Metal–organic
frameworks (MOFs) are versatile platforms to design switchable and
sensory materials responsive to external stimulus. Copuling the electron-deficient
bipyridinium chromorphore with the pore structures of MOFs is a nice
strategy to design multiresponsive MOFs. Here we present a proof-of-concept
study. Postsynthetic N,N′-cycloalkylation
of UiO-67-bpy (bpy = 2,2′-bipyridyl) leads to a novel ionic
MOF (UiO-67-DQ) functionalized by the electron-deficient diquat (DQ)
chromophore. The combination of porosity, cationic character and electron
deficiency imparts UiO-67-DQ with versatile responsive properties.
It readily undergoes anion exchange, with selective ionochromism associated
with charge-transfer (CT) complexation; it is electrochemically active
and shows anion-dependent photochromism associated with radical formation
through electron transfer (ET); the iono- and photochromism cause
efficient luminescence quenching because of energy transfer (EnT)
to CT complexes or radicals. The properties of UiO-67-MQ (MQ = N,N′-dimethyl-2,2′-bipyridylium)
are also presented for comparison. The CT and ET effects and consequently
the EnT efficiency in UiO-67-MQ are weaker than those in UiO-67-DQ
because the electron-deficient character is weakened by the severe
interannular twist in MQ2+. On the basis of the rich responsive
properties, the MOFs are used as sensory and switching materials for
facile discrimination of a range of anions, for quantitative detection
of I–, and for mimicking of logic operations ranging
from simple logic gates to complex integrated logic circuits.