地球科学 1964 巻, 75 号

東天北地域の表層地質と成因的土壌型

The authors tried to elucidate the genetical porblems of the upland soils in the eastern Tempoku region from the viewpoint of the historical geology of the Quaternary Period. The geomorphology of this region consists of low mountainous and hilly lands, coastal terraces, sand-dunes and alluvial plains. Terraces are divided into as follows : Osachinai Plane (erosional flat plane, 90-120 m above the sea-level), Kamisarufutsu Plane (50-80 m), Pon'nitachinai Plane (40-60 m) and Asajino Plane (15-30 m). The latter three planes are depositional ones. These terraces are mainly composed of the Quaternary system, the stratigraphy of which is illustrated and summarized in Fig.1 and Table 1. The upland soils of this region are classified and systematized as shown in Table 2, based on the descending genetical system of the soil classification. The most important genetic soil types are Podzol, Brown forest soil and Pseudogley, among which there may be an intimate mutual relationship as shown in Fig.5. It seems that the soil pattern (Fig.6) reflects approximately the features of the surface geology. By way of example, the genesis and distribution of the Brown forest soil and Pseudogley on the Asajino Plane, could be explained as follows : Though the terrace is mainly composed of sand and gravel, the superficial part consists of sand mixed with volcanic ash on the coastal side, while of lacustrine clay on the inland side. It may be said that such a contrast in facies of surface deposit has been caused by the epirogenetic movement during the latest stage of the deposition of Asajino formation, as shown by the palaeogeography in Fig.7, No.4. Then, in order to elucidate the genesis of Pseudogley, developed mainly in the inland side and derived from clayey materials the following succession of palaeogeographical events should be taken into consideration : Formation of an inland lake→filling up by fine sediments ⇄ formation of marsh land→gleization of marsh soils→upheaval, terracing and lowering of ground-water table→formation of Pseudogley from the former gleyed marsh soils. In the coastal side where the grain-size of the superficial materials is coarser, on the contrary, the well drained hydrological conditions may have been maintained, and have favoured the genesis of Brown forest soils. It may be safely concluded that the genesis and distribution of the genetic soil types in this region should be closely related to the development of landscape since the beginning of the Wurm glacial stage.

腕足類の貝殼構造

The author has studied the micro-structure of the brachiopod shells, based upon the observations on the decalcified shells and on the photographs of electron-microscope. In this paper, the general remarks about the terebratellid shells are briefly described, and the relations between calcite crystals and organic matter, and the shape of the latter are shown in the figures.

北西ひだ変成帯の庵谷-大谷地域における広域変成作用と花崗岩化作用

ひだ変成岩のだいぶぶんは,石灰質片麻岩(透輝石片麻岩・角閃石片麻岩)である.そして,場所によっては,黒雲母片麻岩と角閃岩がみられる.本論文では,富山県婦負郡大長谷村の庵谷-大谷地域でみられる広域変成作用と花崗岩化作用の特徴が論じられた． Ⅰ　広域変成作用の特徴 　a. 角閃岩の起源 　残留斜長石にC-twinの多いことから，角閃岩が塩基性凝灰岩ないし火山岩から山来したものと推定される 　b. 堆積岩源片麻岩の起源 　透輝石片麻岩は，石灰質珪岩ないし珪質自雲岩が原岩であり，黒雲母片麻岩は，珪質粘土岩が原岩である．なお，角閃石片麻岩の原岩は，透輝石片麻岩の原岩にほぼ類似するが，ややアルミニウムに富む． 　透輝石片麻岩と角閃石片麻岩では，透輝石−カリ長石という鉱物組合せが角閃岩相で安定に存在する．このことから，広域変成作用の特徴として，水蒸気圧が低く，炭酸がスの分圧が高かったと推定される．ただし，黒雲母片麻岩に作用した条件は，この逆である． Ⅱ　花崗岩作用の特徴 　花崗岩化作用は，角閃岩の花崗岩化作用と堆積岩源片麻岩の花崗岩化作用に大区分され，さらに，次のように小区分された. 　1.　角閃岩の花崗岩化作用 　角閃岩−星雲状片麻岩−庵谷紅色花崗岩 　角閃岩−斑状変晶片麻岩−庵谷紅色花崗岩 　2.　堆穫岩源片麻岩の花崗岩化作用 　透輝石片麻岩−大谷灰色花崗岩 　角閃石片麻岩−大谷灰色花崗岩 　黒雲母片麻岩−大谷灰色花崗岩 　a. 角閃の花岩崗岩化作用 　角閃岩の花崗岩化作用に，二つの差異が生じた原因は，化学的条件によるもの ではなく，おもに物理的条件によるものである．差動運動の有無が主要な原因である．しかし，最終的には，紅色花崗岩の形成をもって，花崗岩化作用がおわる． 　b. 堆積岩源片麻岩の花崗岩化作用 　堆積岩源片麻岩の花崗岩化作用では，原岩に化学成分上の要因が充分なばあいには，直接，灰色花崗岩が形成される例を示した，従来，たとえば，透輝石片麻岩−角閃石片麻岩−無雲母片麻岩−混成岩−花崗岩という漸進的な花崗岩化作用が考えられているが，本論文では，これに対立した考えを提示した． 　最終的に形成された庵谷紅色花崗岩は，大谷灰色花崗岩よりも流動性に富んでいる．これは，WYLLIE・TUTTLE(1959)の実験結果と一致する．全圧力がほぼ等しい条件下で花崗料化作用が進行するばあいには，炭酸がスの分圧が高いと考えられる堆積岩源片麻岩では，溶融の開始がおくれるからである. 　以上に述べた花崗劉化作用を前提にして，岩石の化学成分の変化，造岩鉱物の化学成分と光学的性質の変化が取り扱われた.

動物相からみた日本海の起源(II)

Based on the facts and principles concerning the evolution and distribution of marine animals, mostly fishes, in the Japan Sea and its neighboring waters in the North Pacific, which were discussed in the previous part of the present study, a consideration was made on the history of development of this marginal sea and its fauna during the Quaternary period. 1. During the early phase of the Quaternary period, possibly Pre-Glacial to First Glacial stage, there must have been a shallow and wide freshwater lake in the place of the present-day Japan Sea. In this lake, freshwater fishes of the Amur River system (Acipenseridae, Leuciscinae, Lefua, etc.) as well as of the survival forms from the ancient or paleo-Japan Sea (mostly salmonids), with a minor component of the tropical sea origin (Epinephelinae : the ancestral forms of Stereolepis and Coreoperca), must have been flourishing. In early half of this phase, the paleo-Amur may have poured directly into the lake and a drain river of the lake may have started somewhere on its southern border and flowed southward across the "East China Sea Plain" and, after uniting with the lower part of the paleo-Yantse Kiang, discharged into a lagoon situated in the north of the presentday Miyako Islands, southern Ryukyu. In the latter half of this phase, the area bordering the southern sides of the lake must have been raised, forming a mountain ridge, and the flow pattern of the river system in the surrounding region markedly changed; the lower reaches of the paleo-Amur are now considered to have worked as a drain river of the lake. 2. It is presumed to have been in First Interglacial stage that the lake first received an inundation of sea water and was transformed through a brackish environment eventually into a marine basin. The invasion of sea water must have been made from north, possibly via the lower part of the paleo-Amur or the drain river of the lake. In the course of thalassification, some of the freshwater animals might have been exterminated or taken refuge in less saline or quite freshwater environment in coastal lagoons and upper reaches of rivers, but others succeeded to adapt or re-adapt themselves to the marine environment. The first marine fish invaders and colonizers of this newly-formed seawater environment are supposed to have been the ancestral forms of the families Stichaeidae and Agonidae, both of which, finding the greater part of the habitat unoccupied in the new environment, have adapted themselves to every (bottom) niches, and carried out a prodigious differentiation somewhat resembling the adaptive radiation, producing many important subfamilies such as Opisthocentrinae, Xiphisterinae, Neozoarcinae, etc. and Tilesininae, Brachyopsinae and Agoninae, respectively. 3. The Japan Sea thus originated must have remained in the connected condition with the Pacific possibly throughout First Interglacial to Second Interglacial stages. In Second Interglacial stage, another sea channel is supposed to have been opened somewhere near the present-day Tsugaru Straits. Through these channels, active interchange of marine fauna may have been done between this marginal basin and the Pacific ; of particular significance may be the emigration of a part of the diversely differentiated stichaeid and agonki fishes to the northern North Pacific and further to the west coast of North America, and also the invasion of the ancestral forms of some primitive groups of the Pleuronectinae (Cleisthenes, Hippoglossoides and Acanthopsetta) and of the Cottidae, particularly the Pseudoblenninae and its related groups (Atopocottus, Alcichthys, Ricuzenius, etc.), from the tropical waters in southeastern Asia and the west coast of North America, respectively. 4. In Third Glacial stage, the Japan Sea was possibly isolated , and within this isolated basin most of the animals may have been differentiated into the species or genera endemic to the

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