Pedologist Volume 20, Issue 2

H_E-PQ Diagram of Soil Humus

A H_E-PQ diagram for characterizing soil humus has been proposed. Here. H_E values mean the amount of 0.1N KMnO_4 in milliliter consumed by humic and fulvic acids contained in one gram of soil, while PQ values mean the percentage of humic acid in humic and fulvic acids. As for the A_0 and A horizons of soils dealt with in this paper, the following seven groups were differentiated on the diagram: 1. L, F H layers of all soils. 2. Alpine grassland soils. 3. Soils under temperate and subalpine forests. 4. Soils under warm-temperate forests. 5. Soils under tropical and subtropical forests. 6. Volcanic ash soils (Ohmasa's black soils). 7. Buried A horizons of volcanic ash soil. Podsols were characterized by the fact that each horizon was widely distributed on the diagram and grouping of their A horizons was impossible.

Relationship between Subsoil Characters of Paddy Soil and Plant Growth.

1. So-called "Kareure" phenomena (premature withering) of naked barley cultivated in paddy fields have been found to occur exclusively in paddy soils with gravelly subsoil. 2. The grain yields and the amount of absorbed mineral nutrients of barley as well as the dry matter production of some kinds of grasses were appreciably lower compared to the soils with finer-textured subsoil that can supply nutrients and water to plant roots. 3. Experiments on rice growing were conducted using artificial soil columns. When the plow layer is very low in fertility, the subsoil character greatly influenced both the nutrient uptake and grain yields. In the case of very fertile plow layer, however, the effects of subsoil were very small. 4. The subsoils became gradually reduced under submerged conditions. Some kinds of substances eluviated from the plow layer were mostly absorbed by subsoil, while others were largely leached from the profile.

Studies on Micromorphological Properties of Red Soils and Paddy Soils in Northwestern Kyushu.

The present paper deals with micromorphological properties of the Red soils in northwestern Kyushu, changes in soil structure of paddy soils and young polder soils by farm mechanization, and morphological, physical and micromorphological properties of some paddy soils under the different conditions of rice culture in the Chikugo, the Saga and the Isahaya areas of northern Kyushu. The results obtained are summarized as follows: 1. The A_0 horizons in Red soils are characterized by a silicate moder form and by a predominance of large pores. There are three kinds of fecal pellets in the insects or mite-bitten cavities of plant remains or among partially decomposed plant fragments. One is relatively small (0.01-0.2 mm in size), pale yellow, yellowish brown or reddish brown and dense, egg-like in shape and interspersed with comminuted plant remains in the A_0 horizons of the soils. The second one present among partially-decomposed plant leaves in the A_0 horizon is small (0.05-0.8mm in size), yellowish brown, reddish brown and brown, and irregulary massive in shape and dominated by fine mineral grains. The last one is the fecal pellets and microaggregates (>4 mm and 4-1 mm in size) of earthworms among decomposed plant leaves in the A_0 horizons. The fecal pellets of earthworms in the A_0 horizon of the Setaka soil have higher pH value (about 6), and higher nitrogen contents (about 0.6) than those of the A horizon of the soil (pH value is 4.8 and total nitrogen is 0.1 per cent). CEC, contents of exchangeable bases (calcium, magnesium, potassium and sodium) and base saturation degree in the fecal pellets of eathworms are 47.8 me, 3.4 me, 1.9 me and 60 per cent, respectively. The occurrence of these fecal pellets indicates that litter-feeding soil faunas such as mites, springtails, macroarthropodes and earthworms play an important role in the mechanical comminution and the chemical decomposition of leaf litter at early stage of humification and in biological circulation of soil elements. 2. All the A horizons are characterized by a mull-type humus and porphyroskelic fabrics and are dominated by relatively large pores. The B horizons have a weakly-developed spongy and moderately- and strongly-developed porphyroskelic fabrics and are more compact than the A horizons. Plasmic fabrics of the B horizons are silasepic, skel-silasepic, insepic and mosepic. The B horizons of the Red soils examined contain abundant oriented clays than do the A horizons. Layered, moderately- and strongly-developed oriented clays were mainly found on pore walls. These oriented clays resemble the illuviation cutans. 3. As a result of the land preparation of the paddy soil by using bulldozer, the past plowed horizon (the buried IIA_<11>gG horizon) has become more compact than the upper and the lower horizons. The past plowed horizon (the buried IIA_<11>gG horizon) has a strongly-developed porphyroskelic fabric and a fluidal structure. Low permeability of paddy soil is due to the occurrence of the compacted IIA_<11>gG horizon formed by using bulldozer. 4. According to a classification system of rice soils devised by I. Kanno, paddy soils in the Chikugo, the Saga and the Isahaya areas of northern Kyushu have been classified as "Intermediate Gley-like Rice soils" and "Surface-water Gley-like Rice soils" at the level of genetic soil type, respectively. Those are subdivided into the following subtypes, that is, "Imperfectly-drained gley-like rice soils", "Drained gley-like rice sois" and "Well-drained gley-like rice soils". Micromorphological features of the soils are summarized as follows: (a) All the uppermost horizons have moderately-developed porphyroskelic and weakly-developed spongy fabrics and are dominated by relatively large pores, and nodules and mottles that are composed of iron and manganese. The plowsoles of the seven soils have

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Stratigraphic relation of the red weathering crusts appearing in Kitakami Massif, Northeast Japan.

The red weathering crusts appearing in Kitakami Massif, Northeast Japan were studied geomorphologically and stratigraphically, and the following results were obtained. 1. The red weathering crusts were generated mainly on hilly land and terrace in the margin of Kitakami Massif, but those were also observed partly on peneplane. 2. Because the red weathering crusts were covered with volcanic ash and secondarily deposited red weathering materials in general, the greater parts of the red weathering crusts were recognized as fossil soil, however some of those on hilly land were recognized as relic soil. 3. Judging from morphology and chemical properties of the red weathering crusts, those are similar to the zonal red soils in humid sub-tropical zone. Based on the stratigraphic relation, it is considered that those are not zonal red soils formed under recent bio-climatic condition, but paleo-red soils formed under past warmer bio-climatic one. 4. It is presumed that the volcanic ash layers appearing on peneplane of the northern part of Kitakami Massif, consist of typical volcanic ash stratigraphy, had been generated in Wurm glacial age. From the facts, it will be assumed that red weathering crusts in Kitakami Massif were formed under warmer bio-climatic condition before Wurm glacial age. Actually, based on the occurrence of red soils, Matsui (1962) has presumed that red weathering crusts were formed perhaps in Riss/Wurm interglacial age, and at that time the formation of red weathering crusts had been prevailed on the Pan-Japanese scale. 5. The writer has considered that the difference on the geological history may be existent between the northern half and the southern half of Kitakami Massif, during the dissected process of topography from the formation of red weathering crusts to the deposition of volcanic ash, from the deposited condition of volcanic ash layers and of secondarily deposited red weathering materials.

On the Opal Phytoliths of Tree Origins.

Morphological analyses of opal phytoliths in soils derived from grasses and trees were very useful for the reconstruction of vegetative history. The deposition site, degree of silicification and the morphological features of phytoliths in various tree leaves were examined under the polarization microscope and scanning electron microscope, and the source of phytoliths in soils were assumed from observation of morphological features of phytoliths in tree leaves. The results were summarized as follows: 1) The deposition site of silicification in tree leaves were most prevalent in vascular elements, epidermal cells, epidermal hairs and hair bases. The trees which contained phytoliths apparently were Magnoliaceae, Moraceae, Ulmuaceae, Faguaceae and Palmae. The degree of silicification in broad-leaved trees belonging to the same family varied with genus, species and sampling time, but phytoliths in evergreen trees were generally clearer in shapes than those of deciduous trees. 2) The amounts of silicic acid and phytoliths in tree leaves were lower than those of Gramineae. Among trees, Magnoliaceae, Moraceae, Ulmuaceae, Faguaceae, and Palmae were comparatively higher in its amounts. 3) The phytoliths were markedly different in shapes among broad-leaved trees, conifers and palms. Conifers generally contained simple cubic and irregularly shaped polyhedron phytoliths, while broad-leaved trees contained jisaw-puzzle shaped, hexagnoid or pentagnoid plate shaped, twisted and branched elongate, spindle shaped, blade shaped, irregular sphere or oval shaped and hollow-sockted hair cell phytoliths. 4) Some of phytoliths isolated from present and buried volcanic ash soils in Kyushu, red yellow podzolic soils in Okinawa Honto and red soils in Bonin Island (Chichigima) were derived from trees. Most of phytoliths of tree origins, found first in volcanic ash soils from Tanegashima and Yakushima, were found to be quite similar to those of vascular cells in Distylium racemosum Sieb. et Zucc. leaves.

The Role of the Pedology on the Crop Productivity

Through the examination of the relation between soil maps and the map of crop productivity classes, the authours tried to clarify by means of what pedology would be able to contribute to the productivity. The results obtained were summarized as follows: 1. As the whole soil types, the significant correlation (-0.8298***) were recognized between the crop productivity and the altitudes. The reason for this phenomena would be considered as that in higher altitude zone there distributed the lower productive soils such as Brown forest soil and Pseudogley soil, while in lower altitude zone there located higher productive soil such as Lowland soil. 2. Within the same soil type (e. g. Brown volcanic ash soil), there were further high significant correlation (-0.9271***) between the productivity and the altitudes. The reason would be considered that the productivity would be affected with the cumulative temperature during cropping season, which also has the high significant correlation with the altitudes. 3. The crop productivity levels differ according to soil types under even the same climatic conditions. The reason would be that the soils are affected by the climatic factors such as air temperature, rainfall or others differently in accordance with the soil characters by which the soil types are classified. 4. As for as factors of the soil productivity are concerned, it should be very important to grasp accurately how the soils are affected by the climatic factors in situ, and how the soils reflect the affection of the climate on crop growth and yield. Through the way aforesaid pedology should further contribute to crop productivity than it does now.

Far-Infrared Remote Sensing for Soil Survey.

The remote sensing technique can provide much useful informatin to pedological research, especially in the area of soil mapping. In this report two experiments have been described. The model experiment was for differentiating between wet and dry soil using infrared radiation, the second experiment was carried out in which paddy soils were classified by density slicing of thermal mapper photographs. The model experiment was performed on November 29th 1974 in the lysimater of the National Institute of Agricultural Sciences, Tokyo. The variations of surface soil temperature under optimum weather conditions (i. e. sunny, no wind) for one day period were measured. Three types of soils (Volcanic ash soil, Alluvial soil and Sandy soil) were used and the ground water levels were carefully controlled. The results are listed as follows. 1) The maximum surface soil temperature difference between wet and dry soil occurred at noon. 2) In sandy soil the greatest temperature difference (about 7℃) was recorded. 3) The surface soil temperature was greatly influenced by the density of plant life. The thermal mapper photographs were taken twice (at nine A.M. and noon) on November 27th 1974 in the northern part of Hiratsuka, Kanagawa Prefecture. In the photographs which were taken at noon, a clear contrast in paddy field area could be recognized, on the other hand in the photographs which were taken at nine A.M., this contrast could not be recognized. Strong gley soil, gley soil and gray lowland soil in this area was classified by density slicing of the photographs which were taken at noon.