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Pathway selection as a tool for crystal defect engineering: A case study with a functional coordination polymer

2020; Elsevier BV; Volume: 20; Linguagem: Inglês

10.1016/j.apmt.2020.100632

2352-9415

Afshin Abrishamkar, Salvio Suárez‐García, Semih Sevim, Alessandro Sorrenti, Ramón Pons, Shi‐Xia Liu, Silvio Decurtins, Guillem Aromı́, David Aguilà, Salvador Pané, Andrew J. deMello, Aurelian Rotaru, Daniel Ruiz‐Molina, Josep Puigmartí‐Luis,

Organic and Molecular Conductors Research

New synthetic routes capable of achieving defect engineering of functional crystals through well-controlled pathway selection will spark new breakthroughs and advances towards unprecedented and unique functional materials and devices. In nature, the interplay of chemical reactions with the diffusion of reagents in space and time is already used to favor such pathway selection and trigger the formation of materials with bespoke properties and functions, even when the material composition is preserved. Following this approach, herein we show that a controlled interplay of a coordination reaction with mass transport (i.e. the diffusion of reagents) is essential to favor the generation of charge imbalance defects (i.e. protonation defects) in a final crystal structure (thermodynamic product). We show that this synthetic pathway is achieved with the isolation of a kinetic product (i.e. a metastable state), which can be only accomplished when a controlled interplay of the reaction with mass transport is satisfied. Accounting for the relevance of controlling, tuning and understanding structure-properties correlations, we have studied the spin transition evolution of a well-defined spin-crossover complex as a model system.