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Solid State Microbatteries

  • Book
  • © 1990

Overview

Editors:
  1. James R. Akridge

    1. Eveready Battery Co., Inc., Westlake, USA

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    You can also search for this editor in PubMed   Google Scholar

  2. Minko Balkanski

    1. Université Pierre et Marie Curie, Paris, France

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    You can also search for this editor in PubMed   Google Scholar

Part of the book series: NATO Science Series B: (NSSB, volume 217)

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Table of contents (27 chapters)

  1. Front Matter

    Pages i-x
    Download chapter PDF

  2. Overview of Aqueous and Nonaqueous Batteries and Semiconductors

    • Forrest A. Trumbore
    Pages 1-39

  3. Thin Film Technology and Characterization: Their Use in Microionic Devices

    • M. Ribes
    Pages 41-58

  4. The Physical Formation Processes of Thin Films, Their Characterization by XPS, AES and SIMS and Their Applications in Microbatteries

    • Alain Levasseur, G. Meunier, R. Dormoy, M. Menetrier
    Pages 59-97

  5. Study and Characterization of Thin Films of Conductive Glasses With a View to Application in Microionics

    • J. Sarradin, R. Creus, A. Pradel, R. Astier, M. Ribes
    Pages 99-102

  6. Chemistry, Physics and Applications of Polymeric Solid Electrolytes to Microbatteries

    • Bruno Scrosati
    Pages 103-143

  7. The Use of EXAFS in the Study of Polymeric Electrolytes

    • Roger J. Latham
    Pages 145-149

  8. Amorphous Room Temperature Polymer Solid Electrolytes

    • W. Wieczorek, K. Such, J. Przyluski
    Pages 151-155

  9. Designing a Solid Electrolyte I. Quality Criteria and Applications

    • John B. Goodenough
    Pages 157-175

  10. Designing a Solid Electrolyte II. Strategies and Illustrations

    • John B. Goodenough
    Pages 177-193

  11. Designing a Solid Electrolyte III. Proton Conduction and Composites

    • John B. Goodenough
    Pages 195-212

  12. Designing a Solid Electrolyte IV. Designing a Reversible Solid Electrode

    • John B. Goodenough
    Pages 213-232

  13. Technology and Physics of Thin Film Insertion Compounds

    • C. Julien, M. Balkanski
    Pages 233-267

  14. Insertion Cathodes for Solid State Microbatteries

    • M. Balkanski, C. Julien
    Pages 269-292

  15. Kinetics Studies of Lithium Insertion in In-Se Thin Films

    • I. Samaras, C. Julien, M. Balkanski
    Pages 293-296

  16. The Role of NiPS3 as a Cathode in Secondary Lithium Solid State Batteries

    • I. Saikh, C. Julien, M. Balkanski
    Pages 297-300

  17. Theory and Applications of Amorphous Solid for Electrochemical Cells

    • J. L. Souquet, A. Kone, M. Levy
    Pages 301-322

  18. Silver Gallium Thiohypodiphosphate Glasses

    • Claus Wibbelmann, Brian Munro
    Pages 323-328

  19. Modeling, Fabrication, and Development of Miniature Ion Sensors

    • Robert F. Savinell, Chi-Jin Chen, Chung-Chiun Liu
    Pages 329-342

  20. Solid State Batteries

    • James R. Akridge
    Pages 343-352
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Keywords

About this book

This Advanced Study Institute on the topic of SOLID STATE MICROBATTERIES is the third and final institute on the general theme of a field of study now termed "SOLID STATE IONICS". The institute was held in Erice, Sicily, Italy, 3 - 15 July 1988. The objective was to assemble in one location individuals from industry and academia expert in the fields of microelectronics and solid state ionics to determine the feasibility of merging a solid state microbattery with microelectronic memory. Solid electrolytes are in principle amenable to vapor deposition, RF or DC sputtering, and other techniques used to fabricate microelectronic components. A solid state microbattery 1 1 mated on the same chip carrier as the chip can provide on board memory backup power. A solid state microbattery assembled from properly selected anode/solid electrolyte/cathode materials could have environmental endurance properties equal or superior to semiconductor memory chips. Lectures covering microelectronics, present state-of-art solid state batteries, new solid electrolyte cathode materials, theoretical and practical techniques for fabrication of new solid electrolytes, and analytical techniques for study of solid electrolytes were covered. Several areas where effort is required for further understanding of materials in pure form and their interactions with other materials at interfacial contact points were identified. Cathode materials for solid state batteries is one particular research area which requires attention. Another is a microscopic model of conduction in vitreous solid electrolytes to enhance the thermodynamic macroscopic Weak ~lectrolyte Iheory (WET).

Editors and Affiliations

  • Eveready Battery Co., Inc., Westlake, USA

    James R. Akridge

  • Université Pierre et Marie Curie, Paris, France

    Minko Balkanski

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