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A. S. Furumoto 《Bulletin of Volcanology》1978,41(4):435-453
From a combination of results of gravity, magnetic and seismic refraction surveys, the dike complex under the east rift zone of Kilauea Volcano in Hawaii was found to extend for 110 km from the summit area of the volcano to a point 60 km at sea beyond the eastern tip of the island. Near the summit the complex is 20 km wide, and at about 40 km distance from the summit, the complex narrows to 12 km wide. The main body of the dike complex is 2.3 km deep, but some parts are as shallow as 1 km. From extrapolation of temperature data of a deep well and from analysis of magnetic data, it was inferred that temperature of the dike complex is above the Curic point of 540°C. The internal part of the complex can approach the melting point of 1060°C. The dike complex was formed by numerous excursions of magma from the holding reservoir under the volcano summit. The theory of forceful intrusion of magma into rift zones accounts for the magma excursions and migration of the passageways. Gravity and seismic velocity data indicate that density of the material left in the dike complex is 3.1 g/cm3. In the light of recent density determinations of Hawaiian rocks under high pressure and temperature, it is concluded that during Hawaiian volcanic activity, less dense components of the parent magma crupt through surface vents while the more dense components remain trapped below. Samples of the dense material from the dike complex are required before we can have a complete picture of the parent magma of Hawaiian volcanoes. The dike complex is the source of thermal energy for a commercial quality geothermal reservoir that was found by drilling. 相似文献
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The crustal structure of the Hawaiian Archipelago, northern Melanesia, and parts of the Central Pacific Basin have been studied by seismic refraction methods. The systematic variation found in crustal thickness in the Hawaiian Islands is explainable by a hypothesis of differential subsidence. The crustal structure of northern Melanesia points to tensional forces in an east-west direction and compressional forces in a north-south direction. In the Central Pacific Basin, a 7.4 km/sec layer in the lower crust seems to be present over a wide area. 相似文献
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Augustine S. Furumoto Robert L. Kovach 《Physics of the Earth and Planetary Interiors》1979,18(3):197-208
By use of teleseismic and local data, the P-wave source mechanism of the Kalapana, Hawaii, earthquake of November 29, 1975 was found to have a common strike of N64°E for the two nodal planes. One plane dipped 4° to the NW; the other dipped 86° to the SE. After consulting subsurface geological data obtained by the recent Hawaii geothermal exploration program, it was decided that the plane dipping to the NW at 4° was the preferred solution.Seismic moment obtained from body-wave data and surface-wave data averaged 1.2 · 1027 dyn cm. Fault area from P-wave, surface wave and tsunami data amounted to about 2200 km2. Stress drop was on the order of tens of bars.The earthquake appears to be of volcanic origin. When magma pressure in the dike complex of the east rift of Kilauea exceeded the fracture point, the southern flank of the east rift was pushed across the ancient sea floor upon which the volcanic edifice rests. The result was a low-angle overthrust, which also produced a tsunami. The hypothesis of forceful intrusion of magma into the east rift is consistent with the mechanism of the earthquake.The low stress drop (in relation to other intra-plate earthquakes) is probably due to the occurrence of the earthquake in a hot-rock regime. 相似文献
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A. S. Furumoto 《Bulletin of Volcanology》1966,29(1):733-733
Numerous seismic refraction traverses were carried out over the Hawaiian Islands to outline the structure of the volcanoes and determine the thickness of the layers of the crust. Results indicate that there is a progressive thickening of the crust in the area from younger to older volcanic islands. High velocity mantle-like material was detected under rift zones and in volcanic plugs. Volcanic regions were found to be intersected by flexure zones in the crust and in the mantle. The seismic refraction method, in conjunction with gravity and magnetic methods, was found to be successful in outlining the horizontal and vertical structures of rift zones and plugs of volcanoes. 相似文献
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Summary . The great Etorofu earthquake of 1958 November 6 is characterized by a relatively small aftershock area (70 × 150 km2 ) and an extremely large felt area. The felt area is more extensive than those of any other large earthquakes which have occurred in the southern Kurile to northern Japan arc since the beginning of this century. The mechanism is a pure thrust fault typical of most great earthquakes in island arcs. A body wave magnitude of m b = 8.2 is obtained at periods around 6 s using more than 40 observations, although an m b value of only 7.6–7.7 would be expected empirically from the observed surface wave magnitude of M s = 8.1–8.2. Both an unusually large felt area and a high m b indicate a dominance of high-frequency components in the seismic waves. A seismic moment of M o = 4.4 × 1028 dyne cm is determined from long-period surface waves from which a high stress drop of Δσ = 78 bar is obtained using a relatively small aftershock area. Historic data indicate an anomalously long time interval between the 1958 event and any earlier great earthquake from the same source region. The observed high stress drop can be interpreted as a consequence of this long intervening period through which strain built up. The dominance of the high-frequency seismic waves can then be interpreted as a result of this high stress drop. Stress drops, seismic wave spectra and recurrence intervals of great earthquakes are in this way closely related to each other. The 1958 event may represent a high strength extreme of stochastic fluctuation of fracture strength relevant to great earthquakes. 相似文献
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S. Nagumo T. Ouchi J. Kasahara S. Koresawa Y. Tomoda K. Kobayashi A.S. Furumoto M.E. Odegard G.H. Sutton 《Earth and Planetary Science Letters》1981,53(1):93-102
Ocean bottom seismograph (OBS) long-range explosion experiments were carried out in the Mariana Basin in 1973 and 1976. Seven large shots (8.5–1.5 ton) as well as several tens of small shots were fired. The maximum range of observation was about 1900 km. As many as 25 OBS stations were deployed in an array of about 800 km. It is found that the sub-Moho P-wave velocity structure is of stratified nature, being composed of alternating high- and low-velocity layers. High-velocity layers with apparent velocities of 8.1, 8.2, 8.4, 8.6 and 8.7 km/s are identified. Low-velocity layers, sandwiched between the high-velocity layers of 8.4, 8.6 and 8.7 km/s, are very prominent. The sub-Moho high-velocity lid with an apparent velocity of 8.4 km/s is very thin. Thinning of this lid, thickening of the low-velocity layer, and the presence under it of another high-velocity layer (8.6 km/s) appear to characterize the uppermost mantle structure beneath the Mariana Basin. 相似文献