The Elusive High-Tc Superinductor

Abstract

Ginzburg-Landau (GL) parameters formed the basis for Abrikosov discovery of the quantum vortex of a supercurrent in type-II superconductor with a normal core of size , the superconductor coherence length and circulating supercurrent induced magnetic field diverging as log(1/r) from the core with a decay length of the London penetration depth, λL. In 1964, J. Pearl predicted the slowly decaying (1/r2) field around a vortex spreading out to Pearl length, PL=2λL2/t, in a superconductor film of thickness t < λL. However, his quintessential theory failed to predict the existence of giant kinetic inductance (GKI) that arises from the enlarged screening currents of the vortex. Here, we discover giant kinetic inductance in a high-Tc metasurface due to the 1400% expansion of the vortex screening supercurrent from λL to 14λL in ultrathin film meta-atom of λL/7 thickness, which leads to the emergence of terahertz superinductance possessing quantum impedance exceeding the resistance quantum limit of RQ=h/(2e)2 =6.47 k by 33%. Our discovery presents a new class of high-Tc superconductor electronic, photonic, and quantum devices enabled through metasurface designed at the Pearl length scales, providing novel applications in quantum circuitry, metrology, and single photon kinetic inductance detectors.