Metal–organic frameworks (MOFs)
are emerging as sustainable
reagents and catalysts with promising applications in synthetic chemistry.
Although the hydrothermal stabilities of MOFs have been well studied,
their robustness toward various reagents, including acids, bases,
nucleophiles, electrophiles, oxidants, and reductants, remains poorly
characterized. As such, heterogeneous platforms for promising catalysts
are generally identified on an ad hoc basis and have
largely been limited to carboxylate frameworks to date. To address
these limitations, here we systematically characterize the robustness
of 17 representative carboxylate, salicylate, and azolate MOFs toward
30 conditions representing the scope of synthetic organic chemistry.
Specifically, analysis of the full width at half-maximum of powder
X-ray diffraction patterns, as well as infrared spectroscopy, 77 K
N2 adsorption measurements, and scanning electron microscopy
in select cases are employed to appraise framework degradation and
dissolution under a range of representative conditions. Our studies
demonstrate that azolate MOFs, such as Fe2(bdp)3 (bdp2– = 4,4′-(1,4-phenylene)bis(pyrazolate)),
generally possess excellent chemical stabilities under myriad conditions.
In addition, we find that carboxylate and salicylate frameworks possess
complementary stabilities, with carboxylate MOFs possessing superior
robustness toward acids, electrophiles, and oxidants, and salicylate
MOFs demonstrating improved robustness toward bases, nucleophiles,
and reductants. The guidelines provided herein should facilitate the
rational design of robust frameworks for applications in synthetic
chemistry and guide the development of new strategies for the postsynthetic
modification of MOFs as well.
