Tuning of Exchange Coupling and Switchable Magnetization Dynamics by Displacing the Bridging Ligands Observed in Two Dimeric Manganese(III) Compounds

Two Mn(III)-based dimers, [Mn(2)(bpad)(2)(CH(3)O)(4)](n) (1) and [Mn(2)(bpad)(2)(pa)(2)](n)·2H(2)O (2) (Hbpad = N(3)-benzoylpyridine-2-carboxamidrazone, H(2)pa = phthalic acid), have been assembled from a tridentate Schiff-base chelator and various anionic coligands. Noteworthily, compound 1 could be identified as a reaction precursor to transform to 2 in the presence of phthalic acid, resulting in a rarely structural conversion process in which the bridges between intradimer Mn(III) ions alter from methanol oxygen atom with μ(2)-O mode in 1 (Mn [Image: see text] Mn distance of 3.046 Å) to syn-anti carboxylate in 2 (Mn [Image: see text] Mn distance of 4.043 Å), while the Mn(III) centers retain hexa-coordinated geometries with independently distorted octahedrons in two compounds. The dc magnetic determinations reveal that ferromagnetic coupling between two metal centers with J = 1.31 cm(−1) exists in 1, whereas 2 displays weak antiferromagnetic interactions with the coupling constant J of −0.56 cm(−1). Frequency-dependent ac susceptibilities in the absence of dc field for 1 suggest slow relaxation of the magnetization with an energy barrier of 13.9 K, signifying that 1 features single-molecule magnet (SMM) behavior. This work presents a rational strategy to fine-tune the magnetic interactions and further magnetization dynamics of the Mn(III)-containing dinuclear units through small structural variations driven by the ingenious chemistry.