High Variability of Surface Free Energy and Zeta Potential of Volcanic Particles: Implications for Deposit Stability

A. Ontiveros, Ivan Plaza, J. Calero, A. Moleon, J. Ibáñez
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Abstract

Landslides on the flanks of stratovolcanoes can significantly modify the structure of the volcano. Macroscopic factors that determine the stability of volcanic deposits are well understood, but the microscopic interactions between particles and their impact on deposit cohesion remain poorly understood. Deposit cohesion is related to the energy of interaction between particles, and its calculation depends on the surficial properties of the eruptive materials. The purpose of this study was to perform a preliminary comparative analysis of the surficial properties of volcanic materials from various tectonic settings, including electrical (zeta potential) and thermodynamic (surface free energy) components and to calculate the total interaction energy between particles under different environmental conditions. We analyzed eruptive materials from six active volcanoes (El Hierro, Pico Do Fogo, Vulcano, Stromboli, Mt. Etna, and Deception Island). The results show that deposit cohesion varies among volcanoes, and changes drastically with the pH of the medium. Among the volcanic systems investigated, El Hierro (pH = 3) has the most cohesive materials, while Mt. Etna (pH = 8) has the least cohesive materials. Our results suggest that microscopic electrical and thermodynamic properties play a role in the stability of volcanic deposits, and confirm the need for a greater research focus in this area.
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火山颗粒表面自由能和Zeta电位的高变异性:对矿床稳定性的影响
层状火山两侧的滑坡可以显著地改变火山的结构。决定火山沉积物稳定性的宏观因素已经被很好地理解,但微观颗粒之间的相互作用及其对沉积物粘聚性的影响仍然知之甚少。沉积内聚力与粒子间相互作用的能量有关,其计算取决于喷发物质的表面性质。本研究的目的是对不同构造环境下火山物质的表面特性进行初步比较分析,包括电学(zeta电位)和热力学(表面自由能)分量,并计算不同环境条件下粒子之间的总相互作用能。我们分析了6座活火山的喷发物质(El耶罗火山、Pico Do Fogo火山、Vulcano火山、Stromboli火山、埃特纳火山和欺骗岛)。结果表明,不同火山的沉积物黏结性不同,并随介质pH值的变化而剧烈变化。在所研究的火山系统中,El耶罗火山(pH = 3)的粘性物质最多,而Mt. Etna火山(pH = 8)的粘性物质最少。我们的研究结果表明,微观电学和热力学性质在火山沉积物的稳定性中起着重要作用,并证实了这一领域需要更多的研究重点。
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