Spin-crossover materials: Getting the most from x-ray crystallography

Abstract: The physical phenomenon of spin crossover in molecular crystals is a multiscale process whose properties rely on the supramolecular organization of the spin crossover active elements, their interactions within the crystal packing and their dynamics. The delicate balance between short-range and long-range structural reorganization upon the spin transition is at the origin of remarkable and fascinating physical phenomena such as thermal, light induced and pressure induced hysteresis, multistep transitions and mu… Show more

“…The elasticity law for the nontransforming polymer matrix is where σ, e, and C are stress, strain, and the stiffness matrices, respectively. The elasticity law for the transforming SCO particles before and after transformation is = C e p p p (8) = C e e ( ) p p p p T (9) where e p T is the homogeneous particle transformation strain. The subscripts m and p denote matrix and particles, respectively.…”

Dynamical Mechanical Analysis and Micromechanics Simulations of Spin-Crossover@Polymer Particulate Composites: Toward Soft Actuator Devices

“…The elasticity law for the nontransforming polymer matrix is where σ, e, and C are stress, strain, and the stiffness matrices, respectively. The elasticity law for the transforming SCO particles before and after transformation is = C e p p p (8) = C e e ( ) p p p p T (9) where e p T is the homogeneous particle transformation strain. The subscripts m and p denote matrix and particles, respectively.…”

Dynamical Mechanical Analysis and Micromechanics Simulations of Spin-Crossover@Polymer Particulate Composites: Toward Soft Actuator Devices

“…The configuration of the pyrazine rings has important consequences for the most characteristic feature of this material: the spin-crossover transition. It is not unusual to observe order-disorder processes coupled to SCO, 39,40 in most cases related to counterions or solvent molecules present in the structure, 41,42 and more rarely to ligands. 43,44 An order-disorder process can affect the spin transition in several ways, including the temperature of the transition and its abruptness (and hysteresis), and this has been taken into account in theoretical models of the spin transition.…”

Hidden ordered structure in the archetypical Fe(pyrazine)[Pt(CN)₄] spin-crossover porous coordination compound

“…Spin crossover (SCO) complexes present different magnetic, optical, electrical, and structural properties depending on the electronic configuration that can switch from the low spin (LS) to the high spin (HS) state and vice versa by changes of the temperature, pressure, , and magnetic fields, and also by light irradiation , and hard X-ray excitation . This spin transition can therefore be followed by different experimental techniques according to the changes that occur: magnetic susceptibility measurements, Mössbauer spectroscopy, UV–vis–NIR absorption and vibrational spectroscopy, X-ray diffraction, synchrotron radiation studies, heat capacity measurements, nuclear magnetic resonance, etc. As shown in Figure , the electronic configuration change between the LS and the HS state is for instance generally associated with a visually detectable color change.…”

Spin Crossover Nanoparticles