岩鉱 86 巻, 6 号

九重火山群,東部及び中部域の形成史

Geological field work of Kuju volcano group in central Kyushu has been carried out to construct the evolutional history of the volcano group. Especially, at the eastern and the central area, the evolutional history after a large pyroclastic eruption, which occurred 30, 000-35, 000 y. B. P. to generate pyroclastic flows, has been clarified using a tephrochronological method.
Eleven tephra layers are recognized around Kuju volcano group. These layers are in descend-ing order ; Komekubo crater scoria-fall, Kuju-1 ash-fall, Danbaru scoria-fall, Kuju-1 weathered ash, Kuju-2 ash-fall, Kikai-Akahoya ash-fall, Kuju-2 weathered ash, Kuju-3 weathered ash, Kuju-1 pumica-fall, Kuju-4 weathered ash, Miyakono scoria-fall. Kikai-Akahoya ash-fall were erupted from Kikai caldera, which is situated at the southern Kyushu, about 6, 000-6, 500 y. B. P. The other tephras may have originated from Kuju volcano group. Kuju-1 pumice-fall was accompanied with the 30, 000-35, 000 y. B. P. pyroclastic eruption. Danbaru scoria-fall was erupted 3, 000-5, 000 y. B. P.
The evolutional history of the central area is as follows: At 30, 000-35, 000 y. B. P., a large quantity of pyroclastic materials erupted from a presumed eruption center, which situated between the Kutsukakeyama dacitic mountain and Yuzawa andesitic tablelands. After this eruption, the greater part of the central area had been formed by extrusions of lavas and pyroclastic rocks before Kikai-Akahoya ash-fall deposition (6, 000-6, 500 y. B. P.). From 6, 000-6, 500 y. B. P. to 3, 000-5, 000 y. B. P., Mimatayama dome lava erupted. The activity of the central lava domes (e. g. Kujusan lava dome) occurred after 3, 000-5, 000 y. B. P. This activity was accompanied by Kuju-1 ash-fall. After this activity, phreatic explosion and fumarolic activity occurred, and fumarolic activity continued until now.
The evolutional history of the eastern area is as follows: The activity of eastern area began after 30, 000-35, 000 y. B. P. Before Kikai-Akahoya ash-fall deposition, andesitic lavas effused north of Hiijidake. After this period, all of Hiijidake mountain and the lower part of Taisensan mountain were formed by a large quantity of lavas and a small amount of pyroclastic falls. Kuju-2 ash-fall was deposited simultaneously. About 3, 000-5, 000 y. B. P., Strombolian eruption occurred at Taisen-san, forming Danbaru and Komekubo scoria cones accompanied by the deposition of Danbaru scoria-fall. After this activity, dacitic lava erupted at the southern edge of Komekubo crater, then Komekubo crater scoria-fall erupted from the crater. Finally, Kuroda-ke dome lave erupted at the eastern end of Kuju volcano group.
The volcanic output rates are calculated for three periods; 32, 000-6.300 y. B. P., 6, 300-4, 000 y. B. P. and after 4, 000 y. B. P. At the central area, the rate for 6, 300-4, 000 y. B. P. is the largest (0.256km3/k. y.). At the eastern area, the rate became greater from 0.017km3/k. y. through 0.452km3/k. y. to 0.635 km3/k. y.

音調津斑れい岩体中のグラファイトの成因

Graphite associated with nickeliferous pyrrhotites occurs in the Oshirabetsu gabbroic body in southeast part of the Hidaka Belt, Hokkaido. Brecciated and spherulitic aggregates of graphite are mainly found in norite and diorite.
Stable carbon isotope ratio and degree of graphitization of the graphite and carbonaceous material in the Nakanogawa Group around the gabbroid were determined.
Crystallite thickness (L_c, (002)) of the graphite is more than 1000 Â and lattice strain along c-axis (ε_c) is very small, which means that the graphite is a perfect graphite crystal.
Carbon isotopic composition of the graphite ranges from -23.34 to -23.88‰ (δ¹³C_PDB) and that of carbonaceous material in the Nakanogawa Group is about -25.7‰.
The dδ₁₃C values of the graphite range within isotopic composition of carbon in coal and petroleum. The slight difference of δ₁₃C value between the graphite and the carbonaceous material was due to the fractionation of ₁₃C between the graphite and hydrothermal fluid.
These results suggest that the graphite in the Oshirabetsu gabbroic body is of sedimentary origin and carbonaceous sedimentary rocks were incorporated in ascending gabbroic magma.

東京都白丸鉱山産エディントン沸石

東京都白丸鉱山の層状マンガン鉱床産のブラウン鉱を含む低品位マンガン鉱石を切る脈中に本邦初産のエディントン佛石を確認した。本鉱はブラウン鉱の集合を含む曹長石・重土長石・キュムリ石・赤鉄鉱の細粒集合を切る細脈中に重土長石(脈壁側)と共存する。X線粉末回折値は斜方晶系のものに一致した。また水分を除いた化学分析ではほぼ理想成通りの結果を得た。なお今回の産状はこの鉱物については新しいものである。また同一元素を主要成分とする長石と沸石の共存例ともなったが,長石・沸石を構成する元素中ナトリウム・カリウム・カルシウムについては,曹長石一方沸石などのように例はかなり限定される。
本鉱床では主にバリウム珪酸塩鉱者によって特徴づけられる異常に高いバリウムの濃集がある。エディントン拂石もその一つとして恐らく熱水溶液起源の生成になり,珪酸分の比較的乏しい生成環境を反映しているものと判断される。

立山火山のK-Ar年代

K-Ar age determination based on the Peak Height Comparison Method has been made on four lavas from Tateyama Volcano, which is located in the northern margin of the Norikura Volcanic Chain in Central Japan. Two lavas that erupted in the First and Third Stages gave significant K-Ar ages as 133 ± 22 and 47 ± 9 ka, respectively. K-Ar age of the First Stage Lava in Tateyama Volcano, incorporated with some ages already reported on Norikura and Yakedake Volcanoes also belonging to the Norikura Volcanic Chain, clarified that the activity of this Volcanic Chain commenced in the order of Norikura, Tateyama and Yakedake Volcanoes. K-Ar age of the Third Stage Lava is consistent with that of the Daisen-Kurayoshi Pumice (DKP: ca. 48 ka) covering the Third Stage Lava.