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Hays, M. ; de Lange, G. ; Serniak, K. ; van Woerkom, D. J. ; Bouman, D. ; Krogstrup, P. ; Nygård, J. ; Geresdi, A. ; Devoret, M. H. ( , Physical Review Letters)
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Shabani, J. ; Kjaergaard, M. ; Suominen, H. J. ; Kim, Younghyun ; Nichele, F. ; Pakrouski, K. ; Stankevic, T. ; Lutchyn, R. M. ; Krogstrup, P. ; Feidenhans'l, R. ; et al ( , Physical Review B)
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Vaitiekėnas, S. ; Winkler, G. W. ; van Heck, B. ; Karzig, T. ; Deng, M. -T. ; Flensberg, K. ; Glazman, L. I. ; Nayak, C. ; Krogstrup, P. ; Lutchyn, R. M. ; et al ( , Science)
Hybrid semiconductor-superconductor nanowires have emerged as a promising platform for realizing topological superconductivity (TSC). Here, we present a route to TSC using magnetic flux applied to a full superconducting shell surrounding a semiconducting nanowire core. Tunneling into the core reveals a hard induced gap near zero applied flux, corresponding to zero phase winding, and a gapped region with a discrete zero-energy state around one applied flux quantum, corresponding to 2π phase winding. Theoretical analysis indicates that the winding of the superconducting phase can induce a transition to a topological phase supporting Majorana zero modes. Measured Coulomb blockade peak spacing around one flux quantum shows a length dependence that is consistent with the existence of Majorana modes at the ends of the nanowire.