Electronic properties of the dimerized organic conductor -(BETS)2Mn[N(CN)2]3

Abstract

The two-dimensional molecular conductor -(BETS)2Mn[N(CN)2]3 undergoes a sharp metal-to-insulator phase transition at T MI≈ 21 K, which has been under scrutiny for many years. We have performed comprehensive infrared investigations along the three crystallographic directions as a function of temperature down to 10 K, complemented by electron spin resonance and dc-transport studies. The in-plane anisotropy of the optical conductivity is more pronounced than in any other -type BEDT-TTF or related compounds. The metal-insulator transitions affects the molecular vibrations due to the coupling to the electronic system; in addition we observe a clear splitting of the charge-sensitive vibrational modes below T MI that evidences the presence of two distinct BETS dimers in this compound. The Mn[N(CN)2]3- layers are determined by the chain structure of the anions resulting in a rather anisotropic behavior and remarkable temperature dependence of the vibronic features. At low temperatures the ESR properties are affected by the Mn2+ ions via π-d-coupling and antiferromagnetic ordering within the π-spins: The g-factor shifts enormously with a pronounced in-plane anisotropy that flips as the temperature decreases; the lines broaden significantly; and the spin susceptibility increases upon cooling with a kink at the phase transition.