Determining the superconducting order parameter of UPt3 using scanning tunneling microscopy
Abstract
Superconductivity, a state in which electrical currents can flow without resistance, occurs because of pairing of electrons into quasiparticles with integer spin S. In practically all known superconducting materials, these pairs form a singlet with S=0. Finding a material that has triplet pairing, S=1, would have profound fundamental and technological implications. UPt3 has been a key candidate material for spin-triplet superconductivity. Because of a lack of direct evidence for the pairing symmetry, the nature of the superconducting pairing remains under debate. Here, we use ultra-low temperature scanning tunneling microscopy to resolve this question. Our data reveals a zero-bias Andreev bound state within the gap for a surface normal to the c-axis of UPt3. The superconducting origin of the features is confirmed through vortex imaging. For triplet pairing, such an Andreev state is fragile against Rashba spin-splitting, whereas for singlet pairing it remains robust, classifying UPt3 as a spin-singlet superconductor with a chiral order parameter.
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