Nodal superconductivity with spin-triplet component in a noncentrosymmetric weakly-correlated metal

In conventional superconductors, Cooper pairs form in an even-parity spin-singlet state. Noncentrosymmetric superconductors, which lack inversion symmetry, exhibit antisymmetric spin-orbit coupling (ASOC) that can combine even-parity spin-singlet and odd-parity spin-triplet pairs into a mixed-parity order parameter. Spin-triplet components are highly beneficial for superspintronic devices. Whether ASOC alone $-$ without strong electronic correlations $-$ is sufficient to generate a measurable triplet component remains a central open question. Here, we resolve this question in Nb$_{18}$Re$_{82}$ (Nb-Re), a weakly-correlated noncentrosymmetric metal whose superconducting pairing symmetry has been actively debated. Using low-temperature scanning tunneling spectroscopy on single crystals with four distinct crystallographic orientations, find a pronounced orientation-dependent anisotropy in the local density of states. Supported by a symmetry-constrained model, we show that the complete set of tunneling spectra requires a mixed-parity order parameter with the triplet amplitude reaching up to half of the singlet component. These results reconcile the conflicting reports in the literature on Nb-Re and demonstrate that ASOC is sufficient to foster a sizable spin-triplet component even without strong electronic correlations, suggesting that mixed-parity superconducting states may be more widespread than previously assumed. Since Nb-Re can be readily fabricated in thin-film form, these findings position it as an accessible platform for superspintronic devices and establish orientation-resolved tunneling spectroscopy as a general protocol for the detection of mixed-parity order parameters.