Energy Storage: A New Approach [NOOK Book]

Dedications and Acknowledgements.

1 Introduction.

2 Comments on Classical Mechanics.

2.1 Force.

2.2 Energy Sources.

3 Conversion and Storage.

3.1 Availability of Solar Energy.

3.2 Conversion Processes.

3.3 Storage Processes.

4 Practical Purposes of Energy Storage.

4.1 The Need for Storage.

4.2 The Need for Secondary Energy Systems.

4.3 Sizing Power Requirements of Familiar Activities.

4.4 On-the-road Vehicles.

4.5 Rocket Propulsion Energy Needs Comparison.

5 Competing Storage Methods.

5.1 Problems with Batteries.

5.2 Hydrocarbon Fuel: Energy Density Data.

5.3 Electrochemical Cells.

5.4 Metal-Halogen and Half-Redox Couples.

5.5 Full Redox Couples.

5.6 Possible Applications.

6 The Concentration Cell.

6.1 Colligative Properties of Matter.

6.2 Electrochemical Application of Colligative Properties.

6.3 Further Discussions on Fundamental Issues.

6.4 Adsorption and Diffusion Rate Balance.

6.5 Storage by Adsorption and Solids Precipitation.

6.6 Some Interesting Aspects of Concentration Cells.

6.7 Concentration Cell Storage Mechanisms that Employ Sulfur.

6.8 Species Balance.

6.9 Electrode Surface Potentials.

6.10 Further Examination of Concentration Ratios.

6.11 Empirical Results with Small Laboratory Cells.

6.12 Iron/Iron Concentration Cell Properties.

6.13 The Mechanisms of Energy Storage Cells.

6.14 Operational Models of Sulfide Based Cells.

6.15 Storage Solely in Bulk Electrolyte.

6.16 More on Storage of Reagents in Adsorbed State.

6.17 Energy Density.

6.18 Observations Regarding Electrical Behavior.

6.19 Concluding Comments.

6.20 Typical Performance Characteristics.

6.21 Sulfide/Sulfur Half Cell Balance.

6.22 General Cell Attributes.

6.23 Electrolyte Information.

6.24 Concentration Cell Mechanism and Associated Mathematics.

6.25 Calculated Performance Data.

6.26 Another S/S^-2Cell Balance Analysis Method.

6.27 A Different Example of a Concentration Cell, Fe⁺²/Fe⁺³.

6.28 Performance Calculations Based on Nernst Potentials.

6.29 Empirical Data.

7 Thermodynamics of Concentration Cells.

7.1 Thermodynamic Background.

7.2 The CIR Cell.

8 Polysulfide - Diffusion Analysis.

8.1 Polarization Voltages and Thermodynamics.

8.2 Diffusion and Transport Processes at the (-) Electrode Surface.

8.3 Electrode Surface Properties, Holes, and Pores.

8.4 Electric (Ionic) Current Density Estimates.

8.5 Diffusion and Supply of Reagents.

8.6 Cell Dynamics.

8.7 Further Analysis of Electrode Behavior.

8.8 Assessing the Values of Reagent Concentrations.

8.9 Solving the Differential Equations.

8.10 Cell and Negative Electrode Performance Analysis.

8.11 General Comments.

9 Design Considerations.

9.1 Examination of Diffusion and Reaction Rates and Cell Design.

9.2 Electrodes.

9.3 Physical Spacing in Cell Designs.

9.4 Carbon-Polymer Composite Electrodes.

9.5 Resistance Measurements in Test Cells.

9.6 Electrolytes and Membranes.

9.7 Energy and Power Density Compromises.

9.8 Overcharging Effects on Cells.

9.9 Imbalance Considerations.

10 Calculated Cell Performance Data.

10.1 Electrical Performance Modeling.

11 Single Cell Empirical Data.

11.1 Design and Construction of Cells and the Materials Employed.

11.2 Experimental Data.

12 Conclusion: Problems and Solutions.

12.1 Pros and Cons of Concentration Cells.

12.2 Future Performance and Limitations.

Appendix 1: A History of Batteries.

Al.1 A History of the Battery.

A1.2 The Electric Car and the Power Source Search.

A1.3 The Initial Survey.

A1.4 Review of a Research Path for a Long-life, High ED Battery.

Appendix 2: Aids and Supplemental Material.

A2.1 Properties of Homogeneous Membranes.

A2.2 The van der Waals Equation and its Relevance to Concentration Cells.

A2.3 Derivation of Electrolyte Interconnectivity Losses.

A2.4 Efficiency Calculations.

A2.5 Specific Resistivity and Specific Gravity of Some Reagents.

Bibliography.

Index.