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Surface structure and multigap superconductivity of V3Si (111) revealed by scanning tunneling microscopy

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arxiv 2304.10766 v1 pith:3NQEDP47 submitted 2023-04-21 cond-mat.supr-con cond-mat.mtrl-sci

Surface structure and multigap superconductivity of V3Si (111) revealed by scanning tunneling microscopy

classification cond-mat.supr-con cond-mat.mtrl-sci
keywords surfacev3sifieldsuperconductingvortexbulkcoherencemagnetic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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V3Si, a classical silicide superconductor with relatively high TC (~16 K), is promising for constructing silicon-based superconducting devices and hetero-structures. However, real space characterization on its surfaces and superconducting properties are still limited. Here we report the first low-temperature scanning tunnelling microscopy (STM) study on cleaned V3Si (111) single crystal surface. We observed a r3 by r3 superstructure which displays mirror symmetry between adjacent terraces, indicating the surface is V-terminated and reconstructed. The tunneling spectrum shows full superconducting gap with double pairs of coherence peaks, but has a relatively small gap size with comparing to bulk TC. Impurity induced in-gap state is absent on surface defects but present on introduced magnetic adatoms. Upon applying magnetic field, a hexagonal vortex lattice is visualized. Interestingly, the vortex size is found to be field dependent, and the coherence length measured from single vortex at low field is significantly larger than estimated value from bulk H_c2. These results reflect V3Si is a multi-band, s- wave superconductor.

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