Crystal engineering and solid state chemistry of some β-nitrostyrenes

Abstract

The unusual solid state photodimerisation of (E)-β-nitrostyrene to yield ‘topochemical’ and ‘non-topochemical’ cyclobutanes is accounted for by its disordered, photoreactive crystal structure which is monoclinic, P21/c, Z= 4, a= 8.097(6)A, b= 5.768(5)A, c= 18.647(2)A, β= 117.71(5)°. This structure permits a trans→cis isomerisation which facilitates the formation of the anomalous product. However, 4-methyl-β-nitrostyrene which has a very similar disordered structure is photostable in the solid state since the potentially ‘reactive’ double bonds are beyond the topochemical threshold. C–H ⋯ O and C–H ⋯ Cl interactions are important to the exclusion of Cl ⋯ Cl interactions in the layered structure of the 4-chloro derivative, but this nitrostyrene forms mixed crystals with the 4-methyl compound in the disordered structure of the latter showing that the role of the Cl atom in the 4-chloro derivative is at best marginal. In contrast, the higher Cl stoichiometry in the 2,4-dichloro analogue results in a layered, photoreactive β-structure characterised by Cl ⋯ Cl and C–H ⋯ O interactions. The structures of three layered alkoxy-β-nitrostyrenes are very similar to each other and are held by strong, directional C–H ⋯ O contacts. The 4-methoxy compound has a photostable crystal structure while the 3,4-methylenedioxy and 3,4-dimethoxy crystals appear to be capable of topochemical 2 + 2 cycloaddition. However, only the latter is photoreactive because of optimal double-bond-to-double-bond overlap in the crystal. The 4-bromo derivative is distinct from the 4-chloro compound and there are two molecules in the asymmetric unit because of conflicting packing requirements of the C–H ⋯ O and Br ⋯ O interactions. A survey of 84 intermolecular Br ⋯ O contacts retrieved from 39 nitro-bromo crystal structures has revealed that at least some of these arise due to halogen polarisability. Atomic motion analysis in this crystal structure indicates the importance of lateral C–H ⋯ O interactions.