posted on 2023-11-21, 07:15authored byGiwook Lee, Jongkook Hwang
Currently,
synthesizing mixed-metal metal–organic
frameworks
(MM-MOFs) in a single step remains a challenge due to the varying
reactivities of different metal cations. This often results in the
formation of mixtures of monometallic MOFs or MM-MOFs with nonstoichiometric
metal ratios. A promising approach to overcoming this issue is the
controlled precursor method, which uses prebuilt polynuclear complexes
with structures similar to the secondary building units (SBUs) of
the desired MOFs. In this study, we report that metal acetates can
serve as natural prebuilt SBUs, enabling the controlled synthesis
of MBDs ([M2(BDC)2DABCO]n, M = metal, BDC = 1,4-benzenedicarboxylic acid,
DABCO = 1,4-diazabicyclo[2,2,2]octane) under ambient conditions. By
exploiting the fact that metal acetates readily form soluble paddle-wheel
dimers similar to the SBUs of MBDs, we achieve the direct synthesis
of mixed-metal MBDs at room temperature. The metal ratios (Zn, Co,
and Ni) in the resulting MBDs are controllable, and the production
yields exceed 90%. The use of metal acetates facilitates the fast
and uniform nucleation of MBDs, regardless of the metal cations involved.
This similarity in nucleation rates leads to the formation of bimetallic
and trimetallic MBDs with predefined metal ratios and homogeneous
metal distribution while maintaining the quality of the MOFs. Importantly,
this strategy offers an efficient pathway for synthesizing mixed metal
MBDs using stoichiometric amounts of metal salts without toxic additives,
high energy consumption, and complex synthesis steps.