van Delft, Maarten R.Pezzini, SergioKonig, MarkusTinnemans, PaulHussey, Nigel E.Wiedmann, Steffen2020-06-102020-06-102020-06-102020-04-0110.3390/cryst10040288https://infoscience.epfl.ch/handle/20.500.14299/169190WOS:000535596700052The motivation to search for signatures of superconductivity in Weyl semi-metals and other topological phases lies in their potential for hosting exotic phenomena such as nonzero-momentum pairing or the Majorana fermion, a viable candidate for the ultimate realization of a scalable quantum computer. Until now, however, all known reports of superconductivity in type-I Weyl semi-metals have arisen through surface contact with a sharp tip, focused ion-beam surface treatment or the application of high pressures. Here, we demonstrate the observation of superconductivity in single crystals, even an as-grown crystal, of the Weyl semi-metal tantalum phosphide (TaP), at ambient pressure. A superconducting transition temperature, T-c, varying between 1.7 and 5.3 K, is observed in different samples, both as-grown and microscopic samples processed with focused ion beam (FIB) etching. Our data show that the superconductivity present in the as-grown crystal is inhomogeneous yet three-dimensional. For samples fabricated with FIB, we observe, in addition to the three-dimensional superconductivity, a second superconducting phase that resides on the sample surface. Through measurements of the characteristic fields as a function of temperature and angle, we are able to confirm the dimensionality of the two distinct superconducting phases.CrystallographyMaterials Science, MultidisciplinaryCrystallographyMaterials Sciencesuperconductivityweyl semimetalfocused ion beamising superconductivityangular-dependencefermi arcsdiscoverytransitionfieldtext::journal::journal article::research article