Abstract
The topic of noncovalent spin-spin interactions is of increasing general interest in supramolecular radical chemistry. In this report, a series of exo- and endo-TEMPO radical-functionalized metallacycles 1-4 and metallacages 5 and 6 were constructed via coordination-driven self-assembly, wherein the number, location, and distance of the spins were precisely controlled. Their intriguing spin-spin interactions were systematically investigated by electron paramagnetic resonance (EPR) and were well interpreted at the molecular level assisted by X-ray crystallography analysis. The results revealed their distinct spin-spin interactions in the solution state, wherein the spin-spin interaction of metallacycle 3 was much stronger than that of the other five assemblies mainly due to its shorter intramolecular spin-spin distance. In the solid state, 1-6 exhibited obvious spin-spin (dipole-dipole) interactions because of the close arrangement of TEMPO units as indicated in their single crystals. Specifically, a large zero-field splitting (ZFS; D = 17.5 mT) was observed in the crystalline form of metallacycle 4, which arose from the strong intermolecular spin-spin coupling. Interestingly, when the counterion of PF6- in 4 was changed to BF4-, the BF4- counterion analog 4a also exhibited a large ZFS, but the ZFS originated from the intramolecular spin-spin interaction due to a small variation in its crystal conformation. Moreover, the reversible on-off switching of the ZFS in 4 and 4a via the crystal-to-amorphous transformation induced by mechanical grinding and solvent vapor stimuli was also successfully realized. The unique and controllable inter- and intramolecular spin-spin interactions in this work reveal new insights for the understanding and manipulation of spin-spin interactions and may open up a new way to develop organic spin materials in the future.
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