Inorganic constituents in soil : basics and visuals
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書誌事項
Inorganic constituents in soil : basics and visuals
Springer, c2018
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注記
Includes bibliographical references and index
"Springer Open" --T.p.
内容説明・目次
内容説明
This open access book is a must-read for students of and beginners in soil science. In a well-organized and easy-to-follow manner, it provides basic outlines of soil minerals, new methods and recent developments in the field, with a special focus on visual aids.
The chapters on primary minerals, secondary minerals, non-crystalline inorganic constituents and inorganic constituents sensitive to varying redox conditions will help readers understand the basic components of soils. Further, readers are introduced to new analytical methods with the aid of microscopy and recent developments in the field. Uniquely, the book features case studies on the identification and isolation methods for vivianite crystals from paddy field soils, as well as a useful procedure for identifying noncrystalline constituents such as volcanic glasses and plant opals, which can also be applied to other soils depending on the local conditions.
Given its focus and coverage, the book will be useful to all readers who are interested in agronomy, plant production science, agricultural chemistry and environmental science.
In addition, it can help biogeochemists further expand their research work on the rhizosphere of wetland plant roots, iron and phosphate dynamics, etc.
目次
Chapter 1 Purpose and scope
This is an introductory chapter that includes 4 sections below. Significance of visual aids in studying inorganic soil constituents is also described. Principal purpose of this book is to provide basics and visual aids to beginners of soil science, environmental science and biogeochemistry.
1.1 Soil and ecosystem services
1.2 Functions of inorganic constituents in soil ecosystems
1.3 Analytical methods
1.4 Purpose and scope
Chapter 2 Primary minerals
Major primary minerals in soils are introduced with optical and electron microscope images, energy dispersive X-ray analysis, and X-ray diffraction. This chapter is one of the basic parts of the inorganic constituents in soil. Exemplified minerals are separated from volcanic ash soils (new and old ones as much as possible) and a granitic soil.
2.1 Silica minerals and Silicate minerals
2.1.1 Grouping of silicate minerals
2.1.2 Quartz, Feldspar, Mica, Augite, Hypersthene, Hornblende
2.2 Ferromagnetic minerals
Chapter 3 Secondary minerals
Major crystalline clay minerals including hydroxides and oxides in soils are introduced with optical and electron microscope images, energy dispersive X-ray analysis, and X-ray diffraction. This chapter is also the basic part of the inorganic constituents of soils. Minerals listed below were prepared from several different soils. Although the examples are more or less a mixture with other minor ones, it is very difficult to separate a purely single clay mineral from soil. Among these minerals, alteration of biotite is highlighted because partially weathered biotite is often found in soils and river deposits.
3.1 Grouping of secondary minerals
3.2 The 2:1 type
minerals
3.2.1 Micacious minerals
3.2.2 Vermiculite
3.2.3 Smectite
3.2.4 Chlorite
3.3 The 1:1 type minerals
3.3.1 Kaolinite
3.3.2 Halloysite
3.4 Hydroxides and oxides
3.4.1 Gibbsite
3.4.2 Manganese oxides
Chapter 4 Non-crystalline inorganic constituents
Volcanic glasses, plant opals, pedogenic opals, and short-range order minerals (allophane, imogolite) in Andisols are introduced with optical and electron microscope images, energy dispersive X-ray analysis. Among these, plant opals can be found in many soils under vegetation not only in the volcanic ash soils. A thin section is used to show microscopic distribution of minerals in an Andisol. Elemental composition of the short range order minerals such as allophane and imogolite is highly rich in Al while the parent materials of these short-range o
rder minerals, volcanic ash is silica-rich. Changes in element concentration during the process of short-range order minerals formation are discussed.
4.1 Poorly crystalline minerals in Andosols
4.1.1 Volcanic glasses
4.1.2 Plant opals
4.1.3 Pedogenic opal
4.1.4 Allophane and imogolite
4.2 Changes in element concentration during short-range order minerals
Chapter 5 Inorganic constituents sensitive to varying redox conditions
Minerals sensitive to varying redox conditions such as vivianite, siderite and ferric sulfides, jarosite are introduced with optical and electron microscope images, energy dispersive X-ray analysis, and X-ray diffraction. Many examples are from paddy field soil because in the paddy fields, reducing conditions and oxidizing conditions are repeated every year. The visual evidence of redox in the soil profile is iron
mottles formed at the redox interface. Elemental distribution of the iron mottles changes with morphological properties of the mottles.
It was revealed that an increase in the amount of available (acid soluble) phosphate in the reduced paddy field soil is mainly due to crystallization of vivianite. However, the vivianite dissolves again with the development of oxidizing conditions after drainage passively due to lowering of ferrous ion activity. Siderite is a ferrous carbonate mineral often found in the reduced subsoil. An example of siderite found as an pseudomorph of tubular iron mottles is provided. Oxidation of the large amount of pyrite results in formation of acid sulfate soil. Pyrite found in the tsunami deposit 2011 and Jarosite from eastern coast of Australia are used as examples.
5.1 Redox reactions regarding soil minerals
5.2 Iron mottlings
5.3 Iron Phosphates
5.4 Sider
ite
5.5 Pyrite and related sulfur containing inorganic constituents
Chapter 6 Role of inorganic soil constituents in selected topics
Three topics are provided to exemplify how the inorganic soil constituents play important roles. They are effects of tsunami on soil in 2011, Japan, dynamics of radiocesium in soil environment and phosphorus cycling in soil-plant systems. These topics include different interactions between the different inorganic soil constituents. These topics are helpful to disaster prevention and sustainable food production.
6.1 Evaporites and Tsunami-affected soils
Evaporites such as halite, gypsum, etc. are introduced. Examples found on the surface of lahar deposit in Luzon island and soils affected by tsunami 2011, Japan are shown with optical and electron microscope images, energy dispersive X-ray analysis. Then, an example of effects of seawater on agr
icultural soils is introduced based on analyses of deposits and soils at 344 sites. By comparing soil map and distribution of the carbon content of the tsunami deposit, it was revealed that the muddy tsunami deposit was strongly affected by the nearby farmland soils. At the well-drained sites, salts were removed with rain. In contrast, an adverse effect of seawater lasts long in the coastal area due to the subsidence of the ground.
6.1.1 Evaporites
6.1.2 Effect of tsunami 2011 on agricultural soils
6.1.2.1 Properties of tsunami deposit 2011
6.1.2.2 Salinization, sodification and restoration
6.2 Radiocesium
Cesium ion is strongly sorbed by inorganic soil constituents, and hardly moves in soil. However, cesium ion can move with inorganic soil constituents when erosion take place. The extractability of cesium ion from soil are described comparing with other alkaline metal ions
. Radiocesium affected soils of all over the world in 1950'-60's due to atmospheric nuclear testing and it is still detectable in soil. Further, a large amount of radiocesium deposited on soil by the accidents of nuclear power plants in Chernobyl (1986) and in Fukushima (2011). Regarding the case in Fukushima, semi-micro and macroscopic vertical distribution of radiocesium in the Tsunami-affected soil and transportation of radio cesium in rivers are described.
6.2.1 Sorption of cesium ion by soil
6.2.2 Vertical distribution of radiocesium in soil
6.2.3 Transportation of radiocesium in rivers estimated from side bar deposits
6.3 Inorganic constituents related to phosphorus cycle in soil-plant systems
Phosphate rock is one of the depleting resources. Phosphate rock is mainly processed to fertilizers and is applied to farmlands. However, recovery of phosphate from soil by plants is generally low due to sorption of phosphate by soil. On the other hand, the amount of phosphate in the heavily fertilized farmland is increasing and gradual release of phosphate from farmlands is concerned in order to avoid eutrophication of surface water. It is important to improve phosphate efficiency in agricultural soil-plant systems.
Apatite is the naturally occurring phosphate. Although the concentration of apatite in fresh volcanic ash is not low compared with other soils, phosphate react with active Al and Fe in volcanic ash soil that forms with weathering of volcanic ash. A Procedure to find apatite particles in volcanic ash, SEM images and EDX spectra of apatite are introduced. Then, reactions of phosphate ion with active Al and Fe materials are outlined including reactions of Ca phosphates with active Al and Fe materials. Phosphate absorbed by agricultural plants is partly returned to farmlands as compost and manures. Struvite i
s a major phosphate minerals found in swine and chicken manure composts. Brassica plant roots cover particulate phosphate such as brushite, struvite completely and show high efficiency in phosphate uptake especially in Andisols with high P fixation capacity. Phosphate cycling in paddy fields is reviewed highlighting crystallization of vivianite under reducing conditions as shown above (5.3).
6.3.1 Apatite
6.3.2 Reactions of phosphates with active Al and Fe materials
6.3.3 Struvite and P foraging root growth
6.3.4 Phosphate cycling in paddy fields
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