Motivated by a recent experiment by Bergeal et al., we reconsider incoherent
pair tunneling in a cuprate junction formed from an optimally doped
superconducting lead and an underdoped normal metallic lead. We study the
impact of the pseudogap on the pair tunneling by describing fermions in the
underdoped lead with a model self-energy that has been developed to reproduce
photoemission data. We find that the pseudogap causes an additional temperature
dependent suppression of the pair contribution to the tunneling current. We
discuss consistency with available experimental data and propose future
experimental directions.
Description
Incoherent pair tunneling in the pseudogap phase of cuprates
%0 Generic
%1 micklitz2012incoherent
%A Micklitz, T.
%A Levchenko, A.
%A Norman, M. R.
%D 2012
%K cuprate incoherent pairtunneling pseudogap tunneling
%T Incoherent pair tunneling in the pseudogap phase of cuprates
%U http://arxiv.org/abs/1211.2468
%X Motivated by a recent experiment by Bergeal et al., we reconsider incoherent
pair tunneling in a cuprate junction formed from an optimally doped
superconducting lead and an underdoped normal metallic lead. We study the
impact of the pseudogap on the pair tunneling by describing fermions in the
underdoped lead with a model self-energy that has been developed to reproduce
photoemission data. We find that the pseudogap causes an additional temperature
dependent suppression of the pair contribution to the tunneling current. We
discuss consistency with available experimental data and propose future
experimental directions.
@misc{micklitz2012incoherent,
abstract = {Motivated by a recent experiment by Bergeal et al., we reconsider incoherent
pair tunneling in a cuprate junction formed from an optimally doped
superconducting lead and an underdoped normal metallic lead. We study the
impact of the pseudogap on the pair tunneling by describing fermions in the
underdoped lead with a model self-energy that has been developed to reproduce
photoemission data. We find that the pseudogap causes an additional temperature
dependent suppression of the pair contribution to the tunneling current. We
discuss consistency with available experimental data and propose future
experimental directions.},
added-at = {2012-11-19T04:34:40.000+0100},
author = {Micklitz, T. and Levchenko, A. and Norman, M. R.},
biburl = {https://www.bibsonomy.org/bibtex/23a23d8660d37bc78d3abe430e1b90b89/kyungminlee},
description = {Incoherent pair tunneling in the pseudogap phase of cuprates},
interhash = {eb45fd2e964b08d6d3cff455a470fb68},
intrahash = {3a23d8660d37bc78d3abe430e1b90b89},
keywords = {cuprate incoherent pairtunneling pseudogap tunneling},
note = {cite arxiv:1211.2468Comment: 5 pages, 3 figures},
timestamp = {2012-11-19T04:34:40.000+0100},
title = {Incoherent pair tunneling in the pseudogap phase of cuprates},
url = {http://arxiv.org/abs/1211.2468},
year = 2012
}