Flare up of hot-dry-reduced ignimbrites related to extension in the Cascades Arc: the Deschutes Formation, central Oregon

IF 3.5 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS Journal of Petrology Pub Date : 2023-08-08 DOI:10.1093/petrology/egad058
B. Pitcher, A. Grunder, A. Kent
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引用次数: 1

Abstract

Ignimbrite flare-ups are rare periods of intense silicic volcanism during which the pyroclastic volume and eruptive frequency is more than an order of magnitude higher than background activity. Investigating the compositional differences between flare-up and steady-state magmas provides critical constraints on the petrogenetic causes for the event and can offer unique opportunities to investigate the role of large-scale tectonic or geodynamic processes in arc magmatism. In this study, we focus on the bimodal Deschutes Formation ignimbrite flare-up of Central Oregon, which erupted unusually high volumes of pyroclastic material 6.25-5.45 Ma from a new axis of volcanism in the Cascades arc. This episode is marked by increased eruption rates and eruption of more silicic compositions relative to the Quaternary Cascade arc, which rarely erupts rhyolites. Ignimbrites are crystal-poor (< 10%) dacite to rhyolites (mostly 65-77 wt. % SiO2) with anhydrous mineral assemblages and higher FeO/MgO, Y, Eu/Eu*, MREE and Zr/Sr, indicating drier magmatic evolution compared to the Quaternary arc, and are more similar to those from the rear-arc High Lava Plains (HLP) province that lies to the east. Magnetite-ilmenite oxybarometry indicates that Deschutes Formation felsic magmas tend to be hotter and more reduced (NNO-1 to NNO) than the Quaternary arc (NNO to NNO+1.5). Rhyolite-MELTS geobarometry suggests complex storage of diverse Deschutes Formation magmas within the shallow crust (50 – 250 MPa), and the common co-eruption of multiple plagioclase populations, pumice compositions, and compositionally banded pumice suggest variable degrees of mixing and mingling of distinct magmas. Deschutes magmas also have low δ18Oplagioclase values that indicate partial melting and assimilation of hydrothermally altered shallow crust. Trace element systematics and rhyolite-MELTS modelling suggests that felsic pumice cannot be produced by simple fractionation of co-erupted mafic pumice or basaltic lavas, and requires a crustal melting origin, and trace elements and Pb isotopes suggest that young mafic crust may have been the primary protolith. We suggest that partial melting produced low-Si rhyolite melt (~72 wt. %) that acted as both a parent for the most evolved rhyolites, and as a mixing endmember to create the dacite to rhyodacite magmas with heterogenous plagioclase populations. Unlike the predominantly calc-alkaline basalts erupted in the Quaternary Cascade arc, Deschutes Formation primary basalts are mostly low-K tholeiites, indicative of decompression melting. These are similar to the compositions erupted during a contemporaneous pulse of low-K tholeiite volcanism across the whole HLP that reached into the Cascades rear-arc. We suggest that intra-arc extension focused decompression melts from the back-arc into the arc and that tensional stresses allowed this high flux of hot-dry-reduced basalt throughout the crustal column, causing partial melting of mafic protoliths and the production of hot-dry-reduced rhyolite melts. Depletion of incompatible elements in successive rhyolites implies progressive depletion in fertility of the protolith. Extension also allowed for the establishment of a robust hydrothermal system, and assimilation of hydrothermally-altered rocks by magmas residing in a shallow, complex storage network lead to low δ18O melts. Our findings suggest the integral role that extensional tectonics played in producing an unusual ignimbrite flare-up of hot-dry-reduced rhyolite magmas that are atypical of the Cascades arc and may be an important contributor to flare-ups at arcs worldwide.
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与喀斯喀特弧的延伸有关的干热还原烟灰的爆发:俄勒冈州中部的德舒特地层
火成岩爆发是罕见的强烈的硅火山活动时期,在此期间,火山碎屑体积和喷发频率比背景活动高一个数量级以上。研究爆发岩浆和稳定岩浆之间的成分差异,为研究该事件的成因提供了关键的约束条件,并为研究大型构造或地球动力学过程在弧岩浆活动中的作用提供了独特的机会。在这项研究中,我们关注的是俄勒冈中部的双峰Deschutes组火成岩爆发,它从Cascades弧的一个新的火山活动轴喷发了异常大量的火山碎屑物质6.25-5.45 Ma。与第四纪级联弧相比,这一时期的喷发速率增加,喷发的硅成分较多,而第四纪级联弧很少喷发流纹岩。暗斑岩为贫晶英安岩—流纹岩(主要为65 ~ 77 wt. % SiO2),矿物组合无水,FeO/MgO、Y、Eu/Eu*、MREE和Zr/Sr较高,与第四纪弧相比岩浆演化较为干燥,与弧后高熔岩平原(HLP)省更为相似。磁铁矿-钛铁矿氧压测量表明,Deschutes组长英质岩浆比第四纪弧(NNO ~ NNO+1.5)更热、更还原(NNO-1 ~ NNO)。流纹岩-熔体地球压测量表明,浅层地壳(50 ~ 250 MPa)内存在多种德舒特组岩浆的复杂储层,多种斜长石群、浮石组成和带状浮石的共同喷发表明,不同的岩浆存在不同程度的混合和混染。Deschutes岩浆的δ 18o斜长石值也较低,表明其浅层地壳存在热液蚀变的部分熔融和同化作用。微量元素系统和流纹岩-熔体模拟表明,长英质浮石不可能由共喷发的基性浮石或玄武岩熔岩的简单分选产生,而需要地壳熔融成因,微量元素和Pb同位素表明,年轻的基性地壳可能是主要的原岩。我们认为,部分熔融产生了低硅流纹岩熔体(~72 wt. %),它既是最进化的流纹岩的母体,也是形成具有非均质斜长石群的英安岩-流纹岩岩浆的混合末端成员。与第四纪级联弧喷发的钙碱性玄武岩不同,德舒特组原生玄武岩多为低钾拉斑岩,具有减压熔融特征。这些成分与同时期的低钾拉斑火山活动脉冲喷发的成分相似,这些火山活动贯穿整个HLP,一直延伸到喀斯喀特弧后。我们认为,弧内伸展集中的减压熔体从弧后进入弧内,张应力使得这种高通量的热干还原玄武岩贯穿整个地壳柱,导致基性原岩部分熔融,并产生热干还原流纹岩熔体。不相容元素在连续流纹岩中的耗竭意味着原岩的肥力逐渐耗竭。伸展也允许建立一个强大的热液系统,并且位于浅层复杂储存网络中的岩浆对热液蚀变岩的同化导致低δ18O熔体。我们的研究结果表明,伸展构造在产生非典型喀斯喀特弧的干热还原流纹岩岩浆的不寻常的火成岩爆发中发挥了不可或缺的作用,这可能是世界范围内弧爆发的重要因素。
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来源期刊
Journal of Petrology
Journal of Petrology 地学-地球化学与地球物理
CiteScore
6.90
自引率
12.80%
发文量
117
审稿时长
12 months
期刊介绍: The Journal of Petrology provides an international forum for the publication of high quality research in the broad field of igneous and metamorphic petrology and petrogenesis. Papers published cover a vast range of topics in areas such as major element, trace element and isotope geochemistry and geochronology applied to petrogenesis; experimental petrology; processes of magma generation, differentiation and emplacement; quantitative studies of rock-forming minerals and their paragenesis; regional studies of igneous and meta morphic rocks which contribute to the solution of fundamental petrological problems; theoretical modelling of petrogenetic processes.
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