Investigation of exotic stable calcium carbides using theory and experiment

It is well known that pressure causes profound changes in the properties of atoms and chemical bonding, leading to the formation of many unusual materials. Here we systematically explore all stable calcium carbides at pressures from ambient to 100 GPa using variable-composition evolutionary structure predictions using the USPEX code. We find that Ca(5)C(2), Ca(2)C, Ca(3)C(2), CaC, Ca(2)C(3) and CaC(2) have stability fields on the phase diagram. Among these, Ca(2)C and Ca(2)C(3) are successfully synthesized for the first time via high-pressure experiments with excellent structural correspondence to theoretical predictions. Of particular significance is the base-centred monoclinic phase (space group C2/m) of Ca(2)C, a quasi-two-dimensional metal with layers of negatively charged calcium atoms, and the primitive monoclinic phase (space group P2(1)/c) of CaC with zigzag C(4) groups. Interestingly, strong interstitial charge localization is found in the structure of R-3m-Ca(5)C(2) with semi-metallic behaviour.