Change in reaction pathway of nickel(II) complex induced by magnetic fields

Three identical hydrothermal self-assembly reactions in a mixture of nickel nitrate hexahydrate, nicotinic acid, sodium azide were carried out with the applied magnetic fields of 0, 0.15, 0.3 T, respectively. It was found that [Ni1.5(N3)(nic)2(Hnic)]n can be obtained at 160 °C for 48 h without an applied magnetic field, while the final product totally changed into [Ni2(nic)4(H2O)] as a 0.3 T weak magnetic field was employed in the reaction. Both of the two products show three-dimensional frameworks, however, they display two different coordination geometries with different ligands. We consider the mechanism base on changes of magnetic susceptibilities and structures of [Ni2(nic)4(H2O)], and propose a view that the magnetic field can reduce the activation energy of reaction pathways according to transition state theory. The possible reason of the decrease of activation energy is that a magnetic field can mediate coupling among the Ni2+ ions during the formation of [Ni2(nic)4(H2O)], which is indicated by the slight changes of microstructure of crystal, such as bond angle and length.

► An interesting phenomenon that the magnetic field can change reaction directions of molecule-based magnets has been found. ► The strength of magnetic field could influence the final product. ► The possible reason has been well explained based on the magnetic susceptibilities and structures of molecule-based magnets.