Unusual suppression of tungsten 5electron depletion in superhard tungsten tetraboride solid solution with chromium under compression.

The lattice compressibility and deformation in superhard tungsten tetraboride (WB) solid solution with chromium (Cr) are investigated by high-pressure x-ray diffraction and x-ray absorption fine structure (XAFS) spectroscopy up to 54 GPa. In contrast to pure WB, the-axis softening is effectively suppressed in WCrB, and less compressibility is shown for the- and-axes in the entire pressure range. Meanwhile, the white-line peak of W L-edge XAFS in WCrBshows an absence of the sudden intensity drop as previously observed in WBat ∼21 GPa, suggesting a strong inhibition of W 5electron depletion. This phenomenon is followed by an initial increase and then decrease for the W-B bond disorder, with the magnitude greatly lower than that of WB. Besides the apparent atomic size mismatch effect, these results imply that addition of Cr, which has the same number of valence electrons as W, can introduce an unexpected electronic structure change to strengthen the W-B bond via a modification of W vacancies and B trimers distribution in WBlattice. Our findings point out the great significance to precise manipulation of the intrinsic W vacancies and B trimers through different solute atoms to rational optimization of WBhardness.