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Takeshi Nishimura Masato Iguchi Ryohei Kawaguchi Surono Muhamad Hendrasto Umar Rosadi 《Bulletin of Volcanology》2012,74(4):903-911
We examine the basic characteristics of inflations at Semeru Volcano, Indonesia, to clarify the pressurization process prior
to two different styles of explosive eruptions: Vulcanian eruptions and gas bursts. Analysis of data obtained from tilt meters
installed close to the active crater allows clarification of the common features and the differences between the two styles
of eruptions. To improve the signal-to-noise ratio and to determine the mean characteristics of the inflations, we stack tilt
signals obtained from eruptions of different magnitudes and evaluate the maximum amplitude of the seismic signal associated
with these eruptions. Vulcanian eruptions, which explosively release large amounts of ash, are preceded by accelerating inflation
about 200–300 s before the eruption, which suggests volume expansion of the gas phase. In contrast, gas bursts, which rapidly
effuse water steam accompanied by explosive sounds, follow non-accelerating changes of inflation starting 20 s before each
emission. Tilt amplitudes increase with the magnitude of eruptions for both eruption styles. This suggests that the volume
and/or pressure of magma or gas stored in the conduit before eruptions controls the magnitude of volcanic eruptions. These
results further suggest that the magnitude of eruptions can be predicted from geodetic measurements of volcano inflation. 相似文献
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Céline Dumaisnil Jean‐Claude Thouret Guillaume Chambon Emma E. Doyle Shane J. Cronin Surono 《地球表面变化过程与地形》2010,35(13):1573-1590
Lahars (volcanic debris flows) have been responsible for 40% of all volcanic fatalities over the past century. Mount Semeru (East Java, Indonesia) is a persistently active composite volcano that threatens approximately one million people with its lahars and pyroclastic flows. Despite their regularity, the behaviour and the propagation of these rain‐triggered lahars are poorly understood. In situ samples were taken from lahars in motion at two sites in the Curah Lengkong River, on the southeast flank of Semeru, providing estimates of the particle concentration, grain size spectrum, grain density and composition. This enables us to identify flow sediment from three categories of lahars: (a) hyperconcentrated flow, (b) non‐cohesive, clast‐ and matrix‐supported debris flow, and (c) muddy flood. To understand hyperconcentrated flow sediment transport processes, it is more appropriate to sample the active flows than the post‐event lahar deposits because in situ sampling retains the full spectrum of the grain‐size distribution. Rheometrical tests on materials sampled from moving hyperconcentrated flows were carried out using a laboratory vane rheometer. Despite technical difficulties, results obtained on the <63, <180, and <400 µm fractions of the sampled sediment, suggest a purely frictional behaviour. Importantly, and contrary to previous experiments conducted with monodisperse suspensions, our results do not show any transition towards a viscous behaviour for high shear rates. These data provide important constraints for future physical and numerical modelling of lahar flows. Copyright © 2010 John Wiley & Sons, Ltd. 相似文献
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Jean-Claude Thouret Franck Lavigne Hiroshi Suwa Bambang Sukatja Surono 《Bulletin of Volcanology》2007,70(2):221-244
Mt. Semeru, the highest mountain in Java (3,676 m), is one of the few persistently active composite volcanoes on Earth, with
a plain supporting about 1 million people. We present the geology of the edifice, review its historical eruptive activity,
and assess hazards posed by the current activity, highlighting the lahar threat. The composite andesite cone of Semeru results
from the growth of two edifices: the Mahameru ‘old’ Semeru and the Seloko ‘young’ Semeru. On the SE flank of the summit cone,
a N130-trending scar, branched on the active Jonggring-Seloko vent, is the current pathway for rockslides and pyroclastic
flows produced by dome growth. The eruptive activity, recorded since 1818, shows three styles: (1) The persistent vulcanian
and phreatomagmatic regime consists of short-lived eruption columns several times a day; (2) increase in activity every 5
to 7 years produces several kilometer-high eruption columns, ballistic bombs and thick tephra fall around the vent, and ash
fall 40 km downwind. Dome extrusion in the vent and subsequent collapses produce block-and-ash flows that travel toward the
SE as far as 11 km from the summit; and (3) flank lava flows erupted on the lower SE and E flanks in 1895 and in 1941–1942.
Pyroclastic flows recur every 5 years on average while large-scale lahars exceeding 5 million m3 each have occurred at least five times since 1884. Lumajang, a city home to 85,000 people located 35 km E of the summit,
was devastated by lahars in 1909. In 2000, the catchment of the Curah Lengkong River on the ESE flank shows an annual sediment
yield of 2.7 × 105 m3 km−2 and a denudation rate of 4 105 t km−2 yr−1, comparable with values reported at other active composite cones in wet environment. Unlike catchments affected by high magnitude
eruptions, sediment yield at Mt. Semeru, however, does not decline drastically within the first post-eruption years. This
is due to the daily supply of pyroclastic debris shed over the summit cone, which is remobilised by runoff during the rainy
season. Three hazard-prone areas are delineated at Mt. Semeru: (1) a triangle-shaped area open toward the SE has been frequently
swept by dome-collapse avalanches and pyroclastic flows; (2) the S and SE valleys convey tens of rain-triggered lahars each
year within a distance of 20 km toward the ring plain; (3) valleys 25 km S, SE, and the ring plain 35 km E toward Lumajang
can be affected by debris avalanches and debris flows if the steep-sided summit cone fails. 相似文献
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Structure and CO<Subscript>2</Subscript> budget of Merapi volcano during inter-eruptive periods 总被引:1,自引:0,他引:1
Jean-Paul Toutain Jean-Claude Baubron Patrick Richon Surono Sri Sumarti Anthony Nonell 《Bulletin of Volcanology》2009,71(7):815-826
Soil temperature and gas (CO2 concentration and flux) have been investigated at Merapi volcano (Indonesia) during two inter-eruptive periods (2002 and
2007). Precise imaging of the summit crater and the spatial pattern of diffuse degassing along a gas traverse on the southern
slope are interpreted in terms of summit structure and major caldera organization. The summit area is characterized by decreasing
CO2 concentrations with distance from the 1932 crater rim, down to atmospheric levels at the base of the terminal cone. Similar
patterns are measured on any transect down the slopes of the cone. The spatial distribution of soil gas anomalies suggests
that soil degassing is controlled by structures identified as concentric historical caldera rims (1932, 1872, and 1768), which
have undergone severe hydrothermal self-sealing processes that dramatically lower the permeability and porosity of soils.
Temperature and CO2 flux measurements in soils near the dome display heterogeneous distributions which are consistent with a fracture network
identified by previous geophysical studies. These data support the idea that the summit is made of isolated and mobile blocks,
whose boundaries are either sealed by depositional processes or used as pathways for significant soil degassing. Within this
context, self-sealing both prevents long-distance soil degassing and controls heat and volatile transfers near the dome. A
rough estimate of the CO2 output through soils near the dome is 200–230 t day−1, i.e. 50% of the estimated total gas output from the volcano summit during these quiescent periods. On Merapi’s southern
slope, a 2,500 m long CO2 traverse shows low-amplitude anomalies that fit well with a recently observed electromagnetic anomaly, consistent with a
faulted structure related to an ancient avalanche caldera rim. Sub-surface soil permeability is the key parameter that controls
the transfer of heat and volatiles within the volcano, allowing its major tectonic architecture to be revealed by soil gas
and soil temperature surveys. 相似文献
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J. Vandemeulebrouck J. -C. Sabroux M. Halbwachs Surono N. Poussielgue J. Grangeon J. Tabbagh 《Journal of Volcanology and Geothermal Research》2000,97(1-4)
The results of a hydroacoustic monitoring experiment in the Kelut Crater lake, Indonesia, prior to its 1990 eruption, are presented, with the benefit of hindsight. Indeed, the underwater noise levels in three widely separated frequency bands, together with the lake water temperature, was radio-transmitted and almost continuously recorded from a period of quiescence of the volcano till the onset of its 10 February 1990, eruption, which destroyed the monitoring buoy. The comparative analysis of the noise variations in the three bands, together with seismic and temperature data, have shed light on the mechanisms underlying the pre-eruptive activity. The three acoustic levels had shown conspicuous, yet distinctive, changes prior to the eruption. Acoustic level in the low-frequency (1–50 Hz) band, which increased one year before the resumption of seismic activity and the lake warming up, is interpreted as the result of boiling at depth. The source of high-acoustic level in the audiometric (500–5000 Hz) range is clearly the bubbling of volcanic gases, occurring as a strong convective column in the middle of the lake. From the variations of this audiometric level, we have estimated that the degassing rate in the lake increased by a hundred-fold during the pre-eruptive period. Variations of ultrasonic (20–100 kHz) frequency acoustic level seem to be related with pressure and thermal changes within the hydrothermal system and its rock matrix beneath the lake. In conclusion, this experiment demonstrates the potential of hydroacoustic monitoring as an early warning system at crater lake volcanoes. 相似文献
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