The rheology of rhyolite magma from the IDDP-1 borehole and Hrafntinnuhryggur (Krafla, Iceland) with implications for geothermal drilling

IF 2.4 3区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Journal of Volcanology and Geothermal Research Pub Date : 2024-08-02 DOI:10.1016/j.jvolgeores.2024.108159

Fabian B. Wadsworth , Jérémie Vasseur , Yan Lavallée , Kai-Uwe Hess , Jackie E. Kendrick , Jonathan M. Castro , Daniel Weidendorfer , Shane M. Rooyakkers , Annabelle Foster , Lucy E. Jackson , Ben M. Kennedy , Alexander R.L. Nichols , C. Ian Schipper , Bettina Scheu , Donald B. Dingwell , Tamiko Watson , Georgina Rule , Taylor Witcher , Hugh Tuffen

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引用次数: 0

Abstract

Changes in rhyolite melt viscosity during magma decompression and degassing exert a first order control on ascent through the crust and volcanic eruption style. These changes have as yet unknown hazard implications for geothermal drilling in pursuit of particularly hot fluids close to magma storage regions. Here, we exploit the situation at Krafla volcano in which rhyolite has both erupted at Earth's surface and been sampled at shallow storage depths via drilling of the 2009 IDDP-1 and 2008 KJ-39 boreholes. We use differential scanning calorimetry to constrain that the IDDP-1 magma quenched to glass at ∼ 700 K, at a rate of between 7 and 80 K.min⁻¹. We measure the equilibrium viscosity of the IDDP-1 rhyolite at temperatures close to the glass transition interval and show that the rhyolite viscosity is consistent with generalized viscosity models assuming a dissolved $H_{2} O$ concentration of $2.12$ wt%. We couple these results with micro-penetration and concentric cylinder rheometry over a range of potential magma storage temperatures to constrain the response of surficial Krafla rhyolites to stress. The surficial rhyolites at Krafla match the same viscosity model, assuming a lower dissolved $H_{2} O$ concentration of $0.12$ wt%. Our results show that at a storage temperature of 1123–1193 K, the viscosity of the stored magma is ∼ 3×10⁵ Pa.s. At the same temperature, the viscosity following degassing during ascent to the surface rises to ∼ 2×10⁹ Pa.s. Finally, we use high-stress compression tests on the Hrafntinnuhryggur surface obsidian to determine the onset of unrelaxed behavior and viscoelastic melt rupture or fragmentation pertinent to understanding the melt response to rapid pressure changes that may be associated with further (near-) magma exploration at Krafla. Taken together, we characterize the relaxation and viscosity of these magmas from source-to-surface.

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IDDP-1 号钻孔和 Hrafntinnuhryggur（冰岛克拉弗拉）流纹岩岩浆的流变学及其对地热钻探的影响

在岩浆减压和脱气过程中，流纹岩熔体粘度的变化对地壳上升和火山喷发方式具有一阶控制作用。这些变化对在岩浆贮存区附近进行地热钻探以寻找特别热的流体具有未知的危险影响。在这里，我们利用克拉弗拉火山的情况，即流纹岩既在地球表面喷发，又通过 2009 年 IDDP-1 和 2008 年 KJ-39 井眼的钻探在浅层贮存深度取样。我们利用差示扫描量热法推测，IDDP-1岩浆是在∼700 K时以7至80 K.min-1的速度淬火成玻璃状的。我们测量了 IDDP-1 流纹岩在接近玻璃化转变区间温度下的平衡粘度，结果表明流纹岩粘度与假设溶解 H2O 浓度为 2.12 wt%的广义粘度模型一致。我们将这些结果与岩浆潜在贮存温度范围内的微穿透和同心圆流变仪结合起来，以确定克拉弗拉表层流纹岩对应力的反应。克拉弗拉的表层流纹岩符合相同的粘度模型，但假设溶解的 H2O 浓度较低，为 0.12 wt%。我们的结果表明，在 1123-1193 K 的贮存温度下，贮存岩浆的粘度为 3×105 Pa.s。最后，我们利用对Hrafntinnuhryggur表面黑曜石的高压力压缩试验来确定非松弛行为和粘弹性熔体破裂或碎裂的开始时间，以了解熔体对快速压力变化的反应，这可能与克拉弗拉岩浆的进一步（近距离）勘探有关。总之，我们描述了这些岩浆从源头到地表的松弛和粘度特征。

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来源期刊

Journal of Volcanology and Geothermal Research 地学-地球科学综合

CiteScore

5.90

自引率

13.80%

发文量

183

审稿时长

19.7 weeks

期刊介绍： An international research journal with focus on volcanic and geothermal processes and their impact on the environment and society. Submission of papers covering the following aspects of volcanology and geothermal research are encouraged: (1) Geological aspects of volcanic systems: volcano stratigraphy, structure and tectonic influence; eruptive history; evolution of volcanic landforms; eruption style and progress; dispersal patterns of lava and ash; analysis of real-time eruption observations. (2) Geochemical and petrological aspects of volcanic rocks: magma genesis and evolution; crystallization; volatile compositions, solubility, and degassing; volcanic petrography and textural analysis. (3) Hydrology, geochemistry and measurement of volcanic and hydrothermal fluids: volcanic gas emissions; fumaroles and springs; crater lakes; hydrothermal mineralization. (4) Geophysical aspects of volcanic systems: physical properties of volcanic rocks and magmas; heat flow studies; volcano seismology, geodesy and remote sensing. (5) Computational modeling and experimental simulation of magmatic and hydrothermal processes: eruption dynamics; magma transport and storage; plume dynamics and ash dispersal; lava flow dynamics; hydrothermal fluid flow; thermodynamics of aqueous fluids and melts. (6) Volcano hazard and risk research: hazard zonation methodology, development of forecasting tools; assessment techniques for vulnerability and impact.