Understanding Phonon Properties in Isoreticular Metal-Organic Frameworks from First Principles
Tomas Kamencek, Natalia Bedoya-Mart\'inez, and Egbert Zojer

TL;DR
This study uses quantum-mechanical simulations to analyze phonon properties in isoreticular MOFs, revealing how linker complexity and metal mass influence phonon spectra, group velocities, and anharmonicities, aiding future material design.
Contribution
It provides a comprehensive first-principles analysis of phonon behaviors in MOFs, highlighting the effects of structural variations on vibrational properties.
Findings
Higher linker complexity shifts phonon density to higher frequencies
Increased metal mass lowers phonon frequencies
High group velocities observed in acoustic and optical phonons
Abstract
Metal-organic frameworks (MOFs) are crystalline materials consisting of metal centers and organic linkers forming open and porous structures. They have been extensively studied due to various possible applications exploiting their large amount of internal surface area. Phonon properties of MOFs are, however, still largely unexplored, despite their relevance for thermal and electrical conductivities, thermal expansion, and mechanical properties. Here, we use quantum-mechanical simulations to provide an in-depth analysis of the phonon properties of isoreticular MOFs. We consider phonon band structures, spatial confinements of modes, projected densities of states, and group velocity distributions. We find that more complex linkers shift the spectral weight of the phonon density of states towards higher frequencies, while increasing the mass of the metal atoms in the nodes has the opposite…
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