BULLETIN OF THE VOLCANOLOGICAL SOCIETY OF JAPAN
Online ISSN : 2189-7182
Print ISSN : 0453-4360
ISSN-L : 0453-4360
Volume 47, Issue 6
Displaying 1-5 of 5 articles from this issue
  • Tabito MATSU'URA, Emi NITTA, Satoshi KANISAWA, Kazuo NAKASHIMA
    Article type: Article
    2003 Volume 47 Issue 6 Pages 711-725
    Published: January 08, 2003
    Released on J-STAGE: March 20, 2017
    JOURNAL FREE ACCESS
    Kitahara tephra (Kth) and Dokusawa tephra (Dks) are Late Pleistocene tephra layers containing biotite and cummingtonite characteristically. Kth is distributed on the eastern side of the Ou Ranges and Dks is on the western sides of the Ranges in the central part of Northeast Japan. Vertical variations of modal amounts, refractive indices and major element chemistry of minerals and mineral assemblages were examined on Dks and Kth. Cummingtonite shows nearly constant variation in the refractive indices and Mg-values [Mg/(Mg +Mn+ Fe)]. On the contrary, the refraetive indices and Mg-values of orthopyroxene and hornblende have wide variations. Dks and Kth correlate with each other because the refractive indices and chemical composition of cummingtonite are quite similar. "Atago tephra" containing a lot of high-quartz can be correlated with the lower unit of Kth because high-quartz is included in both tephras. Dks comprises cummingtonite, biotite, high-quartz and epidote as a whole layer. The upper part of Dks also includes orthopyroxene, clinopyroxene and hornblende. The mineral composition of Kth resembles the upper part of Dks and does not show vertical variation. These facts indicate that the upper part of Dks is distributed on both sides of the Ou Ranges.
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  • Akio YOSHIDA, Kohji HOSONO
    Article type: Article
    2003 Volume 47 Issue 6 Pages 727-738
    Published: January 08, 2003
    Released on J-STAGE: March 20, 2017
    JOURNAL FREE ACCESS
    We investigated how the intermediate-depth seismicity changes with depth in the Pacific slab beneath Hokhaido and the Kanto district using JMA data since Oct. 1997. We found that seismicity in the upper seismic plane decreases noticeably at about the depth of 100 km and on its deeper side both in Hokkaido and the Kanto district. In Hokkaido the volcanic front is located nearly above the line where the seismicity in the upper seismic plane starts to decrease (the D line). This feature is the same as that seen in the Tohoku district (Hosono and Yoshida, 200la). In the Kanto region, however, the D line is located several tens km to the east of the volcanic front, the cause of which may be attributed to the subduction of the Philippine Sea plate above the Pacific plate. We think the noticeable decrease of seismicity in the upper seismic plane at about the depth of 100 km which is commonly observed in the Pacific slab beneath Japan and the correspondence between the location of the D Iine and the volcanic front in Hokkaido and the Tohoku district indicate that the decrease of seismicity in the upper seismic plane may be related to the genetic process of magmatic bodies in the subduction zone.
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  • Hideyuki TATEYAMA, Hideo HOSHIZUMI, Kazunori WATANABE
    Article type: Article
    2003 Volume 47 Issue 6 Pages 739-749
    Published: January 08, 2003
    Released on J-STAGE: March 20, 2017
    JOURNAL FREE ACCESS
    Nodake volcano is a small edifice, located at the south of the central part of Unzen Volcano, Kyushu, Japan. It is composed mainly of thick lavas and pyroclastics, and is divided into five geologic units in ascending order, i.e., Fukhoshi lava, Yugawachi pyroclastic flow deposits, Tawaraishi debris avalanche deposit, Nodake lava and Nodake pyroclastic flow deposit. The Fukkoshi lava, which has two lithofaces of dark gray and light gray in color, erupted about 100 to 110 ka. The Yugawachi pyroclastic flow deposits are divided into four units intercalated with weathered volcanic ash beds, and spread over the central and the southern flanks of Nodake volcano. The Tawaraishi debris avalanche deposit contains light gray dacitic block derived from Fukkoshi lava. The Nodake lava forms an andesitic lava dome on the summit area of Nodake volcano. The Nodake pyroclastic flow deposits are block and ash flows generated at about 74 ka upon collapses of Nodake lava dome.
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  • Katsuhiko FURUYAMA, Masahiro DAISHI, Keisuke NAGAO, Mugihiko EGUCHI
    Article type: Letter
    2003 Volume 47 Issue 6 Pages 751-755
    Published: January 08, 2003
    Released on J-STAGE: March 20, 2017
    JOURNAL FREE ACCESS
  • Isoji MIYAGI, Akihiko TOMIYA
    Article type: Letter
    2003 Volume 47 Issue 6 Pages 757-761
    Published: January 08, 2003
    Released on J-STAGE: March 20, 2017
    JOURNAL FREE ACCESS
    We developed a new thermometer that uses color of volcanic ashes. A series of heating experiments for basaltic ashes under the atmospheric condition provided a quantitative relationship among color, heating temperature, and heating duration. The higher the heating temperature, the more the redness in color of heated ash. We applied the relationship to estimate heated temperature of the ash that was underlying below or contact with a cauliflower-shaped volcanic bomb ejected from the Miyakejima volcano on 18 August, 2000. The estimated temperature was about 390℃ for the ash underlying 1 cm below the volcanic bomb, and 550℃ for the ash in contact with the bomb. Numerical heat transfer calculations for the volcanic bomb on the ash layer suggested that temperature of its center at the time of landing is about 1,000℃. This is the first concrete evidence that the bomb was essential material and that the 18 August eruption was phreatomagmatic.
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