AI Article Synopsis
- The metal-organic frameworks (MOFs) M(BPZNO) (with M being Co, Cu, Zn) were synthesized and analyzed, showcasing their robust thermal stability, with decomposition temperatures reaching up to 663 K for Zn(BPZNO).
- These MOFs feature unique 3D structures with channels, decorated by polar NO groups, and exhibit specific surface areas between 400 to 900 m²/g, indicating their micro-mesoporous nature.
- Notably, Zn(BPZNO) demonstrates exceptional CO adsorption capacity and selectivity, outperforming existing nitro-functionalized MOFs, with significant insights into the interactions between the framework's C(3)-NO group and carbon dioxide during gas uptake.
Article Abstract
The metal-organic frameworks (MOFs) M(BPZNO ) (M=Co, Cu, Zn; H BPZNO =3-nitro-4,4'-bipyrazole) were prepared through solvothermal routes and were fully investigated in the solid state. They showed good thermal stability both under a N atmosphere and in air, with decomposition temperatures peaking up to 663 K for Zn(BPZNO ). Their crystal structure is characterized by 3D networks with square (M=Co, Zn) or rhombic (M=Cu) channels decorated by polar NO groups. As revealed by N adsorption at 77 K, they are micro-mesoporous materials with BET specific surface areas ranging from 400 to 900 m g . Remarkably, under the mild conditions of 298 K and 1.2 bar, Zn(BPZNO ) adsorbs 21.8 wt % CO (4.95 mmol g ). It shows a Henry CO /N selectivity of 15 and an ideal adsorbed solution theory (IAST) selectivity of 12 at p=1 bar. As a CO adsorbent, this compound is the best-performing MOF to date among those bearing a nitro group as a unique chemical tag. High-resolution powder X-ray diffraction at 298 K and different CO loadings revealed, for the first time in a NO -functionalized MOF, the insurgence of primary host-guest interactions involving the C(3)-NO moiety of the framework and the oxygen atoms of carbon dioxide, as confirmed by Grand Canonical Monte Carlo simulations. This interaction mode is markedly different from that observed in NH -functionalized MOFs, for which the carbon atom of CO is involved.
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