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Literature DB >> 21699332

Both electron and hole Dirac cone states in Ba(FeAs)2 confirmed by magnetoresistance.

Khuong K Huynh¹, Yoichi Tanabe, Katsumi Tanigaki.

Abstract

Quantum transport of Dirac cone states in the iron pnictide Ba(FeAs)(2) with a d-multiband system is studied by using single crystal samples. Transverse magnetoresistance develops linearly against the magnetic field at low temperatures. The transport phenomena are interpreted in terms of the zeroth Landau level by applying the theory predicted by Abrikosov. The results of the semiclassical analyses of a two carrier system in a low magnetic field limit show that both the electron and hole reside as the high mobility states. Our results show that pairs of electron and hole Dirac cone states must be taken into account for an accurate interpretation in iron pnictides, which is in contrast with previous studies.

Entities: Chemical

Year: 2011 PMID： 21699332 DOI： 10.1103/PhysRevLett.106.217004

Source DB: PubMed Journal: Phys Rev Lett ISSN： 0031-9007 Impact factor: 9.161

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Cited

5 in total

1. Optical signatures of Dirac nodal lines in NbAs₂.

Authors: Yinming Shao; Zhiyuan Sun; Ying Wang; Chenchao Xu; Raman Sankar; Alexander J Breindel; Chao Cao; Michael M Fogler; Andrew J Millis; Fangcheng Chou; Zhiqiang Li; Thomas Timusk; M Brian Maple; D N Basov
Journal: Proc Natl Acad Sci U S A Date: 2018-12-17 Impact factor: 11.205

5. Transport property of multi-band topological material PtBi[Formula: see text] studied by maximum entropy mobility spectrum analysis (MEMSA).

Authors: Haijun Zhao; Wenchong Li; Yue Chen; Chunqiang Xu; Bin Li; Weidong Luo; Dong Qian; Zhixiang Shi
Journal: Sci Rep Date: 2021-03-18 Impact factor: 4.379

5 in total

Both electron and hole Dirac cone states in Ba(FeAs)2 confirmed by magnetoresistance.

1. Optical signatures of Dirac nodal lines in NbAs₂.

2. Large nonsaturating magnetoresistance and signature of nondegenerate Dirac nodes in ZrSiS.

3. Selective orbital reconstruction in tetragonal FeS: A density functional dynamical mean-field theory study.

4. Linear magnetoresistivity in layered semimetallic CaAl₂Si₂.

5. Transport property of multi-band topological material PtBi[Formula: see text] studied by maximum entropy mobility spectrum analysis (MEMSA).

Both electron and hole Dirac cone states in Ba(FeAs)2 confirmed by magnetoresistance.

1. Optical signatures of Dirac nodal lines in NbAs2.

2. Large nonsaturating magnetoresistance and signature of nondegenerate Dirac nodes in ZrSiS.

3. Selective orbital reconstruction in tetragonal FeS: A density functional dynamical mean-field theory study.

4. Linear magnetoresistivity in layered semimetallic CaAl2Si2.

5. Transport property of multi-band topological material PtBi[Formula: see text] studied by maximum entropy mobility spectrum analysis (MEMSA).

1. Optical signatures of Dirac nodal lines in NbAs₂.

4. Linear magnetoresistivity in layered semimetallic CaAl₂Si₂.