Format:
1 Online-Ressource (421 pages)
ISBN:
9780429651052
Content:
Cover -- Half Title -- Title -- Copyrights -- Contents -- Preface -- 1 Introduction -- 1.1 Survismeter: An Experimental Resource -- 1.2 Survismeter: A Flagship Science -- 1.2.1 Detection of Alcoholic (-OH) Functional Group -- 1.2.2 Detection of Cations -- 1.3 Survismeter: A Boon for Nanomaterials -- 1.3.1 Merits of the Survismeter -- 1.3.1.1 Primary physicochemical parameters measured, determined, or detected -- 1.3.1.2 Secondary physicochemical parameters measured with Borosil Mansingh Survismeter -- 1.4 Distinguishing Solution and Dispersion -- 2 Survismeter: A New Device -- 2.1 Quattropolar, Virtual Valve, Center of Gravity, and CPU -- 2.2 Interzonal Distance -- 2.3 Fundamental Model of Friccohesity Measurements -- 2.4 Advanced Method for Surface Tension Measurements -- 3 Electronic Optimization and Molecular Energetics -- 3.1 Experiment: Distinguishing Saturated and Unsaturated Oil Mixtures -- 3.1.1 Theory for the Experiment -- 3.1.2 Systems to be Experimented -- 3.2 Friccohesity -- 3.2.1 Friccohesity Measurement of Samples in Small Amounts: Biological and Biochemical Samples -- 3.2.2 Friccohesity to Formulate Reinforcing Materials -- 3.2.3 Friccohesity of Hydrophobic and Hydrophilic Forces -- 3.2.4 Friccohesity as a Structural Function -- 3.2.5 Friccohesity to Determine Percolation of Oil or Drug Amount in Micelles -- 4 Advanced Method for Surface Tension Measurements -- 4.1 Limitations of du No¨ uy Ring Method -- 4.2 Limitations of Platinum-Iridium-Made Wilhelmy Plate -- 4.3 Friccohesity of Survismeter Measurements -- 5 Friccohesity: Advanced Molecular Forces Engineering -- 5.1 Science and Expression of Hydrogen Bonding -- 5.2 Scientific Capabilities of the Survismeter -- 5.3 Determining Percentage of Saturated Oil -- 5.3.1 Theory -- 6 Noncovalent Chemical Activities -- 6.1 Density Determination with a Survismeter
Content:
6.2 Alignment of Cations -- 6.3 Biocompatible Nanoemulsion -- 7 Hyperconjugation and Friccohesity -- 7.1 Anticoagulants -- 7.2 Friccohesity Model for Determining Polymer MoleculeWeight -- 7.3 Experiment for Drug Loading by a Dendrimer -- 8 Cross-Partitioning Law of the Survismeter -- 8.1 Basics of Friccohesity Science -- 8.2 Solubility Determination with a Survismeter -- 8.3 Biophysics Experiments for Testing Blood Sugar -- 9 Intramolecular Multiple Forces Theory -- 9.1 Unique Theory of New Science: Friccohesity -- 9.2 Friccohesity for Understanding Colloids -- 10 Friccohesity Determination with the Survismeter -- 10.1 Normal Cohesive Cages -- 10.2 Supporting Reasons for Measuring Friccohesity -- 10.3 Salient Features of Survismeter Science -- 11 Food Molecules and Calorie Value -- 11.1 Nanoemulsion for Anticorrosion, Antifat Deposition, and Fat Hydrolysis -- 11.2 In Situ pH Impact of Phenols -- 11.3 Fat Dissolution by a Eutectic Mixture of Choline and Urea -- 11.4 Activation Energy -- 11.5 Relationship of Kinetic Energy with πr2l Condition -- 12 Heat Carrying Emulsions: Lower Viscosity and Higher Surface Tension -- 12.1 Hydrophilic and Hydrophobic Domains -- 12.2 Interfacial Thermodynamics and G -- 12.3 Mechanistic Understanding of IFT of Salinity Effect -- 13 Critical Temperature of a Single-Component System -- 13.1 Heat Transfer and Physicochemical Properties -- 13.2 Micelle with Effective Membrane Strength -- 14 Friccohesity of Fortified Beverages: Excellent Physicochemical Properties -- 14.1 Incentives and Understanding of Food Intake -- 14.2 Friccohesity and SAR -- 15 Structural Interactions with Viscosity Coefficients -- 15.1 Interionic Interaction Depicted by Viscosity A-Coefficient -- 15.2 Intermolecular Interaction Depicted by Viscosity B-Coefficient -- 15.3 Structure Breaking and Making Interactions with Viscosity A- and B-Coefficients
Content:
15.4 New Equation and Physicochemical Indicators -- 15.5 Structure Maker and Breaker Theories -- 16 Detection Limit of the Survismeter -- 16.1 Entropy Determination from Activation Energy -- 16.2 Effect of Particle Size on Physicochemical Parameters -- 17 Particle Size Distribution and Particle Packing -- 17.1 Pressure Interconversion Units -- 17.2 Tentropic Emulsion -- 17.3 Microemulsion for Food Sciences -- 18 Unique Experiment -- 18.1 Salt Mechanism of Surfactants -- 18.1.1 Calculating Integrals -- 18.2 Law for Shifting CF to FF in Bulk with Higher Friccohesity -- 19 Dynamic and Static Surface Tension -- 19.1 Pdn: Most Effective Methodology with the Survismeter for Surface Tension -- 19.2 Two-Way to One-Way Chemical Activity: Multiple Kinetic Energy Indexes -- 19.3 Compatibility in LightWavelength and Particle Size: Theory -- 19.4 Gelatin Microemulsion as Viscosity Enhancer -- 20 Hydrodynamic Size of a Gelatin Particle -- 20.1 Theory -- 20.2 Activation Energy -- 20.3 Unique Experiments: Theory and Method with the Survismeter -- 20.3.1 Theory and New Method -- 21 Surface Area of a Gelatin Particle -- 21.1 Gelatin Fluid Dynamics -- 21.2 Friccohesity of AgNO3 Colloidal Solution -- 21.3 Auto Purity Device -- 21.4 Water for Athletes -- 22 Optical and Molecular Interface -- 22.1 Viscosity Increasing Theory -- 23 Molecular Origin of Physicochemical Properties: IMMFT and Tentropy -- 24 Thermodynamic Stability -- 24.1 Friccohesity Law of Interacting Surface Area -- 24.2 Thin Film andWetting of Solid Glass Surface -- 24.3 Study of Ion-Induced Dipole Forces -- 25 Molecular Mechanics -- 25.1 Molecular Dynamics -- 26 Domain of Physicochemical Processes -- 26.1 Fundamentals of Physicochemical States -- 26.2 Art History and Restoration -- 27 Molecular Swirling -- 27.1 Swirling Sound Generation -- 27.2 Physicochemical Properties of a Transitional Structure
Content:
28 Fundamentals of Nanoemulsion -- 28.1 Immiscible Solvent Phases -- 28.2 Anticaking Chemicals -- 28.3 Experiment for Simultaneous Adsorption of Water and Oil at the LLI -- 29 Natural Preservative and Antioxidants -- 29.1 Organic Preservatives -- 29.2 Photon Conversion into Sound of a Specific Frequency -- 29.3 Chemical Activities During Liquid Flow in the Survismeter Capillary -- 30 Cohesive Forces, Friccohesity, and Crop Growth -- 30.1 Entropy Production in Forming Micelles -- 30.2 Micelle Packing Parameter -- 31 Block Copolymer Micelles -- 31.1 Graphene Research -- 32 Industrial Outlook of Cohesive Forces -- 33 Friccohesity ofWalking Molecular Liquids and Nonwalking Molecular Liquids -- 34 Special Experiments with the Survismeter -- 34.1 Basic Concept of Micelles -- 34.2 Theory for Nanoemulsions -- 35 Friccohesity of Dispersion or Flocculation of Colloidal Suspensions through the Surface Area of NPs' Zeta Potential -- 36 Critical Insight into Molecular Activities for Tentropy and IMMFT -- 37 Oil Oxygen Capturing Ability of Molecules Studied with the Survismeter -- 37.1 Experimentation for Oil Stability Index -- 37.2 Friccohesity and Structural Application -- 38 Monodisperse Nanomaterials for Drug Delivery Systems -- 38.1 Salts Have an Effect on Double Activities of Tweens -- 38.1.1 Surfactant and the Least Surface Tension -- 38.2 Viscosity Enhancement -- 39 Radius of a POVS Macromolecule -- 39.1 The Description of a Depsurvismeter -- 39.2 Nanoemulsions and Allied Features -- 39.3 Advantages of a Nanoemulsion over Other Dosage Forms -- 39.4 Disadvantages of Nanoemulsion-Based Systems -- 40 Formation of a Nanoemulsion -- 40.1 Factors Affecting Nanoemulsion Formulation -- 40.2 Nanoemulsion Preparation -- 40.3 High-Pressure Homogenization -- 40.4 Variables for Optimized Formulation -- 40.4.1 Homogenization Pressure -- 40.4.2 Microfluidization
Content:
40.5 Microfluidizer for Nanoemulsions -- 40.5.1 Ultrasonication -- 40.6 Spontaneous Emulsification -- 40.6.1 Solvent Evaporation -- 40.6.2 Hydrogel Method and Transmembrane Permeation -- 41 Characteristics and Applications of Nanoemulsions -- 41.1 Dye Solubilization and Dilutability Test -- 41.2 Conductance in Nanoemulsions -- 41.2.1 Dynamic Light Scattering -- 41.2.2 Polydispersity -- 41.2.3 Phase analysis -- 41.2.4 Interfacial tension -- 41.2.5 Viscosity Measurement -- 41.2.6 In Vitro Skin Permeation -- 41.2.7 Thermodynamic Stability -- 41.3 Stability of Nanoemulsions -- 41.4 Applications of Nanoemulsions -- 41.4.1 Parenteral Delivery -- 41.4.2 Oral Delivery -- 41.4.3 Topical Delivery -- 41.4.4 Cosmetics -- 41.4.5 Transdermals -- 41.4.6 Biotechnology -- 41.4.7 Determining van derWaals Forces in DMSO,Water, and DMF -- 42 Friccohesity and Its Applications -- 42.1 Determination of the Nanoemulsion of BaSO4 -- 42.2 Questionnaires -- 43 Novelty in Polarity of Solutions and Nanoemulsions -- 43.1 Thermodynamics of Nanoemulsions -- 44 CO2 Determination of a Healthy Person Using the Survismeter -- 44.1 Lungs and Friccohesity -- 44.2 Cellulose Acetate Propionate -- 45 Noncovalent Interaction Engineering -- 45.1 Hydrophobic Engineering and the Survismeter -- 46 Demulsifier Salts: Pulling out of Impurities by Preferential Binding Activities -- 47 Kinematics Viscosity -- 47.1 Friccohesity of SOx, COx, and NOx Gases -- 48 Friccohesity Titrations for Hydration and Dehydration -- 49 Shear Thickening and Shear Thinning -- 49.1 Shear Thickening -- 49.1.1 Shear Thickening of Eye Lotions -- 49.2 Fundamentals of Dealing with a Liquid in Daily Activities -- 49.2.1 Academic applications of liquids -- 49.2.2 Teeth-cleaning biokinetic liquids -- 49.2.3 Industrial applications of liquids -- 49.2.4 Interfacing between FTIR and friccohesity -- 49.3 Shear Thinning
Content:
49.4 Thixotropic Liquids
Additional Edition:
9789814774703
Additional Edition:
Erscheint auch als Druck-Ausgabe Singh, Man Survismeter : Fundamentals, Devices, and Applications Milton : Pan Stanford Publishing,c2019 9789814774703
Language:
English
URL:
Volltext
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