地理学評論
Online ISSN : 2185-1719
Print ISSN : 0016-7444
ISSN-L : 0016-7444
27 巻, 6 号
選択された号の論文の5件中1~5を表示しています
  • 加藤 武雄
    1954 年 27 巻 6 号 p. 229-243
    発行日: 1954/06/25
    公開日: 2008/12/24
    ジャーナル フリー
    Mt. Zao Proper has been the active center of the Zao volcanic group in historic tunes. At present, near the entrance of the Jigokuzawa, not far from G oshikidake (the central cone of Zao Proper), several fumaroles are still found. The Sugawa and the Nigorigawa, the too river systems around Zao Proper, have been well known for their poisonous acidic water. The Sugawa, including such branches as the Sukawa, Zaogawa, Miyakawa, Shirakawa, etc., flows into the Sea of Japan. The Nigorigawa has its origin in the vicinity of a crater Jake, Ohania, just west of Goshikidake and, after being joined by various branches, flows into the Pacific Ocean. Both of the systems seem to have a close relation to the volcanic activity. From the limnological point of view, these systems have already been investigated to some extent by Yoshida and others, but many problems are still unsolved. In order to gain further knowledge of the rivers and to study the change s in their chemical constituents, the present research has been carried on since 1951.
    So far as Sugawa system. is concerned, in 1951. the author examined the temperature and the chemicall ingredients of the water at 18 stations in the drainage system. The results of the chemical analyses are summarised as follows:-
    1) The Sukawa, the Zaogawa, and the Sugawa (the main stream) are strongly acidic. The Sukawa is joined by waters from. Zao hot spring (an acidic alum vitriol spring) and the Zaogawa is contaminated by poisonous acid water from a sulphur mine now in operation. As is shown in Figure 3 of the text, the acid content of the Sukawa has kept the same value for the last twenty years, but, on the contrary, the pH values of the Sugawa have become higher during these years.
    2) It must be noted that the sulphate content of the Sukaw-a as well. as of the Zaogaw a is remarkably high, but the chloride content of tie latter is negligibly small as compared with that of the former. This may be explained by the fact the Sukawa contains n-iagniatic juvenile water while the Zaogawwa is not influ-enced by such water. Though running through adjacent areas composed of volcanic mud flows, the two branches show remarkable differences in their chemical properties.
    3) As for calcium, magnesium, manganese, iron, and silicate, the water of the two rivers show abnormality in. their content and differ fromm. other branches of the system. The Sukawva especially shows a high concentration of aluminum owing to the fact that the water from the Zao hot spring joins it.
    4) At every station in the Sukawa-Sugawa system, the ratio Ca/Mn and Cl/SO4 keep the same values respectively.
    In addition, the writer has been examining the chemical constituents every month since January, 1951, at six stations in the system. Front the. results of the observations, it is found that there is a negative correlation between the sulfate content of the Sugawa and the precipitation except at the snowmeting season.
    In the middle of July, 1953, the author explored the Nigorigawa valley andd analysed water taken from. 16 stations in the drainage system. According to the results of these chemical analyses, he has reached the following conclusions:
    1) As in the case of the Sugawa system, the Nigorigaw a system has long been famous for poisonous acidic water which originates from Mt. Zao Proper. The present investigation has shown that the pH value of the water in the Nigorigawa-Matsukaiva system increases gradually from 2.9 to 5.9 while the streams are running down grade.
    2) Sulfur deposits which had once been mined are distributed in the vicinity of Paikokuten. Being influenced by those deposits, as well as by the crater lake Okanma, the water of the upper reaches of the Nigorigawa is rich, in sulfate content. Waters taken from the upper stream of the Nigorigawa and the Jigokuzawa are characterized by a large content of iron, calcium, and magnesiulit. 3)
  • 岩塚 守公
    1954 年 27 巻 6 号 p. 244-254
    発行日: 1954/06/25
    公開日: 2008/12/24
    ジャーナル フリー
    The northern part of Nagasaki Prefecture is a region in which landslides occur very frequently; in fact more landslides occur here than any other region in Japan. Landslides are now occuring at about fifty places as shown on the map accompanying this article.
    The general landforms of northern Nagasaki Prefecture consist of five elements: 1) at the top, the slightly undulating surface of the basaltic lava plateau, 2) the steep cliff of the edge of the basaltic lava plateau, 3) the small flat surface at the base of the steep cliff, 4) the pediment-lihe gentle slope extending downward from the small flat surface, and 5) at the lowest elevation, the alluvium-covered surface on the valley floor. (These elements are shown in diagrammatic form in Figure 2.)
    Many landslides in this region occur on the small hat surface at the base of the steep cliff andd on the pediment-like gently. slope extending downwards from the small flat surface. Such landslides are caused, in large part, by the underlying, soft Tertiary formations of sandstones and shales, for sliding surfaces are rapidly formed on them and, thus, facilitate the sliding of the upper materials. The sliding materials are more generally the basaltic detritus, abundantly supplied from. the steep cliff of the edge of the basaltic lava plateau, and are less the decomposed materials of the Tertiary formations.
    In this paper four landslide areas (noted on the map) are described in detail with accompanying diagrams.
  • 入会慣行と山林状態
    千葉 徳爾
    1954 年 27 巻 6 号 p. 255-262
    発行日: 1954/06/25
    公開日: 2008/12/24
    ジャーナル フリー
    In the documents which have been studied, it was noted, that there are more bare hills in the rural common forest than in the other lands of the Okayama district. There were two types of rural common forest, one was used by the families of only one village and the other was used by the people of two or more villages. The former is not such a big problem, but the latter is the very subject of this study. In this study the word “common forest” means this type. The common forest is usually located between settlements, on ridges of hills or on the borders of villages. Forestry experts say that the soils of the rounded ridges are clay which are eroded easily for morphological reasons. However, the soil of the ridges. are.not always naturally eroded but also have been devastated by man's activities.
    In the documents we see that many of the common forests have been in dispute between some of the villages. Soil erosion has been noted, because the use of the forest were so wasteful by digging of roots, or by the use of the moss surface. Some people says that the cutting of wood for fuel and timber is the reason for erosion. In fact the requirement for fuel for urban and rural settlement increased due to the growing population and the development of industry. However, the fuel sold commercially was obtained from the private forest, because the products of the common forest. could not be sold without compensation to the villages and such cases were very rarely mentioned in the documents.
    Thus the author concludes that as the poor class who have no private forest grew with the development of an exchange economy, the common forest were used for fuel by the poor class and much waste took place. Thus the forests are denuded and have not been replanted. The rain weathered the granite hills and the eroded soils made the stream beds higher and higher. This process began from the. 19th century near the salt farms and margins of the Setouchi lowland.
  • 山本 荘毅, 谷津 栄寿, 品田 毅, 星野 朗, 中村 清史
    1954 年 27 巻 6 号 p. 263-267
    発行日: 1954/06/25
    公開日: 2008/12/24
    ジャーナル フリー
    鬼怒川流域に於て民家の井戸を使つて測水,測温,水素イオン濃度測定を行つた結果次のことが知られた.尚調査は上流地域を1951年8月に,下流地域を1952年10月下旬から11月上旬にかけて行つた.
    1) 地下水面迄の深さは台地に深く低地に浅いが全般的に見て北部に深く南部に浅い.
    2) 地下水面の形態は上流に単純で下流に複雑になる.
    3) 河川と地下水との交流関係を見ると鬼怒川上流では伏流滲透,西鬼怒川では涵養滲透,田川では中立関係,五甞川では涵養滲透である.
    4) 低地の地下水温は上流で20°C,下流16°Cであるが台地の夫れは上流で16°C,下流で14°Cである.
    5) 低地の水素イオン濃度は上流で6.1~6.2,下流で6.4であるが台地の夫れは上流で5.8,下流で5.8~6.0である.
    6) 宙水水が台地北部の宝積寺附近に,自噴水が下流に見られた.
  • 1954 年 27 巻 6 号 p. 268-274_1
    発行日: 1954/06/25
    公開日: 2008/12/24
    ジャーナル フリー
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