Unconventional spectral signature of Tc in a pure d-wave superconductor

In conventional superconductors, the phase transition into a zero-resistance and perfectly diamagnetic state is accompanied by a jump in the specific heat and the opening of a spectral gap(1). In the high-transition-temperature (high-T-c) cuprates, although the transport, magnetic and thermodynamic signatures of T-c have been known since the 1980s(2), the spectroscopic singularity associated with the transition remains unknown. Here we resolve this long-standing puzzle with a high-precision angle-resolved photoemission spectroscopy (ARPES) study on overdoped (Bi,Pb)(2)Sr2CaCu2O8+delta (Bi2212). We first probe the momentum-resolved electronic specific heat via spectroscopy and reproduce the specific heat peak at T-c, completing the missing link for a holistic description of superconductivity. Then, by studying the full momentum, energy and temperature evolution of the spectra, we reveal that this thermodynamic anomaly arises from the singular growth of in-gap spectral intensity across T-c. Furthermore, we observe that the temperature evolution of in-gap intensity is highly anisotropic in the momentum space, and the gap itself obeys both the d-wave functional form and particle-hole symmetry. These findings support the scenario that the superconducting transition is driven by phase fluctuations. They also serve as an anchor point for understanding the Fermi arc and pseudogap phenomena in underdoped cuprates.

Automated summary

Scientists have resolved the spectroscopic singularity associated with the high-Tc superconducting transition in cuprates using high-precision angle-resolved photoemission spectroscopy. They discovered that the anomaly is caused by the singular growth of in-gap spectral intensity and observed that the temperature evolution of this intensity is highly anisotropic in momentum space.