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Main Authors: Zhang, Long, Wang, Tianyang, Zhang, Yugang, Liu, Shuang, Sun, Yuping, Zhou, Xiaoyuan, Sun, Young, He, Mingquan, Wang, Aifeng, Luo, Xuan, Chai, Yisheng
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2308.01212
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author Zhang, Long
Wang, Tianyang
Zhang, Yugang
Liu, Shuang
Sun, Yuping
Zhou, Xiaoyuan
Sun, Young
He, Mingquan
Wang, Aifeng
Luo, Xuan
Chai, Yisheng
author_facet Zhang, Long
Wang, Tianyang
Zhang, Yugang
Liu, Shuang
Sun, Yuping
Zhou, Xiaoyuan
Sun, Young
He, Mingquan
Wang, Aifeng
Luo, Xuan
Chai, Yisheng
contents Quantum oscillation (QO), a physical phenomenon that reflects the characteristics of the Fermi surface and transport fermions, has been extensively observed in metals and semimetals through various approaches, like magnetostriction, magnetization, resistivity, and thermoelectric power. However, only some allowed oscillation frequencies can be revealed by each individual method, particularly in semimetals with intricate Fermi pockets and associated magnetic breakdown phenomena. In this paper, we present the application of an ac composite magnetoelectric (ME) technique to measure the QOs of a topological nodal-line semimetal, ZrSiS, which possesses six fundamental QO frequencies. By employing the ME technique with a maximum magnetic field of 13 T and a minimum temperature of 2 K, we are able to capture all the fundamental frequencies and most of the permissible magnetic breakdown frequencies. In comparison, some of the frequencies were missing in the aforementioned four methods under identical measurement conditions. Remarkably, a series of magnetic breakdown frequencies around 8000 T were revealed even in a magnetic field as low as 7.5 T. These findings highlight the ME technique as an ultrahigh-sensitive tool for studying Dirac Fermions and other topological semimetals with complex Fermi surfaces.
format Preprint
id arxiv_https___arxiv_org_abs_2308_01212
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Comprehensive investigation of Quantum Oscillations in Semimetal Using an ac Composite Magnetoelectric Technique with Ultrahigh Sensitivity
Zhang, Long
Wang, Tianyang
Zhang, Yugang
Liu, Shuang
Sun, Yuping
Zhou, Xiaoyuan
Sun, Young
He, Mingquan
Wang, Aifeng
Luo, Xuan
Chai, Yisheng
Strongly Correlated Electrons
Mesoscale and Nanoscale Physics
Quantum oscillation (QO), a physical phenomenon that reflects the characteristics of the Fermi surface and transport fermions, has been extensively observed in metals and semimetals through various approaches, like magnetostriction, magnetization, resistivity, and thermoelectric power. However, only some allowed oscillation frequencies can be revealed by each individual method, particularly in semimetals with intricate Fermi pockets and associated magnetic breakdown phenomena. In this paper, we present the application of an ac composite magnetoelectric (ME) technique to measure the QOs of a topological nodal-line semimetal, ZrSiS, which possesses six fundamental QO frequencies. By employing the ME technique with a maximum magnetic field of 13 T and a minimum temperature of 2 K, we are able to capture all the fundamental frequencies and most of the permissible magnetic breakdown frequencies. In comparison, some of the frequencies were missing in the aforementioned four methods under identical measurement conditions. Remarkably, a series of magnetic breakdown frequencies around 8000 T were revealed even in a magnetic field as low as 7.5 T. These findings highlight the ME technique as an ultrahigh-sensitive tool for studying Dirac Fermions and other topological semimetals with complex Fermi surfaces.
title Comprehensive investigation of Quantum Oscillations in Semimetal Using an ac Composite Magnetoelectric Technique with Ultrahigh Sensitivity
topic Strongly Correlated Electrons
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2308.01212