Topological Dirac surface states and superconducting pairing correlations in PbTaSe 2

Superconductivity in topological band structures is a platform for many novel exotic quantum phenomena such as emergent supersymmetry. This potential nourishes the search for topological materials with intrinsic superconducting instabilities, in which Cooper pairing is introduced to electrons with helical spin texture such as the Dirac states of topological insulators and Dirac Semimetals, forming a natural topological superconductor of helical kind. We employ first-principles calculations, ARPES experiments and new theoretical analysis to reveal that PbTaSe2, a non-centrosymmetric superconductor, possesses a nonzero Z2 topological invariant and fully spin-polarized Dirac states. Moreover, we analyze the phonon spectrum of PbTaSe2 to show how superconductivity can emerge due to a stiffening of phonons by the Pb intercalation, which diminishes a competing charge-density-wave instability. Our work establishes PbTaSe2 as a stoichiometric superconductor with nontrivial Z2 topological band structure, and shows that it holds great promise for studying novel forms of topological superconductivity not realized previously.