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Selective formation of metastable polymorphs in solid-state synthesis.

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|January 17, 2024
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Researchers developed a new theoretical framework to control solid-state synthesis of metastable materials by manipulating reaction energy and precursor selection for targeted polymorph nucleation.

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Area of Science:

  • Materials Science
  • Solid-State Chemistry
  • Crystallography

Background:

  • Metastable polymorphs arise from complex thermodynamic and kinetic factors.
  • Predictive synthesis methods for solution-based techniques are advancing, but solid-state methods lag.
  • Controlling polymorph selectivity in solid-state reactions remains a challenge.

Purpose of the Study:

  • To introduce a theoretical framework for predicting and controlling polymorph selectivity in solid-state reactions.
  • To demonstrate the use of reaction energy as a key parameter for selecting metastable phases.
  • To enable targeted synthesis of specific polymorphs via solid-state routes.

Main Methods:

  • Developed a theoretical framework integrating thermodynamics and kinetics.
  • Utilized in situ characterization techniques.
  • Performed density functional theory (DFT) calculations.
  • Investigated two synthesis pathways for Lithium Titanium Phosphate (LiTiOPO₄).

Main Results:

  • Identified reaction energy as a critical factor influencing surface energy and metastable phase nucleation.
  • Demonstrated precursor selection impacts reaction energy and thus polymorph outcome.
  • Quantified conditions for experimental accessibility of metastable polymorphs.
  • Successfully controlled LiTiOPO₄ polymorph synthesis via precursor choice.

Conclusions:

  • The developed framework provides a general approach for targeted solid-state materials synthesis.
  • Precursor selection offers a viable strategy for controlling polymorph nucleation.
  • This approach has potential applications across diverse chemistries for selective polymorph synthesis.