posted on 2017-12-18, 18:53authored bySven M.
J. Rogge, Michel Waroquier, Veronique Van Speybroeck
ConspectusOver the
past two decades, metal–organic frameworks (MOFs)
have matured from interesting academic peculiarities toward a continuously
expanding class of hybrid, nanoporous materials tuned for targeted
technological applications such as gas storage and heterogeneous catalysis.
These oft-times crystalline materials, composed of inorganic moieties
interconnected by organic ligands, can be endowed with desired structural
and chemical features by judiciously functionalizing or substituting
these building blocks. As a result of this reticular synthesis, MOF
research is situated at the intriguing intersection between chemistry
and physics, and the building block approach could pave the way toward
the construction of an almost infinite number of possible crystalline
structures, provided that they exhibit stability under the desired
operational conditions. However, this enormous potential is largely
untapped to date, as MOFs have not yet found a major breakthrough
in technological applications. One of the remaining challenges for
this scale-up is the densification of MOF powders, which is generally
achieved by subjecting the material to a pressurization step. However,
application of an external pressure may substantially alter the chemical
and physical properties of the material. A reliable theoretical guidance
that can presynthetically identify the most stable materials could
help overcome this technological challenge.In this Account,
we describe the recent research the progress on
computational characterization of the mechanical stability of MOFs.
So far, three complementary approaches have been proposed, focusing
on different aspects of mechanical stability: (i) the Born stability
criteria, (ii) the anisotropy in mechanical moduli such as the Young
and shear moduli, and (iii) the pressure-versus-volume equations of
state. As these three methods are grounded in distinct computational
approaches, it is expected that their accuracy and efficiency will
vary. To date, however, it is unclear which set of properties are
suited and reliable for a given application, as a comprehensive comparison
for a broad variety of MOFs is absent, impeding the widespread use
of these theoretical frameworks.Herein, we fill this gap by
critically assessing the performance
of the three computational models on a broad set of MOFs that are
representative for current applications. These materials encompass
the mechanically rigid UiO-66(Zr) and MOF-5(Zn) as well as the flexible
MIL-47(V) and MIL-53(Al), which undergo pressure-induced phase transitions.
It is observed that the Born stability criteria and pressure-versus-volume
equations of state give complementary insight into the macroscopic
and microscopic origins of instability, respectively. However, interpretation
of the Born stability criteria becomes increasingly difficult when
less symmetric materials are considered. Moreover, pressure fluctuations
during the simulations hamper their accuracy for flexible materials.
In contrast, the pressure-versus-volume equations of state are determined
in a thermodynamic ensemble specifically targeted to mitigate the
effects of these instantaneous fluctuations, yielding more accurate
results. The critical Account presented here paves the way toward
a solid computational framework for an extensive presynthetic screening
of MOFs to select those that are mechanically stable and can be postsynthetically
densified before their use in targeted applications.