Petrology of Stewart Mountain basalt field in central Arizona, U.S.A.: A lithospheric source with small-scale trace element and isotopic heterogeneities

Q3 Earth and Planetary Sciences

Rocky Mountain Geology Pub Date : 2013-09-01 DOI:10.2113/GSROCKY.48.2.185

K. I. Singer, R. V. Fodor

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引用次数: 4

Abstract

The Stewart Mountain basalt field in central Arizona is composed of three horizons of Miocene lavas over ~4 km 2 . The youngest lava is ~15.5 Ma. The field is in the southern Basin and Range at its transition to the Colorado Plateau. It is also at the northwestern margin of the ~8000 km 2 Goldfield-Superstition volcanic province (G-SVP), where basaltic lavas are ~20–19 Ma. Stewart Mountain basalts are alkalic, and most have from 6–8 weight percent (wt%) MgO, but more primitive and evolved lavas (10.7 and 4 wt% MgO, respectively) are also present. Most incompatible element abundances differ widely for basalts within the 6–8 wt% MgO range, and they distinguish the three horizons (e.g., ranges for P 2 O 5 are 0.5–1.4 wt%; Zr 125–250 ppm; La 40–80 ppm). One lava has quartz and plagioclase xenocrysts and even lower incompatible element abundances (e.g., P 2 O 5 0.25 wt%; La 25 ppm). All Stewart Mountain basalts, however, have Nb-Ta negative anomalies, consistent with a lithospheric mantle source that had subduction characteristics. Isotopic compositions differ across the three basalt horizons (e.g., ranges for 87 Sr/ 86 Sr are 0.7049–0.7061; 206 Pb/ 204 Pb 17.7–19.2; e Nd -3.5 to -6.2), where the xenocrystic lava has the lowest Sr and Pb isotopic ratios. Over its life, the Stewart Mountain field radiogenic isotope ratios decreased to reflect source heterogeneities, and its 206 Pb/ 204 Pb range is as wide as that formed by Oligocene–Miocene basalts collectively across the southern Basin and Range and transition zone. Incompatible-element abundances and ratios also reflect source heterogeneities, whereby the greatest differences are observed as abundances decreasing from middle to upper horizon basalts. Several abundance ratios, such as Zr/Nb, Th/Ta, Th/Nb, and Zr/Hf, record some of the source heterogeneities that are manifested over the short geologic time represented by the successive lava horizons. These temporal compositional changes likely reflect partial melts from a variably metasomatized lithospheric mantle. Compared to the compositions of the older, neighboring G-SVP basalts, Stewart Mountain lavas are generally evolved (MgO <8 wt%). The absence of mantle xenoliths in any Stewart Mountain lava and the xenocrystic lava both point to the compositional evolution having occurred in crustal reservoirs; however, based on the lowest isotopic ratios present in the xenocrystic lava, the upper crust was not a reservoir. Comparing Stewart Mountain basalt incompatible-element abundance ratios to those in the neighboring G-SVP shows enough difference to conclude that these two Miocene basalt localities had lithospheric sources with distinct trace element characteristics. The G-SVP source also had higher, distinguishing e Nd (-1 to -2). All characteristics combined, the Stewart Mountain field shows that lithospheric source heterogeneities can be manifested both temporally and spatially over only a small surface area. Stewart Mountain lithospheric source indicates that magmatism in central Arizona did not have asthenospheric sources by 15 Ma.

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美国亚利桑那州中部斯图尔特山玄武岩田的岩石学:具有小尺度微量元素和同位素非均质性的岩石圈源

美国亚利桑那州中部的斯图尔特山玄武岩田由三层超过4 km 2的中新世熔岩组成。最年轻的熔岩约15.5 Ma。该油田位于盆地和山脉向科罗拉多高原过渡的南部。它也位于~8000 km 2的金迷信火山省(G-SVP)的西北缘，那里的玄武岩熔岩约为~ 20-19 Ma。斯图尔特山玄武岩是碱性的，大多数的MgO重量百分比为6 - 8% (wt%)，但也存在更原始和演化的熔岩(MgO重量百分比分别为10.7和4 wt%)。玄武岩中大多数不相容元素丰度在6-8 wt% MgO范围内差异很大，它们区分了三个层位(例如，p2o的范围为0.5-1.4 wt%;Zr 125-250 ppm;La 40-80 ppm)。一种熔岩有石英和斜长石异种结晶，甚至有更低的不相容元素丰度(如p2o - 0.25 wt%;La 25 ppm)。斯图尔特山玄武岩均存在Nb-Ta负异常，与具有俯冲特征的岩石圈地幔源一致。三个玄武岩层的同位素组成不同(例如，87 Sr/ 86 Sr的范围为0.7049 ~ 0.7061;206pb / 204pb 17.7-19.2;e Nd -3.5 ~ -6.2)，其中异晶熔岩Sr和Pb同位素比值最低。Stewart山野外放射性成因同位素比值在其生命周期中呈下降趋势，反映了源的非均质性，其206 Pb/ 204 Pb范围与盆地南部渐新世-中新世玄武岩共同形成的范围相当。不相容元素丰度和比值也反映了烃源岩的非均质性，其中，中上层玄武岩丰度递减，差异最大。若干丰度比，如Zr/Nb、Th/Ta、Th/Nb和Zr/Hf，记录了在较短的地质时间内由连续的熔岩层代表的一些物源非均质性。这些时间成分的变化可能反映了岩石圈地幔的部分熔融。与邻近的G-SVP玄武岩相比，Stewart山熔岩的组成普遍演化(MgO <8 wt%)。斯图尔特山熔岩中没有地幔捕虏体，且熔岩中有异晶熔岩，说明地壳储层中发生了成分演化;然而，根据异晶熔岩中存在的最低同位素比率，上地壳不是一个储层。将斯图尔特山玄武岩不相容元素丰度比值与邻近的G-SVP进行比较，差异足以说明这两个中新世玄武岩的岩石圈源具有明显的微量元素特征。G-SVP源也具有较高的区别性e Nd(-1至-2)。综合所有特征，斯图尔特山油田表明，岩石圈震源非均质性在时间和空间上都可以在很小的表面上表现出来。斯图尔特山岩石圈源表明，在15 Ma以前，亚利桑那中部的岩浆活动没有软流圈源。

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Rocky Mountain Geology Earth and Planetary Sciences-Geology

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期刊介绍： Rocky Mountain Geology (formerly Contributions to Geology) is published twice yearly by the Department of Geology and Geophysics at the University of Wyoming. The focus of the journal is regional geology and paleontology of the Rocky Mountains and adjacent areas of western North America. This high-impact, scholarly journal, is an important resource for professional earth scientists. The high-quality, refereed articles report original research by top specialists in all aspects of geology and paleontology in the greater Rocky Mountain region.