Calcite : formation, properties, and applications / Joana Dobrev and Petra Markovic, editors.

Includes bibliographical references and index.

Description based on print version record.

English.

CALCITE: FORMATION, PROPERTIES AND APPLICATIONS; CHEMICAL ENGINEERING METHODS AND TECHNOLOGY; EARTH SCIENCES IN THE 21ST CENTURY; CALCITE: FORMATION, PROPERTIES AND APPLICATIONS; Library of Congress Cataloging-in-Publication Data; CONTENTS; PREFACE; CHAPTER 1. CALCITE AS A TRACER OF ORE-FORMING HYDROTHERMAL FLUIDS: CARBON AND OXYGEN ISOTOPIC EVIDENCE; ABSTRACT; INTRODUCTION; CARBON AND OXYGEN ISOTOPES OF CALCITE; Analytical Procedure; Standardization (Reference Materials); OXYGEN ISOTOPE GEOTHERMOMETRY; APPLICATIONS OF THE METHOD TO ORE DEPOSITS.

1. Kushikino and Hishikari Gold Deposits in the Hokusatsu District1.1. Hokusatsu Gold District; 1.2. Kushikino Deposit; 1.3. Hishikari Deposit; 2. Noya Gold Deposit; 3. Ohtani and Kaneuchi Tungsten Deposits; 4. Kamioka Lead-Zinc Deposit; Geology; Isotopic Characteristics of Marine Limestones; Isotopic Characteristics of Crystalline Limestone in the Kamioka Mining District; 5. Gold Deposits in BIF; CONCLUSION; ACKNOWLEDGMENTS; REFERENCES; CHAPTER 2. THE MODULATION OF BIOMACROMELCULES ON THE CRYSTALLIZATION OF CALCIUM CARBONATE; ABSTRACT; INTRODUCTION.

1. THE INFLUENCE OF BIOMACROMOLECULES ON CACO3 CRYSTALLIZATION2. THE INFLUENCE OF SYNTHESIZED POLYMERS ON CACO3 CRYSTALLIZATION; 3. THE INFLUENCE OF BIOLOGICAL POLYSACCHARIDES ONCACO3 CRYSTALLIZATION; 3.1. The Influence of Chitosan Derivatives on CaCO3 Crystallization; 3.1.1. The Influence of Hydroxylated Chitosan on CaCO3 Crystallization; 3.1.2. The Influence of Carboxylated Chitason on CaCO3 Crystallization; 3.2. The Influence of Xanthan on CaCO3 Crystallization; CONCLUSION; ACKNOWLEDGEMENTS; REFERENCES; CHAPTER 3. THE ARCHAEOLOGICAL SIGNIFICANCE OF CALCITE; ABSTRACT; INTRODUCTION.

CALCITE AND TAPHONOMYCALCITE SPELEOTHEMS IN ARCHAEOMETRY; THE CALCITE FRACTION OF LOESS; REFERENCES; CHAPTER 4. CHALLENGES OF SPONTANEOUSLY FORMATION OF CALCITE DURING BIOACTIVITY ASSESSMENT ON BIOACTIVE MATERIALS INTERFACES; 1. INTRODUCTION; 1.1. Physico-Chemical Reactions at Biomaterials Interfaces; 1.1.1. Bioinert Materials; 1.1.2. Bioactive Materials; 1.2. Bioactivity Assessment of Bioactive Materials; 1.2.1. Disability of SBF in Predicting In Vivo; 2. COPRECIPITATION OF CALCITE; 2.1. A Short Review on Previous Researches; 2.2. Formation Mechanism of Calcite.

3. EFFECTS OF SBF COMPOSITION ON THE PRECIPITATION OF CALCITE3.1. Principles and Short History of SBF Solution; 3.2. Modification of SBF; 3.3. The Potential of SBF to Form HAp or Calcite; 3.4. Formation and Growth of Clusters in Different Kinds of SBFs; 4. EFFECTS OF SBF VOLUME ON THE FORMATION OF CALCITE; 4.1. The Importance of SBF Volume; 4.2. Recent Studies; 5. BONE BONING BEHAVIOR OF CALCITE; 5.1. General Feature; 5.2. Bonding Ability; 6. SUMMARY; REFERENCES; CHAPTER 5. SURFACE PROPERTIES OF CALCITE IN AQUEOUS SUSPENSIONS; ABSTRACT; 1. INTRODUCTION; 2. THE CACO3-H2O-CO2 EQUILIBRIUM.

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