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Exploring the Co-Crystallization Landscape of One-Dimensional Coordination Polymers Using a Molecular Electrostatic

Ozana Mišura1, Ivan Kodrin1, Mladen Borovina1

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Researchers explored creating multicomponent coordination polymers (CPs) using molecular electrostatic potential. This method successfully integrated new co-formers into existing CP structures, retaining key features and forming hydrogen bonds.

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Area of Science:

  • Materials Science
  • Crystallography
  • Supramolecular Chemistry

Background:

  • Coordination polymers (CPs) offer potential for multicomponent materials.
  • Retaining parent CP structural integrity during heteromeric material formation is challenging.

Purpose of the Study:

  • To investigate the use of molecular electrostatic potential (MEP) driven co-crystallization for creating multicomponent coordination polymers.
  • To identify effective co-former design principles for successful integration into CP architectures.

Main Methods:

  • Utilized MEP calculations to evaluate the activation of hydrogen-bond donors in thirteen co-formers.
  • Performed co-crystallization experiments between nine CP families and seven selected co-formers.
  • Structurally characterized successful co-crystalline compounds using X-ray diffraction.

Main Results:

  • Six successful co-crystallizations were achieved out of twenty-one attempts.
  • Four compounds were structurally characterized, confirming the formation of intended hydrogen bonds.
  • MEP analysis correlated with co-former effectiveness, identifying key structural and electrostatic requirements.

Conclusions:

  • Molecular electrostatic potential-driven co-crystallization is a viable strategy for designing multicomponent coordination polymers.
  • Effective co-formers require highly activated hydrogen-bond donors and specific orientations of electron-withdrawing groups.
  • This approach enables the rational design of complex 3D architectures from 1D CP building units.