Direct observation of the Higgs mode in a superconductor by non-equilibrium Raman scattering

The Anderson-Higgs mechanism provides mass to the photon in a superconductor, resulting in the Meissner effect, representing a one-to-one analogy to high-energy physics. We report on the direct observation of the Higgs excitation in d-wave high-temperature superconductors by developing an innovative technique to study the Higgs mode after a soft quench of the Mexican-hat free-energy potential by light: Non-Equilibrium Anti-Stokes Raman Scattering (NEARS) identifies the Higgs mode by its distinct characteristic symmetry-dependent excitation energy below twice the energy of the superconducting gap of optimally-doped Bi-2212. Disentangling the Higgs mode from different types of superconductivity-induced excitations opens the avenue for Higgs spectroscopy and provides a unique pathway to study exotic forms of superconductivity at interfaces and in transient states.