Observations from the island of Montserrat in the Caribbean have shown that volcanic eruptions (particularly explosive ones) can generate internal waves in the atmosphere that can be observed by microbarographs at ground level. It is possible that observations of such waves may give early information about volcanic eruptions when other methods are unavailable (because of bad weather, nocturnal eruptions, and poor visibility or remoteness), if it is possible to interpret them. This paper describes a dynamical model of the forcing of internal waves in which the eruption is modelled as a turbulent plume, forced by a source of buoyancy at ground level that specifies the total height and relevant properties of the eruption. Specifically, the rising plume entrains environmental air from ground level to 70% of its maximum height z M , and above 0.7 z M the rising fluid spreads radially. During the eruption, this flow forces horizontal motion in the surrounding fluid that generates internal waves, which may be computed by assuming that this is due to a linear dynamical process. Properties of the resulting waves are described for a variety of parameters that include the strength and height of the eruption, the effect of the tropopause, generation in the stratosphere for large eruptions, and the differing effects of the duration of the eruption. Implications for characterising eruptions from observations of these properties are discussed.
展开▼
机译:从加勒比海蒙特塞拉特岛进行的观察表明,火山喷发(特别是爆炸性喷发)可在大气中产生内部波,可通过地面微气压计观察到。如果可以解释这些波,有可能在其他方法不可用时(由于恶劣的天气,夜间爆发,能见度或偏远性较差),对此类波的观测可以提供有关火山喷发的早期信息。本文描述了一种内部波强迫的动力学模型,其中,喷发被模拟为湍流羽流,由地面上的浮力源强迫,该浮力源指定了喷发的总高度和相关属性。具体而言,上升的羽流将环境空气从地面夹带到其最大高度z M的70%,并且在0.7 z M以上时,上升的流体径向扩散。在喷发过程中,该流动迫使周围流体中的水平运动产生内部波,可以通过假设这是由于线性动力学过程而进行计算。针对各种参数描述了生成波的属性,这些参数包括喷发的强度和高度,对流层顶的影响,平流层中大喷发的产生以及喷发持续时间的不同影响。讨论了通过观测这些特性来表征喷发的含义。
展开▼
