Insights into the development of small-volume long lava flows: A case study of the Coalstoun Lakes Volcanic Field, southeast Queensland, Australia

IF 2.4 3区地球科学 Q2 GEOSCIENCES, MULTIDISCIPLINARY

Journal of Volcanology and Geothermal Research Pub Date : 2024-05-31 DOI:10.1016/j.jvolgeores.2024.108115

Catherine Brown , Scott E. Bryan , David A. Gust , Hayden Dalton

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引用次数: 0

Abstract

Long lava flows exceeding 50 km in length are usually produced during large-volume flood basalt eruptions (>100 to 10,000 km³) but can also occur from small to moderate-volume (<30 km³) basaltic eruptions in continental intraplate monogenetic volcanic fields. Eruptive volume, therefore, is not an a priori barrier to producing long lava flows. Key factors that promote long lava flows include efficient lava transport systems that minimise heat loss, long-lived and sustained effusion rates to maintain flow advancement, and lava flow across low topographic gradients (<1°-10°) with minimal topographic barriers.

Here, we focus on an anomalously young and poorly studied basaltic monogenetic volcanic field in southeast Queensland, Australia, that formed part of the broader intraplate volcanism in eastern Australia since the Late Cretaceous. The Coalstoun Lakes Volcanic Field (CLVF) comprises three lava fields: the Barambah Basalt Flow Field, the Deep Creek Flow Field and the Hunters Hill Flow Field. Basalt from the Barambah Basalt Flow Field has been redated here by Ar⁴⁰/Ar³⁹ analysis of groundmass material, yielding a weighted mean age of 0.520 ± 0.016 Ma. The Barambah Basalt Flow Field contains most of the eruptive volume and has advanced up to 165 km from the vent. The Hunters Hill and the Deep Creek flow fields are comparatively smaller in volume and have advanced ∼30 and ∼ 20 km from the vent, respectively. Lava tubes are only known from proximal regions and do not appear to be a significant factor in promoting long run-out in the CLVF. Flow confinement and utilisation of existing drainage networks are features of both lava flow fields, and advancement down the sand-based and ephemeral Burnett River significantly promoted long run-out despite low topographic gradients.

New whole-rock geochemical data on our CLVF samples indicates that all lavas are hawaiites, a common feature of other Quaternary long lava flows globally. Overall, there is some compositional variation, but a cryptic zonation is readily apparent in trace element abundances, which helps to further distinguish the flow fields as the products of separate but closely spaced eruptions. The combination of field and geochemical data indicates that the long lava flow of the Barambah Basalt Flow Field resulted from a sustained and relatively low effusion eruption, creating a pāhoehoe flow field that continuously advanced across the landscape, utilising a drainage system that guided lava flow and helped to circumvent any topographic barriers.

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洞察小体积长熔岩流的发展：澳大利亚昆士兰东南部 Coalstoun Lakes 火山带案例研究

长度超过50千米的长熔岩流通常产生于大体积洪水玄武岩喷发（100至10,000立方千米），但也可能产生于大陆板内单生火山带的小到中等体积（30立方千米）玄武岩喷发。因此，喷发量并不是产生长熔岩流的先验障碍。促进长熔岩流的关键因素包括：可最大限度减少热量损失的高效熔岩输送系统；可维持熔岩流前进速度的长效持续喷出率；以及熔岩流穿过地形坡度较低（1°-10°）且地形障碍最小的熔岩流。在此，我们重点研究澳大利亚昆士兰州东南部一个异常年轻且研究较少的玄武岩单源火山区，该火山区是晚白垩世以来澳大利亚东部更广泛的板内火山活动的一部分。Coalstoun 湖火山区（CLVF）由三个熔岩区组成：Barambah 玄武岩流区、Deep Creek 流区和 Hunters Hill 流区。这里对来自巴兰巴玄武岩流场的玄武岩进行了 Ar40/Ar39 分析，得出加权平均年龄为 0.520 ± 0.016 Ma。巴兰巴玄武岩流场包含了大部分的喷发量，并从喷口向前推进了 165 公里。猎人山和深溪流场的体积相对较小，距离喷发口的距离分别为 30 千米和 20 千米。熔岩管仅见于近端区域，似乎不是促进 CLVF 长距离流出的重要因素。尽管地形坡度较低，但熔岩流场的流动限制和对现有排水网络的利用是这两个熔岩流场的特点，而顺着沙基和短暂的伯内特河前进则极大地促进了长距离流出。总体而言，存在一些成分上的差异，但从微量元素丰度上很容易看出隐性分带，这有助于进一步区分这些流场是独立但间隔很近的喷发产物。实地数据和地球化学数据的结合表明，巴兰巴玄武岩流场的长熔岩流是由持续的、相对较低的喷发造成的，形成了一个在地形上不断推进的pāhoehoe流场，利用排水系统引导熔岩流并帮助绕过任何地形障碍。

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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.