posted on 2019-10-09, 16:04authored byHyojin Kim, Hwa Young Lee, Dong Won Kang, Minjung Kang, Jong Hyeak Choe, Woo Ram Lee, Chang Seop Hong
While
mixed-metal ions into a single framework can be randomly arranged
in most reported cases, it is synthetically challenging to control
and organize the distribution of different metal ions over a three-dimensional
structure. In this context, for the family of M2(dobpdc)
with broad applications, we present the first case of a bimetallic
Mg/Zn(dobpdc) framework with a 1:1 compositional ratio, based on a
one-dimensional Zn(H2dobpdc) template, which would not
be obtained by the conventional reaction of the corresponding metal
salts. Moreover, we demonstrate that the resultant compositional ratios
in the bimetallic M′/Zn(dobpdc) (M′ = Mg, Mn, Co, Ni)
are governed by the ionic radii of the metals and the affinity of
the metal ions for the linker groups. Notably, the unexpected gradual
reduction in the adsorption enthalpy and the mixed CO2 adsorption
feature are revealed in Mg/Zn(dobpdc) and its diamine-grafted framework,
respectively.