Solvent extraction : classical and novel approaches / Vladimir S. Kislik.

Includes bibliographical references and index.

pt. 1. Conventional (classical) principles and practice of solvent extraction. 1. Modern (classical) fundamental principles of solvent extraction. 2. Principles of solvent extraction of organic and mineral acids. 3. Chemistry of metal solvent extraction. 4. Engineering development of solvent extraction. 5. Examples of application of solvent extraction techniques in chemical, radiochemical, biochemical, pharmaceutical, analytical separations, and wastewater treatment -- pt. 2. Novel competitive complexation/solvation theory (CCST) of solvent extraction : principles and practice. 6. Backgrounds of the competitive complexation/solvation theory of solvent extraction. 7. Competitive complexation/solvation theory of solvent extraction : general mechanisms and kinetics. 8. CCST in engineering design, procedures, and calculations. 9. The CCST in solvent extraction of acids by amine-based extractants. 10. Competitive complexation/solvation theory in metal solvent extraction. 11. Final remarks on the competitive complexation/solvation theory of solvent extraction and its application -- pt. 3. Modern and future trends in fundamentals and applciations of solvent extraction. 12. Modern and future trends in fundamentals of solvent extraction. 13. Advances in development of solvents for liquid-liquid extraction. 14. Recent advances in solvent extraction processes and techniques -- Appendix -- Index.

The main challenge in modern solvent extraction separation is that most techniques are mainly empirical, specific and particular for narrow fields of practice and require a large degree of experimentation. This concise and modern book provides a complete overview of both solvent extraction separation techniques and the novel and unified competitive complexation/solvation theory. This novel and unified technique presented in the book provides a key for a preliminary quantitative prediction of suitable extraction systems without experimentation, thus saving researchers time and resources. Analyzes and compares both classical and new competitive models and techniques Offers a novel and unified competitive complexation / solvation theory that permits researchers to standardize some parameters, which decreases the need for experimentation at R&D Presents examples of applications in multiple disciplines such as chemical, biochemical, radiochemical, pharmaceutical and analytical separation Written by an outstanding scientist who is prolific in the field of separation science.