| Physical Chemistry of Cetyl Alcohol: Occurrence and Function of Liquid Crystals in O/W Creams / Shoji Fukushima ; Michihiro Yamaguchi1.: |
| Introduction |
| Cetyl Alcohol |
| Description of Cetyl Alcohol / 1.1.: |
| Short History of Cetyl Alcohol / 1.2.: |
| Definitions in Official Books / 1.3.: |
| Physical Properties of Cetyl Alcohols / 2.: |
| Polymorphism of Higher Alcohols / 2.1.: |
| Crystal Structure of Higher Alcohols / 2.2.: |
| Melting Point and Transition Point of Higher Alcohols / 2.3.: |
| Transition Point and Infrared Absorption / 2.4.: |
| Specific Interaction between 1-Hexadecanol and 1-Octadecanol / 3.: |
| Composition of Commercially Available Cetyl Alcohol / 3.1.: |
| Transition Point of 1-Hexadecanol / 3.2.: |
| Interaction between Higher Alcohols and Water / 4.: |
| Experimental Facts / 4.1.: |
| Formation of Hemihydrate / 4.2.: |
| Structure of Hydrated Alcohols / 4.3.: |
| Phase Diagram of the 1-Hexadecanol/1-Octadecanol/Water Ternary System / 4.4.: |
| Studies on Higher Alcohol/Surfactant/Water Systems / 5.: |
| The 1-Decanol/Sodium Caprylate/Water System / 5.1.: |
| The 1-Hexadecanol/OTAC/Water System / 5.2.: |
| Rheology of Ternary Systems Containing 1-Hexadecanol or a Homologous Alcohol / 5.3.: |
| Influence of the Amount of 1-Hexadecanol / 5.3.1.: |
| Influence of the Nature of Surfactant and of Higher Alcohol / 5.3.2.: |
| Influence of Alkyl Chain Length of Surfactant / 5.3.3.: |
| Conclusion / 5.3.4.: |
| Nature of Ternary Systems Prepared with Hexaoctadecanols / 6.: |
| Stability and Rheological Properties of Ternary Systems as a Function of Temperature / 6.1.: |
| Variations in External Appearance / 6.1.1.: |
| Variations in Viscosity / 6.1.2.: |
| Microscopic Observation / 6.1.3.: |
| X-Ray Diffraction Analysis / 6.1.4.: |
| Low-Angle X-Ray Diffraction Analysis / 6.1.5.: |
| Thermal Property / 6.1.6.: |
| Polymorphism of Hexaoctadecanol (3:2) and Stability of a Ternary Cream / 6.2.: |
| Liquid Crystalline Phases in Hexaoctadecanol (3:2)/Surfactant/Water Ternary Systems / 7.: |
| Phase Diagram / 7.1.: |
| D[subscript 2] Region / 7.2.: |
| M Region / 7.3.: |
| The Location and State of the D[subscript 2] Phase and M Particles in a Ternary Cream / 7.4.: |
| Temperature and the Process Yielding the Liquid Crystalline Phase / 8.: |
| Temperature of the Formation of the Liquid Crystalline Phase / 8.1.: |
| Method of Phase Separation Experiments / 8.1.1.: |
| Results of the Phase Separation Experiment / 8.1.2.: |
| G Phase and S Phase / 8.2.: |
| X-Ray Diffraction / 8.2.1.: |
| Differential Scanning Calorimetry / 8.2.3.: |
| Temperature at which the LC Phase is Formed / 8.2.4.: |
| In situ Formation of G and M Phases / 8.3.: |
| The Function of Liquid Crystalline Phases in O/W Creams / 9.: |
| Studies on O/W Creams / 9.1.: |
| The Difference in the Viscosity-Increasing Effects due to the Nature of Higher Alcohols / 9.2.: |
| The Difference in the Viscosity-Increasing Effect due to the Nature of Surfactants / 9.3.: |
| The Viscosity Change due to the Ratio of Cetostearyl Alcohol to Surfactant / 9.4.: |
| The Effect of Mixing 1-Hexadecanol with 1-Octadecanol / 9.5.: |
| Crystallization of Cetyl Alcohol in Cosmetic Creams / 9.6.: |
| Internal Structure and Stability of O/W C Creams / 10.: |
| Internal Structure of O/W Creams / 10.1.: |
| A Novel Theory for the Stabilization of O/W Creams / 10.2.: |
| Additional References on Cetyl and Homologous Alcohols / Appendix 1: |
| Appendix 2 |
| References |
| Ionization Processes and Proton Binding in Polyprotic Systems: Small Molecules, Proteins, Interfaces, and Polyelectrolytes / Michael Borkovec ; Bo Jonsson ; Ger J. M. Koper |
| Experimental Techniques |
| Macroscopic Techniques |
| Definition and Measurement of pH / 2.1.1.: |
| Potentiometric Titration Techniques / 2.1.2.: |
| Other Macroscopic Techniques / 2.1.3.: |
| Spectroscopic Methods |
| Nuclear Magnetic Resonance (NMR) Techniques / 2.2.1.: |
| Optical and Other Spectroscopic Methods / 2.2.2.: |
| Modeling of Ionizable Systems |
| General Considerations |
| Computer Simulation Techniques |
| Simple Electrolyte Solutions / 3.3.: |
| Poisson-Boltzmann (PB) and Debye-Huckel (DH) Approximations / 3.3.1.: |
| An Illustrative Example / 3.3.2.: |
| Beyond the Poisson-Boltzmann (PB) Approximation / 3.3.3.: |
| Charged Molecules and Macromolecules in Water / 3.4.: |
| Debye-Huckel (DH) and Poisson-Boltzmann (PB) Treatment / 3.4.1.: |
| High-Salt versus Low-Salt Regime / 3.4.2.: |
| Toward Detailed Molecular Models / 3.4.3.: |
| Treatment of Ionization Equilibria / 3.5.: |
| Single Ionizable Site / 3.5.1.: |
| Localized versus Delocalized Binding / 3.5.2.: |
| Macroscopic Description / 3.5.3.: |
| Microscopic Description / 3.5.4.: |
| Adding Internal Degrees of Freedom / 3.5.5.: |
| Small Molecules |
| Monoprotic Acids and Bases |
| Equilibrium Constants / 4.1.1.: |
| Titration Behavior / 4.1.2.: |
| Experimental Data / 4.1.3.: |
| Diprotic Acids and Bases |
| Conformational Degrees of Freedom / 4.2.1.: |
| Equivalent Sites / 4.2.4.: |
| Oligoprotic Acids and Bases |
| Microscopic Description for Triprotic Acids and Bases / 4.3.1.: |
| Linear Molecules / 4.3.3.: |
| Noninteracting Sites |
| Microscopic versus Macroscopic Picture / 4.4.1.: |
| Affinity Distributions / 4.4.2.: |
| Interpretation and Prediction of Ionization Constants / 4.5.: |
| Empirical Methods / 4.5.1.: |
| Methods Based on First Principles / 4.5.2.: |
| Proteins |
| The Null Model |
| The Smeared-Out Charge Model |
| The Tanford-Kirkwood Model |
| Solution Techniques of the Ionization Problem |
| Shifts in Ionization Constants |
| Recent Developments in Dielectric Continuum Models / 5.4.: |
| General Methodology / 5.4.1.: |
| Case Studies / 5.4.2.: |
| Side Chain Flexibility / 5.4.3.: |
| Beyond Dielectric Continuum Models / 5.5.: |
| Protein Folding / 5.6.: |
| Polyelectrolytes |
| Mean-Field Models |
| Nearest-Neighbor Chain Interaction Models |
| Discrete Charge Model / 6.3.: |
| Mean-Field and Smearing-Out Approximations / 6.3.1.: |
| Chain Flexibility / 6.3.2.: |
| Polyamines / 6.4.: |
| Linear Polyamines / 6.4.1.: |
| Branched Polyamines / 6.4.2.: |
| Polycarboxylates / 6.5.: |
| Weakly Charged Linear Polycarboxylates / 6.5.1.: |
| Highly Charged Linear Polycarboxylates / 6.5.2.: |
| Humic Acids / 6.6.: |
| Ionizable Interfaces |
| Diffuse Layer Model and Its Generalization |
| Nernstian Surface / 7.1.1.: |
| Basic Stern Model / 7.1.2.: |
| Specific Counterion Binding / 7.1.3.: |
| Smearing-Out Approximation / 7.2.1.: |
| 1-pK versus 2-pK Models / 7.2.2.: |
| pK Shifts / 7.2.3.: |
| Latex Particles |
| Ionizable Monolayers |
| Metal Oxide and Metal Hydroxide Particles / 7.5.: |
| Experimental Aspects / 7.5.1.: |
| Data Interpretation / 7.5.2.: |
| Goethite / 7.5.3.: |
| Hematite / 7.5.4.: |
| Rutile and Anatase / 7.5.5.: |
| Gibbsite / 7.5.6.: |
| Silica / 7.5.7.: |
| Discussion |
| Electrostatics of Point Charges / Appendix A.: |
| Planar Interface / A.1.: |
| Sphere / A.2.: |
| Cylinder / A.3.: |
| Further Tools in the Ising Model Analysis / Appendix B.: |
| Cluster Expansion / B.1.: |
| Other Choices of State Variables / B.2.: |
| Mean-Field Cluster Expansions / B.3.: |
| Mean-Field Treatment of Nonequivalent Sites / B.4.: |
| Square Lattice with Nearest-Neighbor Interactions / B.5.: |
| Affinity Distribution Approach / Appendix C.: |
| Derivation from Simple Models / C.1.: |
| Experimental Data Inversion / C.2.: |
| Combined Application of Radiochemical and Electrochemical Methods for the Investigation of Solid/Liquid Interfaces / Kalman Varga ; Gabor Hirschberg ; Pal Baradlai ; Melinda Nagy |
| On the Significance of Radiotracer Methods in Sorption Studies |
| General Problems of Radioactive Contamination Studies |
| An Overview of Radiotracer Methods |
| Methods Used for the Investigation of Interfacial Phenomena |
| Experimental Techniques: A Historical Survey |
| Recent Progress |
| Methods Used for the Investigation of Radioactive Contamination-Decontamination of Constructional Materials |
| Selected Results |
| Adsorption of Anions and Cations on Polycrystalline Gold |
| Comparative Study of Specific Adsorption of Cl[superscript -], HSO[superscript - subscript 4]/SO[superscript 2- subscript 4] and HSO[superscript - subscript 3]/SO[superscript 2- subscript 3] Ions / 3.1.1.: |
| Electrosorption of Ag and Co Species / 3.1.2.: |
| Accumulation of [superscript 110m]Ag on an Austenitic Stainless Steel |
| Sorption Behavior of Duplex Stainless Steels in HCl and H[subscript 2]SO[subscript 4] Solutions |
| Time and Concentration Dependence of Cl[superscript -] and HSO[superscript - subscript 4]/SO[superscript 2- subscript 4] Accumulations |
| Potential Dependence of Cl[superscript -] and HSO[superscript - subscript 4]/SO[superscript 2- subscript 4] Accumulations |
| Conclusions |
| Author Index |
| Subject Index |
| Magnetic Particles: Preparation, Properties and Applications / M. Ozaki1: |
| Maghemite (gamma-Fe2O3): A Versatile Magnetic Colloidal Material / C.J. Serna ; M.P. Morales2: |
| Dynamics of Adsorption and Oxidation of Organic Molecules on Illuminated Titanium Dioxide Particles Immersed in Water / M.A. Blesa ; R.J. Candal ; S.A. Bilmes3: |
| Colloidal Aggregation in Two-Dimensions / A. Moncho-Jorda ; F. Martinez-L=pez ; M.A. Cabrerizo-V8lchez ; R. Hidalgo Alvarez ; M. Quesada-PMFrez4: |
| Kinetics of Particle and Protein Adsorption / Z. Adamczyk5: |
| Physical Chemistry of Cetyl Alcohol: Occurrence and Function of Liquid Crystals in O/W Creams / Shoji Fukushima ; Michihiro Yamaguchi1.: |
| Introduction |
| Cetyl Alcohol |
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