Synthesis, structure, and magnetic properties of a layered copper molybdate with 3-pyridylnicotinamide coligands

•Synthesis of copper molybdate [CuMoO4(3-pna)]n (3-pna = 3-pyridylnicotinamide).•[CuMoO4]n ribbon motifs with two distinct types of {Cu2Mo2O4} 8-membered rings.•[CuMoO4]n ribbon motifs pillared by 3-pna into 2-D [CuMoO4(3-pna)]n slabs.•First molybdate with 3,5-connected binodal (426)(42678) topology.•Net weak antiferromagnetic coupling within [CuMoO4]n ribbon motifs.

Hydrothermal reaction of copper nitrate, sodium molybdate, and 3-pyridylnicotinamide (3-pna) afforded a polycrystalline sample of [CuMoO4(3-pna)]n (1), which was structurally characterized by single-crystal X-ray diffraction. Compound 1 manifests [CuMoO4]n ribbon motifs that contain two distinct types of {Cu2Mo2O4} 8-membered rings. Parallel [CuMoO4]n ribbon motifs are pillared into 2-D [CuMoO4(3-pna)]n coordination polymer slabs by dipodal anti conformation 3-pna tethers. These possess a 3,5-connected binodal (426)(42678) topology, representing the first time this topology has been observed in metal oxide chemistry. Net weak antiferromagnetic coupling was observed within the 1-D [CuMoO4]n ribbons, with g = 1.99(2) and J = −0.45(14) cm−1.

Graphical abstract[CuMoO4(3-pna)]n (1,3-pna = 3-pyridylnicotinamide) shows ribbon motifs pillared into 2-D [CuMoO4(3-pna)]n coordination polymer slabs by 3-pna tethers. The layers have a 3,5-connected binodal (426)(42678) topology. Net weak antiferromagnetic coupling was observed within the ribbon motifs.Figure optionsDownload full-size imageDownload as PowerPoint slide