TY - DATA T1 - Effect of the Substitution Pattern (Peripheral vs Non-Peripheral) on the Spectroscopic, Electrochemical, and Magnetic Properties of Octahexylsulfanyl Copper Phthalocyanines PY - 2018/05/16 AU - Tulin Ateş Turkmen AU - Lihan Zeng AU - Yan Cui AU - İsmail Fidan AU - Fabienne Dumoulin AU - Catherine Hirel AU - Yunus Zorlu AU - Vefa Ahsen AU - Alexander A. Chernonosov AU - Yurii Chumakov AU - Karl M. Kadish AU - Ayşe Gül Gürek AU - Sibel Tokdemir Öztürk UR - https://acs.figshare.com/articles/journal_contribution/Effect_of_the_Substitution_Pattern_Peripheral_vs_Non-Peripheral_on_the_Spectroscopic_Electrochemical_and_Magnetic_Properties_of_Octahexylsulfanyl_Copper_Phthalocyanines/6275573 DO - 10.1021/acs.inorgchem.8b00528.s001 L4 - https://ndownloader.figshare.com/files/11472662 KW - g values KW - Cu-P KW - Octahexylsulfanyl Copper Phthalocyanines KW - Peripheral vs Non-Peripheral KW - HOMO KW - Cu-NP KW - copper phthalocyanines KW - substitution position effect KW - ESR KW - moment KW - room temperature N2 - In order to investigate the substitution position effect on the spectroscopic, electrochemical, and magnetic properties of copper phthalocyanines, a detailed structure–property analysis has been performed by examining two copper phthalocyanines that are octasubstituted by hexylsulfanyl chains respectively in the peripheral (Cu-P) and non-peripheral (Cu-NP) positions. Cu-NP showed a marked near-IR maximum absorption compared to Cu-P and, accordingly, a smaller HOMO–LUMO energy gap, calculated via the electrochemical results and simulations in the gas phase, as well as for Cu-NP from its crystallographic data. An electron-spin resonance (ESR) technique is used to extract the g values from the powder spectra that are taken at room temperature. The g values were determined to be g∥ = 2.160 and g⊥ = 2.045 for Cu-P and g∥ = 2.150 and g⊥ = 2.050 for Cu-NP. These values indicate that the paramagnetic copper center in both phthalocyanines has axial symmetry with a planar anisotropy (g∥ > g⊥). The ESR spectra in solution could be obtained only for Cu-P. Curie law is used to fit the experimental data of the magnetic susceptibility versus temperature graphs, and the Curie constant (C) and diamagnetic/temperature-independent paramagnetic (α) contributions are deduced as 0.37598 (0.39576) cm3·K/mol and −23 × 10–5 (25 × 10–5) cm3/mol respectively for Cu-P and Cu-NP. The room temperature magnetic moment value (1.70 μB) is close to the spin-only value (1.73 μB) for the peripheral complex, showing that there is no orbital contribution to μeff. In contrast, at room temperature, the value of the magnetic moment (1.77 μB) is above the spin-only value, showing an orbital contribution to the magnetic moment. Cu-NP’s room temperature magnetic moment value is larger than the value for Cu-P, demonstrating that the orbital contribution to the magnetic moment depends upon the substituent position. The magnitudes of the effective magnetic moment values also support that both Cu-P and Cu-NP complexes have square-planar coordination. This result is consistent with the determined g values. The spin densities were determined experimentally, and the results suggest that the positions of the substituents affect these values (0.469 for Cu-P and 0.490 for Cu-NP). ER -