly more alkalic and enriched in trace elements such as light rare earth elements, Zr, Nb, and Th from the San Juan locus northeastward into central Colorado. Such variations may reflect synmagmatic crustal thickening and deeper levels of primary magma generation concurrent with assembly of upper-crustal magma bodies that could support large ignimbrite eruptions. Substantial uncertainties remain for growth histories of the early volcanoes, however, because of unexposed lower parts of edifices, eroded upper parts, and limited availability of mineral phases that could be dated reliably. Although the early volcanoes are widely distributed within the SRMVF, many are clustered at sites of subsequent ignimbrite calderas. The precursor edifices are inferred to record incubation stages in construction of overall translithospheric batholithic-scale magmatic systems. Prolonged processes of incremental magma generation, accumulation, fractionation, and solidification intermittently generated sufficient liquid to erupt large ignimbrites. Maturation of focused eruptions and intrusions was prolonged, 5 m.y. or more, prior to the culminating ignimbrite at some centers in the San Juan Mountains. Some large-volume ignimbrites and related calderas, including the ~5000 km3 Fish Canyon Tuff and associated La Garita caldera, formed as much as several million years later than peak growth of associated precursor volcanoes, recording a sustained interval of diminished eruptive activity as the magma reservoir increased in volume and evolved to more silicic compositions capable of supporting a subsequent large ignimbrite eruption. Dike configurations at early volcanoes that were active nearly concurrently in the SRMVF vary from symmetrically radial to more parallel trends. The contrasting dike geometries are inferred to record possible multiple fluctuations from compressive to weakly extensional regional stress, concurrent with destabilization of the prior flat-slab plate configuration that triggered mid-Cenozoic ignimbrite flare-ups along the Cordilleran margin of the North American plate. These apparent fluctuations in regional stress preceded development of substantial extensional strain in the Southern Rocky Mountain region; outflow ignimbrite sheets of the SRMVF spread across subsequent horst-and-graben structures of the Rio Grande rift without complementary thickness variations.
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来源期刊
Geosphere
Geosphere 地学-地球科学综合
CiteScore
4.40
自引率
12.00%
发文量
71
审稿时长
6-12 weeks
期刊介绍: Geosphere is GSA''s ambitious, online-only publication that addresses the growing need for timely publication of research results, data, software, and educational developments in ways that cannot be addressed by traditional formats. The journal''s rigorously peer-reviewed, high-quality research papers target an international audience in all geoscience fields. Its innovative format encourages extensive use of color, animations, interactivity, and oversize figures (maps, cross sections, etc.), and provides easy access to resources such as GIS databases, data archives, and modeling results. Geosphere''s broad scope and variety of contributions is a refreshing addition to traditional journals.
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