To
investigate the ability for spin-state switching of spin-crossover
(SCO) complexes adsorbed to solid substrates, the SCO complex [Fe(H2B(pz)2)2(phenme4)] (pz =
pyrazole, phenme4 = 3,4,7,8-tetramethyl-1,10-phenanthroline)
is prepared. The new complex is investigated by magnetic susceptibility
measurements and Mößbauer spectroscopy in the solid state
and by temperature-dependent UV/vis spectroscopy in a thin film deposited
by physical vapor deposition (PVD) on quartz glass. Thermal- and light-induced
SCO is observed in the bulk and the film on glass. Submonolayers of
this complex obtained by PVD are studied by temperature-dependent
near-edge X-ray absorption fine structure (NEXAFS) on Au(111) as well
as Bi(111) and by scanning tunneling microscopy (STM) on Au(111).
NEXAFS shows thermal- and light-induced spin-state switching of the
complex on Bi(111), however, with a large temperature-independent
high-spin fraction (∼50%). On the other hand, combined evidence
from NEXAFS and STM indicates that on Au(111) the complex dissociates
into [Fe(H2B(pz)2)2] and phenme4. Similar observations are made with the parent complex [Fe(H2B(pz)2)2(phen)], which on Bi(111) stays
intact and exhibits thermal-induced as well as light-induced SCO,
but on Au(111) dissociates into [Fe(H2B(pz)2)2] and phen.
The switching between two spin states makes spin-crossover molecules on surfaces very attractive for potential applications in molecular spintronics. Using scanning tunneling microscopy, the successful deposition of [Fe(pap)] (pap = N-2-pyridylmethylidene-2-hydroxyphenylaminato) molecules on CuN/Cu(100) surface is evidenced. The deposited Fe spin-crossover compound is controllably switched between three different states, each of them exhibiting a characteristic tunneling conductance. The conductance is therefore employed to readily read the state of the molecules. A comparison of the experimental data with the results of density functional theory calculations reveals that all Fe(pap) molecules are initially in their high-spin state. The two other states are compatible with the low-spin state of the molecule but differ with respect to their coupling to the substrate. As a proof of concept, the reversible and selective nature of the switching is used to build a two-molecule memory.
The bistability of spin-crossover complexes on surfaces is of great interest for potential applications. Using x-ray absorption spectroscopy, we investigated the properties of [Fe(pypyr(CF 3) 2) 2 (phen)] (pypyr = 2-(2'-pyridyl)pyrrolide, phen = 1,10-phenanthroline), a vacuum-evaporable Fe(II) complex, in direct contact to a set of substrates. The electronic properties of these substrates range from metallic to semiconducting. While dissociation is observed on metal surfaces, efficient light-induced switching is realized on semimetallic and semiconducting surfaces. This indicates that the density of states of the substrate at the Fermi level plays a role for the integrity and functionality of the adsorbed compound. In an intermediate case, namely [Fe(pypyr(CF 3) 2) 2 (phen)] on graphene/Ni(111), functional and dissociated species are found to coexist. This result indicates that some previous studies may deserve to be reconsidered because the possibility of coexisting intact and fragmented spin-crossover complexes was neglected.
Understanding and controlling the spin-crossover properties of molecular complexes can be of particular interest for potential applications in molecular spintronics. Using near-edge X-ray absorption fine structure spectroscopy, we investigated these properties for a new vacuum-evaporable Fe(II) complex, namely [Fe(pypyr(CF))(phen)] (pypyr = 2-(2'-pyridyl)pyrrolide, phen = 1,10-phenanthroline). We find that the spin-transition temperature, well above room temperature for the bulk compound, is drastically lowered for molecules arranged in thin films. Furthermore, while within the experimentally accessible temperature range (2 K < T < 410 K) the bulk material shows indication of neither light-induced excited spin-state trapping nor soft X-ray-induced excited spin-state trapping, these effects are observed for molecules within thin films up to temperatures around 100 K. Thus, by arranging the molecules into thin films, a nominal low-spin complex is effectively transformed into a spin-crossover complex.
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