Photoinduced Long-Range Magnetic Ordering of a Cobalt−Iron Cyanide

Abstract

Two kinds of cobalt−iron cyanides (Rb_0.66Co_1.25[Fe(CN)₆]·4.3H₂O and Co_1.5[Fe(CN)₆]·6H₂O) with different electronic structures have been investigated to understand the photoinduced long-range magnetic ordering. Rb_0.66Co_1.25[Fe(CN)₆]·4.3H₂O produces a photomagnetic effect, whereas Co_1.5[Fe(CN)₆]·6H₂O does not respond to light. FT-IR and Mössbauer studies revealed that their oxidation states are expressed as Rb_0.66Co^III_0.84Co^II_0.41[Fe^II(CN)₆] and Co^II_1.5[Fe^III(CN)₆], respectively. The difference in the oxidation states of the metal atoms in these two compounds has been explained by the Co coordination with H₂O or CN ligands. In the case of Rb_0.66Co_1.25[Fe(CN)₆]·4.3H₂O, more CN ligands are involved in coordination than expected in the case of Co_1.5[Fe(CN)₆]·6H₂O. A charge-transfer (CT) band from Fe^II to Co^III is observed at around 550 nm for Rb_0.66Co_1.25[Fe(CN)₆]·4.3H₂O. The magnetism of Rb_0.66Co_1.25[Fe(CN)₆]·4.3H₂O changed from paramagnetic to ferrimagnetic due to the CT from Fe^II to Co^III when illuminated at low temperature. The Curie temperature after illumination was 22 K. This metastable state was stable for more than several days at 5 K. The metastable state was restored back to its original one when the sample was heated to 120 K. It is considered that the interconversion proceeded via a pronounced domain formation.