posted on 2020-12-11, 19:40authored byValentina Martinez, Bahar Karadeniz, Nikola Biliškov, Ivor Lončarić, Senada Muratović, Dijana Žilić, Stanislav M. Avdoshenko, Maria Roslova, Alexey A. Popov, Krunoslav Užarević
Encapsulation and confinement of
fullerene guests in metal-organic
frameworks (MOFs) lead to a novel class of crystalline fulleretic
materials with unique physicochemical properties and a broad field
of potential applications. The control over the amount of target guests
confined in the MOF structure remains a significant challenge, which
is particularly pronounced in the confinement of hardly accessible
fullerene derivatives. The main strategies used in constructing fulleretic
composites are limited by the solubility of components used and solvent
versus guest competition for inhabitation of the framework voids.
As mechanochemical procedures often overcome these issues, we developed
here solvent-free processing by ball milling to gain control over
the encapsulation of bulky and rigid C60-fullerene into
a sodalite MOF with large cages and narrow cage-apertures. A rapid,
green, efficient, and stoichiometry-controlled mechanochemical processing
afforded four model C60@zeolitic-imidazolate framework
8 (ZIF-8) crystalline materials containing target 15, 30, 60, and
100 mol % of fullerene entrapped in the accessible cages of the model
sodalite zeolitic-imidazolate framework 8 (ZIF-8), in stark contrast
to the solution-based strategies that resulted in almost no loading.
Varying the fullerene content affects the framework’s vibrational
properties, color and luminescence of the composites, and the electron-dose
radiation stability. The computational and spectroscopic studies show
that the fullerene is accommodated in the cage’s center and
that the cage-to-cage transport is a hardly feasible and energetically
unfavored process. However, the fast release of C60 molecules
from ZIF-8 can be effectively controlled by the pH. The entrapment
of fullerene molecules in ZIF-8 resulted in their effective isolation
even in higher loadings, paving the way to other tunable porous fulleretics
containing single-molecule magnets or nanoprobes available on low
scales.