Differential thermal analysis : application and results in mineralogy
Author(s)
Bibliographic Information
Differential thermal analysis : application and results in mineralogy
(Minerals and rocks, 11)
Springer-Verlag, 1974
- : U.S.
- : Germany
Available at / 30 libraries
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Hokkaido University, Library, Graduate School of Science, Faculty of Science and School of Science図書
: GermanyDC19:549/M6622020868528
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Note
Bibliography: p. [159]-172
Description and Table of Contents
Description
At first glance it may seem presumptuous to want to add yet another to the numerous books on Differential Thermal Analysis (DT A). Thermoanalytical methods have been in use for some time, as shown by the more than five thousand publications containing DT A or TG curves listed by SMOTHERS and CHIANG in the bibliography to their handbook and abstracted in the several volumes of Thermal Analysis Abstracts (TAA), edited by J. P. REDFERN for the International Con- federation for Thermal Analysis (ICT A). Every three years the proceed- ings of ICT A meetings are published, bringing the latest results of thermoanalytic research. There is also the Scifax DT A Data Index, edited by R. C. MACKENZIE (1962) and modeled on the ASTM pattern card index (used for X-ray investigations), a compilation of the DT A data for several hundred minerals, and inorganic and organic materials. The theoretical foundations of thermogravimetry and DT A have been described in detail by LEHMANN, DAS and PAETSCH (1953), R. C. MACKENZIE (1957, 1970), DUVAL (1963), WENDLANDT (1964), GARN (1965), F. PAULIK et al. (1966), SMOTHERS and CHIANG (1966), and KEATTCH (1969).
Thermoanalytical results are strongly influenced by various factors relative to preparation and equipment (see 1-2. 4 of this study). This is the reason why we frequently find, in these books as well as in the Scifax-Card catalog, contradictory data on the same substance.
Table of Contents
I. Methods.- 1. Thermogravimetry and Differential Thermal Analysis.- 2. Heat Changes and Their Measurement in DTA.- 2.1 Cause of Heat Changes.- 2.2 DTA Apparatus.- 2.3 Characteristics of DTA Curves and DTA Data.- 2.4 Factors Which Influence DTA Data.- 2.4.1 Furnace Atmosphere.- 2.4.2 Sample Arrangement.- 2.4.3 Thermocouples.- 2.4.4 Heating Rate.- 2.4.5 Reference Material.- 2.4.6 Grain Size and Packing Density.- 2.4.7 Amount of Sample.- 2.4.8 Preparative Factors.- 2.5 The Technique of Measurement and of Standardization.- 2.5.1 Recommendations of ICTA for the Publication of Thermoanalytical Data.- 2.5.2 Standardization and Indirect Characterization by Means of PA-Curve and Standard Temperature.- 3. Calibration and Exactness of Measurement.- 3.1 Calibration.- 3.2 Exactness and Reproducibility of Measurements.- 3.3 Improvement of the Exactness of Measurement Using Internal Standards.- 3.4 Sensibility of Proof.- 4. Quantitative Determinations by DTA.- 4.1 Difficulties in Quantitative DTA Determinations of Minerals.- 4.2 Determination of Thermodynamic Data.- 4.2.1 Equilibrium Temperatures.- 4.2.2 Heat of Reaction, ? H.- 5. Methods Combined with DTA.- 5.1 DTA + High-Temperature X-Ray Analysis.- 5.2 DTA + High-Temperature Microscopy.- 5.3 High-Pressure DTA.- 5.4 DTA + Mass Spectrometer.- 5.5 Other Methods Related to or Combined with DTA.- II. Application of Differential Thermal Analysis to Mineralogy: Identification and Semi-Quantitative Determination of Minerals.- 1. Elements and Chalcogenides.- 1.1 Elements.- 1.2 Chalcogenides.- 2. Halogenides and Sulfates.- 2.1 Halogenides.- 2.2 Sulfates.- 3. Oxides and Hydroxides.- 3.1 Oxides.- 3.2 Hydroxides.- 3.3 Soils and Iron Ores.- 4. Carbonates and Nitrates.- 4.1 Carbonates Free of Water and without Other Anions.- 4.2 Carbonates Free of Water with Other Anions.- 4.3 Hydrated Carbonates without Other Anions.- 4.4 Hydrated Carbonates with Other Anions.- 4.5 Nitrates.- 5. Borates, Phosphates, and Arsenates.- 5.1 Borates.- 5.2 Phosphates and Arsenates.- 6. Ortho-, Ring-, and Chain Silicates.- 7. Sheet Silicates.- 7.1 Kaolinites.- 7.2 Pyrophyllite and Talc.- 7.3 Montmorines (Smectites) and Vermiculites.- 7.4 Micas.- 7.5 Chlorites.- 7.6 Serpentines.- 7.7 Palygorskite and Sepiolite.- 7.8 Clay Minerals with Mixed-Layer Structure.- 7.9 Mixtures of Sedimentary Minerals ("Clays").- 8. Zeolites.- 9. Allophane, Opal, and Organic Matter of Soils and Sediments.- 10. Development of Identification Diagrams.- III. Special Application of Differential Thermal Analysis in Mineralogy: Statements about Chemical Composition, Degree of Disorder, and Genesis of Minerals.- 1. Influence of the Chemical Composition on the Decomposition Temperatures of Carbonates and Hydroxides.- 1.1 Substitution of Ca++ by Mg++ or Pb++ in Calcites.- 1.2 Substitution of Ca++ by Sr++, Ba++, and Pb++ in Aragonites.- 1.3 Substitution of Mg++ by Fe++ and Mn++ in Dolomites.- 1.4 Hydrozincite and Aurichalcite.- 1.5 The Incorporation of Al+++ into the Structure of Goethite.- 2. Influence of the Chemical Composition on the Temperatures of Structural Transformations.- 2.1 Carbonates.- 2.2 Cu-Ag Sulfides.- 3. Influence of the Chemical Composition on the Curie-Temperatures of Magnetites.- 4. Contribution to the Classification of Chlorites.- 5. Smectites and Vermiculites: The Distinction between Di- and Tri-Octahedral Minerals and Grain Size Determination.- 6. Determination of the Degree of Disorder in Kaolinites.- 7. The Interdependence of Degree of Disorder, High-Low Inversion, and Temperature of Formation of Low-Temperature Cristobalites.- 8. The Determination of Inversion Temperatures of Quartz Crystals as a Petrologic Tool.- 9. The High-Low Inversion Behaviour of Microcrystalline Quartz Crystals.- References.
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