Visualization of the strain-induced topological phase transition in a quasi-one-dimensional superconductor TaSe3

Since the discovery of topological insulators (TIs), controlling the fascinating properties has been attempted. The most direct way for it is to utilize the phase transition from the topological to normal insulators, which allows an on/off switching of spin current robust against the impurity scattering. The topological phase transition has been realized by elemental substitution in semiconducting alloys, which can tune the spin-orbit coupling (SOC) or lattice constant, leading to the band inversion or eliminating it. However, such treatment requires elaborate preparation of materials with various compositions, thus it is quite far from a feasible device application, which demands a reversible operation. Here we demonstrate a quasi-one-dimensional (quasi-1D) superconductor TaSe3 to be the best material which realizes the reversible on/off switching of topological spin current only by applying uniaxial pressure to a crystal, through the observation of band structure with the high-resolution laser-based angle-resolved photoemission spectroscopy (ARPES) and spin-resolved ARPES (SARPES). Firstly, we uncover that TaSe3 is in a strong TI phase with the spin-polarized, quasi-1D topological surface states (TSSs), which benefits from highly directional, dense spin currents that are protected against backscattering. Most importantly, we present the first direct observation of the strain-induced topological phase transition in solids, through the investigation of TaSe3. The quasi-1D superconductor TaSe3 provides an ideal platform for engineering the topological spintronics which exploits the topological state, its interplay with superconductivity, and the topological phase transition.