Charge transfer complexes of metal-free phthalocyanine radical anions with decamethylmetallocenium cations: (Cp*2Co+)(H2Pc˙−)·solvent and (Cp*2Cr+)(H2Pc˙−)·4C6H4Cl2†
Abstract
Charge transfer complexes (Cp*2Co+)(H2Pc˙−)·0.5C6H4Cl2·0.7C6H5CN·0.3C6H14 (1) and (Cp*2Cr+)(H2Pc˙−)·4C6H4Cl2 (2) have been obtained as single crystals. Both complexes contain metal-free phthalocyanine (Pc) radical anions and decamethylmetallocenium cations. Reduction of the Pc macrocycle leads to the appearance of new bands at 1026–1030 nm in the NIR range and blue shifts of both Soret and Q-bands of H2Pc in the spectra of 1 and 2. The geometry of the Pc macrocycles supports the formation of H2Pc˙− by the alternation of shorter and longer C–N(imine) bonds in the macrocycles in 2. Complex 1 contains pairs of H2Pc˙− having effective π–π interactions with two sandwiched Cp*2Co+ cations, whereas complex 2 contains stacks composed of alternating Cp*2Cr+ and H2Pc˙− ions. The magnetic moment of 1 is 1.64 μB at 300 K due to the contribution of the H2Pc˙− spins with the S = 1/2 state and diamagnetism of Cp*2Co+. This is supported by the observation of a narrow EPR signal of 1 with g = 2.0032–2.0036 characteristic of H2Pc˙−. Strong antiferromagnetic coupling of spins with a Weiss temperature of −23 K is observed between H2Pc˙− in 1. This coupling is probably mediated by the Cp*2Co+ cations. The magnetic moment of 2 is 4.18 μB at 300 K indicating the contribution of both paramagnetic H2Pc˙− (S = 1/2) and Cp*2Cr+ (S = 3/2) species. In spite of the presence of stacks of alternating ions in 2, only weak magnetic coupling is observed with a Weiss temperature of −4 K most probably due to ineffective π–π interactions between Cp*2Cr+ and H2Pc˙−. The EPR spectrum of 2 contains an asymmetric signal attributed to CrIII (g1 = 3.9059–3.9220) and a narrow Lorentzian signal from H2Pc˙− with g2 = 1.9943–1.9961. In addition to these signals, a broad EPR signal grows in intensity below 80 K with g4 = 2.1085–2.2438 which can be attributed to both paramagnetic Cp*2Cr+ and H2Pc˙− species having exchange interactions.