Structural analysis of boron compounds using 11B-3QMAS solid state NMR

The structural analysis of three boron compounds, boron carbide (B₄C), silicon tetraboride (SiB₄) and hexagonal-boron nitride (h-BN), were performed using 2D ¹¹B-triple quantum MAS (3QMAS) solid state NMR capable of averaging the second-order quadrupolar interaction of ¹¹B that cause line broadening, splitting and low frequency shift of the central transition (−1/2, 1/2). The coordination number around the boron atom and structural symmetry of each boron compound is discussed by means of the isotropic chemical shift Δσ and the quadrupolar coupling constant C_Q calculated from 3QMAS spectra. Δσ of SiB₄ is quite larger than that of B₄C, which is thought to be caused by its structural distortion and distribution. Δσ of h-BN was found to be higher frequency shift obviously than that of B₄C and SiB₄ because of the difference of the boron coordination number, three-coordinated in h-BN and six-coordinated in B₄C and SiB₄. h-BN has very large C_Q compared to other two boron compounds since the h-BN forming a two-dimensional network has less structural symmetry than B₄C and SiB₄.