Solution Thermodynamics and its Application to Aqueous Solutions
Elsevier Science Ltd (Verlag)
978-0-444-53073-8 (ISBN)
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As the title suggests, we introduce a novel differential approach to solution thermodynamics and use it for the study of aqueous solutions. We evaluate the quantities of higher order derivative than the normal thermodynamic functions. We allow these higher derivative data speak for themselves without resorting to any model system. We thus elucidate the molecular processes in solution, (referred to in this book “mixing scheme), to the depth equal to, if not deeper, than that gained by spectroscopic and other methods. We show that there are three composition regions in aqueous solutions of non-electrolytes, each of which has a qualitatively distinct mixing scheme. The boundary between the adjacent regions is associated with an anomaly in the third derivatives of G. The loci of the anomalies in the temperature-composition field form the line sometimes referred as “Koga line. We then take advantage of the anomaly of a third derivative quantity of 1-propanol in the ternary aqueous solution, 1-propanol – sample species – H2O. We use its induced change as a probe of the effect of a sample species on H2O. In this way, we clarified what a hydrophobe, or a hydrophile, and in turn, an amphiphile, does to H2O. We also apply the same methodology to ions that have been ranked by the Hofmeister series. We show that the kosmotropes (salting out, or stabilizing agents) are either hydrophobes or hydration centres, and that chaotropes (salting in, or destablizing agents) are hydrophiles.
Dr. Koga's group introduced a new approach to the thermodynamic studies of aqueous solutions. They devised methods of measuring various thermodynamic quantities differentially. These methods allow them to experimentally evaluate the intermolecular interaction, the key quantity in the so-called "many-body problem. The group has started applying this new methodology to aqueous solutions of biopolymers. As a recognition of his contribution to solution thermodynamics, he was awarded the Society Award by The Japan Society of Calorimetry and Thermal Analysis in 2006. In 2011, he obtained for the first time in the world a fourth derivative of Gibbs energy and named it "Acceleration of the effect of solute on entropy-volume cross fluctuation density."
PART A: A Differential Approach to Solution ThermodynamicsChapter I. Basics of thermodynamics – Derivatives of Gibbs energy, GChapter II. Solution thermodynamics – Use of the second and the third derivatives of GChapter III. Determination of the partial molar quantities Chapter IV. Fluctuations and partial molar fluctuations – Understanding H2OPART B: Studies of Aqueous Solutions using the Second and the Third Derivatives of GChapter V. Mixing schemes in binary aqueous mono-olsChapter VI. Mixing schemes in aqueous solutions of non-electrolytesChapter VII. Effects of non-electrolytes on the molecular organization of H2O: 1-Propanol (1P) probing methodology Chapter VIII. Effects of ions on the molecular organization of H2O: 1-Propanol (1P) probing methodologyChapter IX. Interactions in ternary aqueous solutions – General treatmentChapter X. In closing – Executive summary on the effect of solute on H2OAppendix A. B-spline vs. manual graphical differentiationAppendix B. Gibbs-Konovalov correctionAppendix C. Heat capacity anomalies associated with phase transition – Two level approximation Appendix D. Freezing point depressionAppendix E. Titration calorimetry with dilute titrant
Erscheint lt. Verlag | 3.10.2007 |
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Verlagsort | Oxford |
Sprache | englisch |
Maße | 165 x 240 mm |
Gewicht | 730 g |
Themenwelt | Naturwissenschaften ► Chemie ► Physikalische Chemie |
ISBN-10 | 0-444-53073-8 / 0444530738 |
ISBN-13 | 978-0-444-53073-8 / 9780444530738 |
Zustand | Neuware |
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