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Smart Polymers for Soft Materials: From Solution Processing to Organic Solids.

Debashish Mukherji1, Kurt Kremer2

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Summary
This summary is machine-generated.

Smart polymers respond to external stimuli, offering tunable properties for advanced materials. This review explores their solution processing and use in organic solids, aiding future design.

Keywords:
coil–globule transitionorganic solidspolymer solutionsmart polymerssolvent mixturesthermal conductivity

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Area of Science:

  • Materials Science
  • Polymer Chemistry
  • Physical Chemistry

Background:

  • Smart polymers are crucial in modern technologies due to their responsiveness to external stimuli.
  • These polymers exhibit unique solvation behaviors, particularly in mixed solvents below their lower critical solution temperature.
  • Hydrogen bonds play a key role in designing high-performance organic solids with tunable properties.

Purpose of the Study:

  • To review recent developments in smart polymers.
  • To discuss solution processing and applications in organic solids.
  • To provide microscopic understanding for designing advanced functional materials.

Main Methods:

  • Summary of recent theoretical developments in smart polymer simulations.
  • Integration of complementary experimental findings.
  • Analysis of structure-property relationships.

Main Results:

  • Responsive polymers can be processed in solution for various applications.
  • Smart polymers contribute to the development of lightweight, high-performance organic solids.
  • Microscopic understanding facilitates the design of advanced functional materials.

Conclusions:

  • Smart polymers offer significant potential in advanced material design.
  • A deeper understanding of structure-property relationships is crucial for future innovations.
  • This review serves as a guide for experimental and simulation-based research.