posted on 2016-06-13, 00:00authored byThais Grancha, Jesús Ferrando-Soria, Joan Cano, Pedro Amorós, Beatriz Seoane, Jorge Gascon, Montse Bazaga-García, Enrique R. Losilla, Aurelio Cabeza, Donatella Armentano, Emilio Pardo
Proton conduction in solids attracts
great interest, not only because
of possible applications in fuel cell technologies, but also because
of the main role of this process in many biological mechanisms. Metal–organic
frameworks (MOFs) can exhibit exceptional proton-conduction performances,
because of the large number of hydrogen-bonded water molecules embedded
in their pores. However, further work remains to be done to elucidate
the real conducting mechanism. Among the different MOF subfamilies, bioMOFs, which have been constructed using biomolecule derivatives
as building blocks and often affording water-stable materials, emerge
as valuable systems to study the transport mechanisms involved in
the proton-hopping dynamics. Herein, we report a versatile chiral
three-dimensional (3D) bioMOF, exhibiting permanent
porosity, as well as high chemical, structural, and water stability.
Moreover, the choice of this suitable bioligand results in proton
conductivity, and allows us to propose a proton-conducting mechanism
based on experimental data, which are displayed visually by means
of quantum molecular dynamics simulations.