@misc{10481/111430,
year = {2026},
month = {2},
url = {https://hdl.handle.net/10481/111430},
abstract = {Crystal facets are intrinsically defective, chemically distinct interfaces whose reactivity critically influences the function of crystalline materials. In reticular porous systems, while internal pore chemistry has been extensively engineered, growing evidence shows that chemical transformations in complex environments increasingly occur at external crystal surfaces. In this minireview, we highlight how crystal facets reactivity can be dictated by surface functionality, particle size, defects density, or crystal morphology. Precise control of these parameters enables deliberate exposure of crystal facets, leading to enhanced crystal surface accessibility and higher reactivity. We further focus on frameworks based on hemi-labile bonds, whose intermediate bond strength enable dynamic yet structurally persistent crystal surfaces. In these materials, surface-confined reactions can initiate self-propagating cascade processes that extend beyond the crystal surface through controlled bond exchange, lattice degradation, and release of reactive species. This behaviour transcends classical surface-limited catalysis and establishes crystal facets as active, information-bearing interfaces. Together, these insights position crystal surface reactivity as a key design parameter for developing functional materials capable of programmed cascade chemistry in catalytic and biological contexts.},
title = {Crystal Facets Reactivity in Metal-Organic Frameworks},
doi = {10.1002/ijch.70018},
author = {Borrego-Marín, Emilio and Rodriguez Navarro, Jorge},
}