부산대학교 도서관

Even before its role in electroweak symmetry breaking, the Anderson-Higgs mechanism was introduced to explain the Meissner effect in superconductors. Spontaneous symmetry-breaking yields massless phase modes representing the low-energy excitations of the Mexican-Hat potential. Only in superconductors does the gauge field move the phase mode towards higher energies, as a consequence of the charged condensate. This results in a low-energy excitation spectrum governed by the amplitude mode - the Higgs mode. Consequently, the Meissner effect signifies a macroscopic quantum condensate in which a photon acquires mass, representing a one-to-one analogy to high-energy physics. We report on the direct observation of the Higgs particle in the high-temperature superconductor Bi-2212 by developing an innovative technique to study its distinct symmetries and energies after a soft quench of the Mexican-Hat potential. By comparing transient Stokes and anti-Stokes data, we identify the Higgs particle as an additional anti-Stokes Raman cross section after quenching. With our technique we discriminate quasi-particle excitations from excitations in the Cooper channel and argue that alternatives to the Higgs excitation can be ruled out. This opens the avenue for Higgs Spectroscopy in quantum condensates and provides a unique pathway to control and explore Higgs physics.
Comment: Revised version with rewritten text elements and added references, new section in SI, updated author list, results unchanged