posted on 2024-10-04, 16:40authored byDylan
A. Sherman, Erik Landberg, Anjana Ramesh Peringath, Sohini Kar-Narayan, Jin-Chong Tan
Fabrication of metal–organic framework (MOF) thin
films
is an ongoing challenge to achieve effective device integration. Inkjet
printing has been employed to print various luminescent metal–organic
framework (MOF) films. Luminescent metal–organic nanosheets
(LMONs), nanometer-thin particles of MOF materials with comparatively
large micrometer lateral dimensions, provide an ideal morphology that
offers enhancements over analogous MOFs in luminescent properties
such as intensity and photoluminescent quantum yield. The morphology
is also better suited to the formation of thin films. This work harnesses
the preferential features of LMONs to access the advanced technique
of aerosol-jet printing (AJP) to print luminescent films with precise
geometries and patterns across the micrometer and centimeter length
scales. AJP of LMONs exhibiting red (R), green (G), and blue (B) emission
were studied systematically to reveal the increase of luminescence
upon additive layering printing until a threshold was reached limited
by self-quenching. By combining different LMON emitters, emission
chromaticity and intensity were shown to be tunable, including the
combination of RGB emitters to fabricate white-light-emitting films.
A white-light LMON film was printed onto a UV light emitting diode
(LED), producing a working white-light-emitting diode. Printing with
multiple distinct photoluminescent inks produced intricate multicolor
patterns that dynamically responded to excitation wavelength, acting
either as micrometer-scale LED-type cells or larger visual tags. Collectively,
the work offers an advancement for MOF thin films by printing MON
materials using AJP, offering a precise method for manufacturing a
wide range of critical functional devices, from luminescent sensors
to optoelectronics, and more broadly even the opportunity for printed
circuitry with conductive MONs.