Experimental Evidence of Chiral Symmetry Breaking in Kekule-Ordered Graphene

Bao Changhua; Zhang Hongyun; Zhang Teng; Wu Xi; Luo Laipeng; Zhou Shaohua; Li Qian; Hou Yanhui; Yao Wei; Liu Liwei; Yu Pu; Li Jia; Duan Wenhui; Yao Hong; Wang Yeliang; Zhou Shuyun

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Experimental Evidence of Chiral Symmetry Breaking in Kekule-Ordered Graphene

机译：尾骨有序石墨烯手性对称性突破的实验证据

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The low-energy excitations of graphene are relativistic massless Dirac fermions with opposite chiralities at valleys K and K'. Breaking the chiral symmetry could lead to gap opening in analogy to dynamical mass generation in particle physics. Here we report direct experimental evidences of chiral symmetry breaking (CSB) from both microscopic and spectroscopic measurements in a Li-intercalated graphene. The CSB is evidenced by gap opening at the Dirac point, Kekule-O type modulation, and chirality mixing near the gap edge. Our work opens up opportunities for investigating CSB related physics in a Kekule-ordered graphene.

机译：石墨烯的低能量激发是具有相对的对谷K和K'相对的手性的具有相对性的无麻子晶片。打破手性对称性可能导致间隙开口与颗粒物理学中的动态质量产生。在这里，我们报告了在锂插入的石墨烯中的微观和光谱测量中的手性对称断裂（CSB）的直接实验证据。 CSB通过在DIAC点，KEKUE-O型调制和间隙边缘附近的手性混合中的间隙开口证明。我们的工作开辟了调查尾骨有序石墨烯CSB相关物理的机会。

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来源
《Physical review letters》 |2021年第20期|206804.1-206804.7|共7页
作者
Bao Changhua; Zhang Hongyun; Zhang Teng; Wu Xi; Luo Laipeng; Zhou Shaohua; Li Qian; Hou Yanhui; Yao Wei; Liu Liwei; Yu Pu; Li Jia; Duan Wenhui; Yao Hong; Wang Yeliang; Zhou Shuyun;
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Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China;

Beijing Inst Technol MIIT Key Lab Low Dimens Quantum Struct & Devices Sch Informat & Elect Beijing 100081 Peoples R China;

Tsinghua Univ Tsinghua Shenzhen Int Grad Sch Shenzhen Geim Graphene Ctr Shenzhen 518055 Peoples R China|Tsinghua Univ Tsinghua Shenzhen Int Grad Sch Inst Mat Res Shenzhen 518055 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China;

Beijing Inst Technol MIIT Key Lab Low Dimens Quantum Struct & Devices Sch Informat & Elect Beijing 100081 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China;

Beijing Inst Technol MIIT Key Lab Low Dimens Quantum Struct & Devices Sch Informat & Elect Beijing 100081 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China|Frontier Sci Ctr Quantum Informat Beijing 100084 Peoples R China;

Tsinghua Univ Tsinghua Shenzhen Int Grad Sch Shenzhen Geim Graphene Ctr Shenzhen 518055 Peoples R China|Tsinghua Univ Tsinghua Shenzhen Int Grad Sch Inst Mat Res Shenzhen 518055 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China|Frontier Sci Ctr Quantum Informat Beijing 100084 Peoples R China;

Tsinghua Univ Inst Adv Study Beijing 100084 Peoples R China|Stanford Univ Dept Phys Stanford CA 94305 USA;

Beijing Inst Technol MIIT Key Lab Low Dimens Quantum Struct & Devices Sch Informat & Elect Beijing 100081 Peoples R China;

Tsinghua Univ State Key Lab Low Dimens Quantum Phys Beijing 100084 Peoples R China|Tsinghua Univ Dept Phys Beijing 100084 Peoples R China|Frontier Sci Ctr Quantum Informat Beijing 100084 Peoples R China|Beijing Adv Innovat Ctr Future Chip Beijing 100084 Peoples R China;

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入库时间 2022-08-19 02:22:29

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Experimental Evidence of Chiral Symmetry Breaking in Kekule-Ordered Graphene

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