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Conducting organic materials.

R L Greene, G B Street

    Science (New York, N.Y.)
    |November 9, 1984
    PubMed
    Summary
    This summary is machine-generated.

    This review covers electrically conducting organic solids, including charge transfer salts and polymers. It details their novel solid-state properties, phase transitions, and conduction mechanisms.

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    Area of Science:

    • Materials Science
    • Solid-State Physics
    • Organic Chemistry

    Background:

    • Electrically conducting organic solids represent a significant area of scientific research.
    • These materials, including molecular charge transfer salts and polymers, exhibit unique solid-state properties.
    • Understanding their behavior requires integrating chemistry and structural analysis.

    Purpose of the Study:

    • To review current research directions in electrically conducting organic solids.
    • To elucidate the novel solid-state properties of these materials based on their chemistry and structure.
    • To discuss the conduction mechanisms in polymers and compare them to inorganic materials.

    Main Methods:

    • Literature review of current scientific research.

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  • Analysis of the chemistry and structure of molecular charge transfer salts and polymers.
  • Examination of phase transitions, superconducting, and magnetic states in charge transfer salts.
  • Investigation of the conduction mechanism in polymers.
  • Main Results:

    • Charge transfer salts exhibit various metal-to-insulator phase transitions.
    • Recent discoveries include superconducting and magnetic states in charge transfer salts.
    • The conduction mechanism in polymers is examined and contrasted with inorganic counterparts.

    Conclusions:

    • Electrically conducting organic solids, particularly charge transfer salts and polymers, possess complex and novel solid-state properties.
    • Phase transitions, superconductivity, and magnetic phenomena are key characteristics of charge transfer salts.
    • The study of conduction mechanisms in organic polymers offers insights comparable to inorganic materials.