A Combined Synthetic, Magnetic, and Theoretical Study on Enhancing Ligand-Field Axiality for Dy(III) Single-Molecule Magnets Supported by Ferrocene Diamide Ligands
Kexin Yang, Rong Sun, Jingliang Zhao, Chong Deng, Bing‐Wu Wang, Song Gao, Wenliang Huang
Abstract
Molecular design is crucial for improving the performance of single-molecule magnets (SMMs). For dysprosium(III) SMMs, enhancing ligand-field axiality is a well-suited strategy to achieve high-performance SMMs. We synthesized a series of dysprosium(III) complexes, (NN TIPS )DyBr(THF) 2 ( 1, NN TIPS = fc(NSi i Pr 3 ) 2; fc = 1,1′-ferrocenediyl, THF = tetrahydrofuran), [(NN TIPS )Dy(THF) 3 ][BPh 4 ] ( 2 ), (NN TIPS )DyI(THF) 2 ( 3 ), and [(NN TBS )Dy(THF) 3 ][BPh 4 ] ( 4, NN TBS = fc(NSi t BuMe 2 ) 2 ), supported by ferrocene diamide ligands. X-ray crystallography shows that the rigid ferrocene backbone enforces a nearly axial ligand field with weakly coordinating equatorial ligands. Dysprosium(III) complexes 1 – 4 all exhibit slow magnetic relaxation under zero fields and possess high effective barriers ( U eff ) around 1000 K, comparable to previously reported (NN TBS )DyI(THF) 2 ( 5 ). We probed the influences of structural variations on SMM behaviors by theoretical calculations and found that the distribution of negative charges defined by r q, i.e., the ratio of the charges on the axial ligands to the charges on the equatorial ligands, plays a decisive role. Moreover, theoretical calculations on a series of model complexes 1′ – 5′ without equatorial ligands unveil that the axial crystal-field parameters B 2 0 are directly proportional to the N–Dy–N angles and support the hypothesis that enhancing the ligand-field axiality could improve SMM performance.