A model for high-spin/low-spin transitions in solids including the effect of lattice vibrations

Theeffect oflow pressure @= 150 bar) on the high-spin (HS)-lowrpin (LS) transition in [Fe\_,Znl\_\_~(2-pic)~] Cl,-E1OH (x = OS, 1.0) was measured by Mkbauer spectroscopy and the results compared with theory. The linear dependence of the volume of the lattice on the HS fraction, which is the basic as

A series of the d 6 iron(I1) complexes with bulky organic ligands (like [ Fe(bzpy),(NCS),]) can exist in two spin forms: in the low-spin ( S = 0) form at low temperature and in the high-spin ( S = 2) form at high temperature. In the crystal phase, the transition between these two forms may be either

The transition temperature of [Fe@hen)z(NCS)z ] measured by susceptibility measurements in an applied tield of 1 T shifts by -0.11 f 0.04 K when the field is increased to 55 T. This shift is predicted on the basis of the known magnetic susceptibility and specific heat data.

Based on measurements of differential scanning calorimetry, the first-order character of the spin-state transition in Fe(bt),(NCS), is established (bt = 2,2'-bi-2-thiazoline). The transition arises at T, ' =180.9 K and T,l =171.2 K, and is characterized by AH = 9.55 kO.7 kJ mol-' and AS = 54.5 \*4 J

The water -biopolymer cross-relaxation model, proposed by cies; accordingly, the theory in its original form cannot ex-H. E. Rorschach and C. F. Hazlewood (RH) [J. Magn. Reson. plain the low-frequency dependence of T 1 . In this paper, 70, 79 (1986)], explains the Larmor frequency dependence of T 1