Version 2 2024-11-08, 19:04Version 2 2024-11-08, 19:04
Version 1 2024-11-01, 11:34Version 1 2024-11-01, 11:34
journal contribution
posted on 2024-11-08, 19:04authored byMario Fratschko, Tonghan Zhao, Jan C. Fischer, Oliver Werzer, Fabian Gasser, Ian A. Howard, Roland Resel
Understanding the
structure of thin films is essential for successful
applications of metal–organic frameworks (MOFs), such as low
k-dielectrics in electronic devices. This study focuses on the thin
film formation of the 3D nanoporous MOF Cu2(bdc)2(dabco). The thin films are prepared by a layer-by-layer technique
with varying deposition cycles (1 to 50). Thin film morphologies and
crystallographic properties were investigated using atomic force microscopy
(AFM), Fourier transform infrared (FTIR) spectroscopy, and grazing-incidence
X-ray diffraction (GIXD). AFM revealed an island growth (Volmer–Weber)
with plate-like shaped islands. FTIR and GIXD revealed that Cu2(bdc)2(dabco) crystals form already during the
first preparation cycle. The heights of the islands do not increase
linearly with the number of deposition cycles, suggesting multiple
growth stages. X-ray diffraction pole figures uncover a uniplanar
texture of the Cu2(bdc)2(dabco) crystals, together
with randomly oriented crystallites. The fraction of uniplanar oriented
crystals increases with each deposition cycle, reaching a maximum
of 75% at ten deposition cycles, simultaneously achieving complete
substrate coverage. However, already at five cycles, an additional
phase of randomly oriented copper-terephthalate (Cu2(bdc))
crystals appeared; this phase reaches a fraction of 22% at the largest
film thickness (50 cycles). In summary, a detailed understanding of
the thin film formation of an archetypal layer-pillar MOF is presented,
elucidating how films grow in terms of their morphology and crystalline
properties. Samples prepared by ten cycles show complete coverage
of the substrate together with the highest degree of preferred crystal
orientation. These results establish a deepened understanding of critical
parameters for MOF thin film applications, such as complete substrate
coverage and definition of the nanopores relative to the substrate
surface.