Metal–organic
framework (MOF) thin films have recently attracted
much attention as a new platform for surface/interface research, where
unconventional structural and physical properties emerge. Among the
many MOFs as candidates for fabrication of thin films, Hofmann-type
MOFs {Fe(pz)[M(CN)4]} [pz = pyrazine; M = Ni (Nipz), M = Pt (Ptpz)] are attractive, because they undergo
spin transitions with concomitant structural changes. Here, we demonstrate
the first example of a strain-controlled spin transition in heterostructured
MOF thin films. The spin transition temperature of Ptpz can be controlled in the temperature range of 300–380 K by
fabricating a nanometer-sized heterostructured thin film with a Nipz buffer layer, where the smaller lattice of Nipz causes epitaxial compressive strain to the Ptpz layer.
The fabricated heterostructured thin film exhibited a remarkable increase
in spin transition temperature with a dynamic structural transformation,
confirmed by variable-temperature (VT) X-ray diffraction and VT Raman
spectroscopy. By verifying interfacial strain in a heterostructured
thin film, we can rationally control the characteristics of MOFsnot
only spin transition but also various physical properties such as
gas storage, catalysis, sensing, proton conductivity, and electrical
properties, among others.