| Description |
1 online resource : illustrations (black and white) |
| Contents |
880-01 Cover; Preface; Acknowledgements; Contents; Principal Symbols; Selected General References; 10 A Guide to Predictive Models for Metallic Liquid Thermophysical Properties; 10.1 Introduction; 10.2 Essential Conditions of Predictive Models; 10.3 Improvements on Well-Known, Representative Models for Liquid Thermophysical Properties; 10.4 Periodic Table and Grouping, or Classification, of the Chemical Elements; 10.5 Periodic Variations in Values of Some 12 Physical Quantities or Thermophysical Properties with Atomic Number; References; 11 Predictions of the Velocity of Sound; 11.1 Introduction |
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880-01/(S 11.2 Predictions of Melting Point Sound Velocities in Various Liquid Metals11.3 Dimensionless Common Parameters ξ 1/2 T and ξ 1/2 E; References; 12 Predictive Models for Volume Expansivity; 12.1 Introduction; 12.2 Predictive Models for Liquid Metallic Element Volume Expansivity; 12.3 Comparison with Experiment; References; 13 Predictions of Evaporation Enthalpy; 13.1 Introduction; 13.2 Predictive Models for Evaporation Enthalpy; 13.3 Predictions of Evaporation Enthalpies |
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13.4 Relationship between Evaporation Enthalpy of Liquid Metallic Elements and Other Thermophysical Properties or QuantitiesReferences; 14 Predictions of Surface Tension; 14.1 Introduction; 14.2 Calculations or Predictions of Metallic Liquid Surface Tensions; 14.3 Temperature Coefficient of Surface Tension; REFERENCES; 15 Predictions of Viscosity; 15.1 Introduction; 15.2 Viscosity Models for Accurate Predictions; 15.3 Performance of the Modified Fowler-Born-Green Relation; 15.4 Viscosity Calculations using Periodic Relationships and the Weakness of this Method |
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15.5 Calculations or Predictions of Melting Point Viscosity15.6 Supplementary Explanation for the Modified Fowler-Born-Green Relation; 15.7 Temperature Dependence of Viscosity; References; 16 Predictions of Self-Diffusivity; 16.1 Introduction; 16.2 A Predictive Model for Liquid Metallic Self-Diffusivity; 16.3 Calculations or Predictions of Liquid Metallic Self-Diffusivity Data; References; 17 Experimentally Derived Data for the Thermophysical Properties of Liquid Metallic Elements; 17.1 Melting and Boiling Points; 17.2 Atomic Numbers and Relative Atomic Masses |
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17.3 Molar Melting and Evaporation Enthalpies17.4 Density Data; 17.5 Vapour Pressure Equations; 17.6 Molar Heat Capacities at Constant Pressure; 17.7 Sound Velocity Data; 17.8 Surface Tension Data; 17.9 Viscosity Data; 17.10 Self-Diffusivity Data; 17.11 Electrical Resistivity and Thermal Conductivity Data; References; Glossary and/or Supplementary Explanations; Appendix 1 Periodic Table of the Elements; Appendix 2 Derivation of the Linear Equation Satisfying the Condition of the Minimum S Value (i): a Slope = m, an Intercept = 0 |
| Summary |
This volume considers the essential conditions for a model to be truly predictive. The authors use a statistical approach to rate the validity of the various predictive models that have been previously used for evaluating various thermophysical properties. On the basis of this assessment, the authors have predicted values for the thermophysical properties of elemental metallic liquids, which are lacking in experimental data |
| Bibliography |
Includes bibliographical references and index |
| Notes |
Online resource; title from home page (viewed on October 8, 2015) |
| Subject |
Liquid metals -- Thermal properties -- Computer simulation
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Liquid metals -- Effect of temperature on -- Computer simulation
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| Form |
Electronic book
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| Author |
Guthrie, Roderick I. L., author
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| ISBN |
9780191796661 |
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0191796662 |
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