posted on 2018-11-07, 15:48authored byC. Michael McGuirk, Tomče Runčevski, Julia Oktawiec, Ari Turkiewicz, Mercedes K. Taylor, Jeffrey R. Long
Metal–organic
frameworks that display step-shaped adsorption
profiles arising from discrete pressure-induced phase changes are
promising materials for applications in both high-capacity gas storage
and energy-efficient gas separations. The thorough investigation of
such materials through chemical diversification, gas adsorption measurements,
and in situ structural characterization is therefore
crucial for broadening their utility. We examine a series of isoreticular,
flexible zeolitic imidazolate frameworks (ZIFs) of the type M(bim)2 (SOD; M = Zn (ZIF-7), Co (ZIF-9), Cd (CdIF-13); bim– = benzimidazolate), and elucidate the effects of metal
substitution on the pressure-responsive phase changes and the resulting
CO2 and CH4 step positions, pre-step uptakes,
and step capacities. Using ZIF-7 as a benchmark, we reexamine the
poorly understood structural transition responsible for its adsorption
steps and, through high-pressure adsorption measurements, verify that
it displays a step in its CH4 adsorption isotherms. The
ZIF-9 material is shown to undergo an analogous phase change, yielding
adsorption steps for CO2 and CH4 with similar
profiles and capacities to ZIF-7, but with shifted threshold pressures.
Further, the Cd2+ analogue CdIF-13 is reported here for
the first time, and shown to display adsorption behavior distinct
from both ZIF-7 and ZIF-9, with negligible pre-step adsorption, a
∼50% increase in CO2 and CH4 capacity,
and dramatically higher threshold adsorption pressures. Remarkably,
a single-crystal-to-single-crystal phase change to a pore-gated phase
is also achieved with CdIF-13, providing insight into the phase change
that yields step-shaped adsorption in these flexible ZIFs. Finally,
we show that the endothermic phase change of these frameworks provides
intrinsic heat management during gas adsorption.