Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor

Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor

The iron-based superconductors are characterized by multiple-orbital physics where all the five Fe 3d orbitals get involved. The multiple-orbital nature gives rise to various novel phenomena like orbital-selective Mott transition, nematicity, and orbital fluctuation that provide a new route for real...

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Main Authors: Defa Liu, Cong Li, Jianwei Huang, Bin Lei, Le Wang, Xianxin Wu, Bing Shen, Qiang Gao, Yuxiao Zhang, Xu Liu, Yong Hu, Yu Xu, Aiji Liang, Jing Liu, Ping Ai, Lin Zhao, Shaolong He, Li Yu, Guodong Liu, Yiyuan Mao, Xiaoli Dong, Xiaowen Jia, Fengfeng Zhang, Shenjin Zhang, Feng Yang, Zhimin Wang, Qinjun Peng, Youguo Shi, Jiangping Hu, Tao Xiang, Xianhui Chen, Zuyan Xu, Chuangtian Chen, X. J. Zhou
Format: Article
Language:English
Published: American Physical Society 2018-08-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.8.031033
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spelling doaj-0b859b3e38184b01b3b6281b12e160f02020-11-24T23:55:38ZengAmerican Physical SocietyPhysical Review X2160-33082018-08-018303103310.1103/PhysRevX.8.031033Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe SuperconductorDefa LiuCong LiJianwei HuangBin LeiLe WangXianxin WuBing ShenQiang GaoYuxiao ZhangXu LiuYong HuYu XuAiji LiangJing LiuPing AiLin ZhaoShaolong HeLi YuGuodong LiuYiyuan MaoXiaoli DongXiaowen JiaFengfeng ZhangShenjin ZhangFeng YangZhimin WangQinjun PengYouguo ShiJiangping HuTao XiangXianhui ChenZuyan XuChuangtian ChenX. J. ZhouThe iron-based superconductors are characterized by multiple-orbital physics where all the five Fe 3d orbitals get involved. The multiple-orbital nature gives rise to various novel phenomena like orbital-selective Mott transition, nematicity, and orbital fluctuation that provide a new route for realizing superconductivity. The complexity of multiple-orbital physics also requires us to disentangle the relationship between orbital, spin, and nematicity, and to identify dominant orbital ingredients that dictate superconductivity. The bulk FeSe superconductor provides an ideal platform to address these issues because of its simple crystal structure and unique coexistence of superconductivity and nematicity. However, the orbital nature of the low-energy electronic excitations and its relation to the superconducting gap remain controversial. Here, we report direct observation of the highly anisotropic Fermi surface and extremely anisotropic superconducting gap in the nematic state of the FeSe superconductor by high-resolution laser-based angle-resolved photoemission measurements. We find that the low-energy excitations of the entire hole pocket at the Brillouin zone center are dominated by the single d_{xz} orbital. The superconducting gap exhibits an anticorrelation relation with the d_{xz} spectral weight near the Fermi level; i.e., the gap size minimum (maximum) corresponds to the maximum (minimum) of the d_{xz} spectral weight along the Fermi surface. These observations provide new insights in understanding the orbital origin of the extremely anisotropic superconducting gap in the FeSe superconductor and the relation between nematicity and superconductivity in the iron-based superconductors.http://doi.org/10.1103/PhysRevX.8.031033
collection DOAJ
language English
format Article
sources DOAJ
author Defa Liu
Cong Li
Jianwei Huang
Bin Lei
Le Wang
Xianxin Wu
Bing Shen
Qiang Gao
Yuxiao Zhang
Xu Liu
Yong Hu
Yu Xu
Aiji Liang
Jing Liu
Ping Ai
Lin Zhao
Shaolong He
Li Yu
Guodong Liu
Yiyuan Mao
Xiaoli Dong
Xiaowen Jia
Fengfeng Zhang
Shenjin Zhang
Feng Yang
Zhimin Wang
Qinjun Peng
Youguo Shi
Jiangping Hu
Tao Xiang
Xianhui Chen
Zuyan Xu
Chuangtian Chen
X. J. Zhou
spellingShingle Defa Liu
Cong Li
Jianwei Huang
Bin Lei
Le Wang
Xianxin Wu
Bing Shen
Qiang Gao
Yuxiao Zhang
Xu Liu
Yong Hu
Yu Xu
Aiji Liang
Jing Liu
Ping Ai
Lin Zhao
Shaolong He
Li Yu
Guodong Liu
Yiyuan Mao
Xiaoli Dong
Xiaowen Jia
Fengfeng Zhang
Shenjin Zhang
Feng Yang
Zhimin Wang
Qinjun Peng
Youguo Shi
Jiangping Hu
Tao Xiang
Xianhui Chen
Zuyan Xu
Chuangtian Chen
X. J. Zhou
Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor
Physical Review X
author_facet Defa Liu
Cong Li
Jianwei Huang
Bin Lei
Le Wang
Xianxin Wu
Bing Shen
Qiang Gao
Yuxiao Zhang
Xu Liu
Yong Hu
Yu Xu
Aiji Liang
Jing Liu
Ping Ai
Lin Zhao
Shaolong He
Li Yu
Guodong Liu
Yiyuan Mao
Xiaoli Dong
Xiaowen Jia
Fengfeng Zhang
Shenjin Zhang
Feng Yang
Zhimin Wang
Qinjun Peng
Youguo Shi
Jiangping Hu
Tao Xiang
Xianhui Chen
Zuyan Xu
Chuangtian Chen
X. J. Zhou
author_sort Defa Liu
title Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor
title_short Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor
title_full Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor
title_fullStr Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor
title_full_unstemmed Orbital Origin of Extremely Anisotropic Superconducting Gap in Nematic Phase of FeSe Superconductor
title_sort orbital origin of extremely anisotropic superconducting gap in nematic phase of fese superconductor
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2018-08-01
description The iron-based superconductors are characterized by multiple-orbital physics where all the five Fe 3d orbitals get involved. The multiple-orbital nature gives rise to various novel phenomena like orbital-selective Mott transition, nematicity, and orbital fluctuation that provide a new route for realizing superconductivity. The complexity of multiple-orbital physics also requires us to disentangle the relationship between orbital, spin, and nematicity, and to identify dominant orbital ingredients that dictate superconductivity. The bulk FeSe superconductor provides an ideal platform to address these issues because of its simple crystal structure and unique coexistence of superconductivity and nematicity. However, the orbital nature of the low-energy electronic excitations and its relation to the superconducting gap remain controversial. Here, we report direct observation of the highly anisotropic Fermi surface and extremely anisotropic superconducting gap in the nematic state of the FeSe superconductor by high-resolution laser-based angle-resolved photoemission measurements. We find that the low-energy excitations of the entire hole pocket at the Brillouin zone center are dominated by the single d_{xz} orbital. The superconducting gap exhibits an anticorrelation relation with the d_{xz} spectral weight near the Fermi level; i.e., the gap size minimum (maximum) corresponds to the maximum (minimum) of the d_{xz} spectral weight along the Fermi surface. These observations provide new insights in understanding the orbital origin of the extremely anisotropic superconducting gap in the FeSe superconductor and the relation between nematicity and superconductivity in the iron-based superconductors.
url http://doi.org/10.1103/PhysRevX.8.031033
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