6533b7dafe1ef96bd126e1af
RESEARCH PRODUCT
Exploiting Reaction-Diffusion Conditions to Trigger Pathway Complexity in the Growth of a MOF.
Afshin AbrishamkarMauro SattaNéstor Calvo GalveMarco D'abramoAlessandro SorrentiAlessandro SorrentiEugenio CoronadoGuillermo Mínguez EspallargasLorenzo Di RienzoJosep Puigmartí-luisJosep Puigmartí-luisAndrew J. De Mellosubject
Materials sciencePolymersCrystallization; Metal–organic frameworks; microfluidic technologies; pathway complexity; Reaction-diffusion conditionsMicrofluidicsMicrofluidicsCrystal growth010402 general chemistrypathway complexity01 natural sciencesCatalysislaw.inventionMolecular dynamicslawCristal·litzacióCrystallizationMaterialsMixing (physics)Metal–organic frameworks010405 organic chemistryGeneral MedicineGeneral ChemistryMicrofluídica0104 chemical sciencesPolímersmicrofluidic technologiesChemical physicsParticleMetal-organic frameworkCristallsPorous mediumCrystallizationcrystallization; metal–organic frameworks; microfluidic technologies; pathway complexity; reaction-diffusion conditionsReaction-diffusion conditionsdescription
Coordination polymers (CPs), including metal–organic frameworks (MOFs), are crystalline materials with promising applications in electronics, magnetism, catalysis, and gas storage/separation. However, the mechanisms and pathways underlying their formation remain largely undisclosed. Herein, we demonstrate that diffusion-controlled mixing of reagents at the very early stages of the crystallization process (i.e., within ≈40 ms), achieved by using continuous-flow microfluidic devices, can be used to enable novel crystallization pathways of a prototypical spin-crossover MOF towards its thermodynamic product. In particular, two distinct and unprecedented nucleation-growth pathways were experimentally observed when crystallization was triggered under microfluidic mixing. Full-atom molecular dynamics simulations also confirm the occurrence of these two distinct pathways during crystal growth. In sharp contrast, a crystallization by particle attachment was observed under bulk (turbulent) mixing. These unprecedented results provide a sound basis for understanding the growth of CPs and open up new avenues for the engineering of porous materials by using out-of-equilibrium conditions.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-05-19 | Angewandte Chemie (International ed. in English) |