AVS 61st International Symposium & Exhibition
    Scanning Probe Microscopy Focus Topic Friday Sessions
       Session SP+AS+BI+EM+NS+SE+SS-FrM

Paper SP+AS+BI+EM+NS+SE+SS-FrM6
Local Probing of Superconductivity in Half Heusler Compounds

Friday, November 14, 2014, 10:00 am, Room 312

Session: Probe-Sample Interactions and Emerging Instrument Formats
Presenter: Hongwoo Baek, NIST & Seoul National University, Republic of Korea
Authors: H. Baek, NIST & Seoul National University, Republic of Korea
J. Ha, NIST/Maryland Nano Center, University of Maryland
D. Zhang, NIST/Maryland Nano Center, University of Maryland
Y. Nakajima, University of Maryland
P.S. Syers, University of Maryland
X. Wang, University of Maryland
K. Wang, University of Maryland
J. Paglione, University of Maryland
Y. Kuk, Seoul National University, Republic of Korea
J.A. Stroscio, NIST
Correspondent: Click to Email

Heusler alloys have attracted interest as multifunctional experimental platforms for topological quantum phenomena ranging from magnetism to superconductivity and heavy fermion behavior. The rare-earth chalcogenide ternary half Heusler compounds were theoretically predicted to have topologically nontrivial surface states due to band inversion [1]. The lack of inversion symmetry of the crystal lattice makes unconventional pairing symmetry feasible. The superconductivity in the non-centrosymmetric half Heusler compound YPtBi was recently reported as a promising system for the investigation of topological superconductivity [2]. In this work, we use ultra low temperature scanning tunneling micro scopy to investigate the superconducting properties of the ternary half Heusler compounds YPdBi and YPtBi. Both were theoretically proposed to have topological states with different band inversion strength [1], and experimentally reported as a topological insulator [3]. Strong spin-orbit coupling and the lack of inversion symmetry present the possibility of spin-triplet superconductivity in these materials. T he tunneling spectra of YPdBi show two different superconducting gaps of 0.36 meV and 0.16 meV depending on the measurement location. The variation in gaps might originate from inhomogeneity in the crystal. The superconducting gap of 0.36 meV is completely suppressed above a critical magnetic field of B=2.5 T, in agreement with bulk transport measurements. A superconducting gap of 0.21 meV and an upper critical field of 1.25 T were measured in a circular superconducting domain of diameter ≈180 nm in YPtBi. Sequential addition of single vortices to the superconducting YPtBi domain could be observed with increasing magnetic field, with vortices occupying the perimeter of the island. These observations will be discussed in terms of island confinement and pairing symmetry of YPtBi.

[1] S. Chadov, X. Qi, J. Kubler, G. H. Fecher, C. Felser, and S. C. Zhang, Nat. Mater. 9, 541 (2010).

[2] N. P. Butch, P. Syers, K. Kirshenbaum, A. P. Hope, and J. Paglione, Phys. Rev. B 84, 220504(R) (2011).

[3] W. Wang, Y. Du, G. Xu, X. Zhang, E. Liu, Z. Liu, Y. Shi, J. Chen, G. Wu, and X. Zhang, Scientific Reports 3 (2013).