Supercurrent transferring throughc-axis cuprate Josephson junctions with thick normal-metal bridge

Abstract: With a simple but exactly solvable model, we investigate the supercurrent transferring through the c-axis cuprate superconductor-normal metal-superconductor junctions with the clean normal metal much thicker than its coherence length. It is shown that the supercurrent as a function of thickness of the normal metal decreases much slower than the exponential decaying expected by the proximity effect. The present result may account for the giant proximity effect observed in the c-axis cuprate SNS junctions.

“…The model of the SNS junction without the proximity effect [1][2][3] used in our analysis is rather simplistic, but its analysis is an important first step for investigation of more complicated cases when normal and superconducting layers have different Fermi energies and effective masses, or the normal layer of the SNS sandwich is replaced by other materials, e.g., ballistic graphene or ballistic nanotubes. These cases are studied experimentally and theoretically nowadays [4][5][6][7][8][9]. Although the extension of the model on various cases of interest for nowadays experiments is needed, one may expect that the conclusions about the π junction and the temperature dependence would survive this extension.…”

“…Investigations of this model continues up to now [4]. The ballistic SNS Josephson junction was studied for unconventional pairing in high-T c superconductors [5]. There were theoretical and experimental investigations for other materials bridging two superconductors: graphene [6,7], topological insulator [8], and nanotubes [9].…”

Ballistic SNS sandwich as a Josephson junction

“…The model of the SNS junction without the proximity effect [1][2][3] used in our analysis is rather simplistic, but its analysis is an important first step for investigation of more complicated cases when normal and superconducting layers have different Fermi energies and effective masses, or the normal layer of the SNS sandwich is replaced by other materials, e.g., ballistic graphene or ballistic nanotubes. These cases are studied experimentally and theoretically nowadays [4][5][6][7][8][9]. Although the extension of the model on various cases of interest for nowadays experiments is needed, one may expect that the conclusions about the π junction and the temperature dependence would survive this extension.…”

“…Investigations of this model continues up to now [4]. The ballistic SNS Josephson junction was studied for unconventional pairing in high-T c superconductors [5]. There were theoretical and experimental investigations for other materials bridging two superconductors: graphene [6,7], topological insulator [8], and nanotubes [9].…”

Ballistic SNS sandwich as a Josephson junction

“…To provide an enhanced length scale of the proximity effect, several models have been proposed 19 20 21 22 23 24 25 26 27 . One class of models postulate inhomogeneous barriers that contain superconducting islands embedded in a metallic matrix and forming a percolative network that can transmit supercurrent via Josephson coupling between the islands and also between the CuO 2 layers 19 20 21 22 .…”

The Meissner effect in a strongly underdoped cuprate above its critical temperature