R. Vestergaard, Gro Birkefeldt Møller Pedersen, C. Tegner
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引用次数: 1
摘要
利用新的遥感数据、历史报告、岩石学和基于地球化学数据的黏度估算,阐明了1845-46年和1766-68年大喷发期间Hekla峰顶脊的熔岩侵位流线和喷口结构的变化。根据平面测量法,我们估计这些喷发的体积分别接近0.4公里和0.7公里。然而,与1947年至1948年的喷发记录相比,平面测量法似乎低估了40-60%的熔岩体积。因此,真正的体积更可能分别为0.5-0.6公里和1.0-1.2公里。估计1766-68年喷发的熔体粘度平均值为2.5×10 Pa s(喷发前)和2.5×10 Pa s(脱气),1845-46年喷发的熔体粘度平均值为2.2×10 Pa s(喷发前)和1.9×10 Pa s(脱气)。喷发前的岩浆比脱气岩浆的流动性要高一个数量级。在1845-46年和1947-48年的喷发中,SiO2从58-57 wt%下降到55-54 wt%,这与Hekla火山喷发的传统模型一致,即Hekla火山是从一个巨大的层状岩浆房喷发出来的,顶部是最进化的(富含硅的)岩浆。相比之下,1766 - 1768年的熔岩流显示出更为复杂的SiO2趋势。1766年位于其南部的熔岩场SiO2值为54.9 ~ 56.5%,而1767年3月在Hekla脊NE端较年轻喷口喷发的Hringlandahraun熔岩流SiO2值更高,为57.8%。这表明层状岩浆房模型并不适用于Hekla火山喷发期间形成的所有熔岩流。
The 1845–46 and 1766–68 eruptions at Hekla volcano: new lava volume estimates, historical accounts and emplacement dynamics
We use new remote sensing data, historical reports, petrology and estimates of viscosity based on geochemical data to illuminate the lava emplacement flow-lines and vent structure changes of the summit ridge of Hekla during the large eruptions of 1845–46 and 1766–68. Based on the planimetric method we estimate the bulk volumes of these eruptions close to 0.4 km and 0.7 km, respectively. However, comparison with volume estimates from the well-recorded 1947–48 eruption, indicates that the planimetric method appears to underestimate the lava bulk volumes by 40–60%. Hence, the true bulk volumes are more likely 0.5–0.6 km and 1.0–1.2 km, respectively. Estimated melt viscosity averages for the 1766–68 eruption amount to 2.5 × 10 Pa s (pre-eruptive) and 2.5×10 Pa s (degassed), and for the 1845–46 eruption 2.2×10 Pa s (pre-eruptive) and 1.9×10 Pa s (degassed). Pre-eruptive magmas are about one order of magnitude more fluid than degassed magmas. In the 1845–46 and 1947–48 eruptions, SiO2 decreased from 58–57 to 55–54 wt% agreeing with a conventional model that Hekla erupts from a large, layered magma chamber with the most evolved (silicarich) magmas at the top. In contrast, the lava-flows from 1766–68 reveal a more complicated SiO2 trend. The lava fields emplaced in 1766 to the south have SiO2 values 54.9–56.5%, while the Hringlandahraun lava-flow that erupted from younger vents on the NE end of the Hekla ridge in March 1767 has higher SiO2 of 57.8%. This shows that the layered magma chamber model is not suitable for all lava-flows emplaced during Hekla eruptions.
期刊介绍:
Jökull publishes research papers, notes and review articles concerning all aspects of the Earth Sciences. The
journal is primarily aimed at being an international forum
for geoscience research in Iceland. Specific areas of coverage include glaciology, glacial geology, physical geography,
general geology, petrology, volcanology, geothermal research, geophysics, meteorology, hydrology and oceanography. Jökull also publishes research notes and reports from
glacier expeditions, book reviews, and material of interest to
the members of the Icelandic Glaciological and Geological
Societies