Coexistence of symmetry-enforced phononic Dirac nodal-line net and three-nodal surfaces phonons in solid-state materials: Theory and materials realization

Jianhua Wang; Hongkuan Yuan; Zhi Ming Yu; Zeying Zhang; Xiaotian Wang

doi:10.1103/PhysRevMaterials.5.124203

Coexistence of symmetry-enforced phononic Dirac nodal-line net and three-nodal surfaces phonons in solid-state materials: Theory and materials realization

Jianhua Wang, Hongkuan Yuan, Zhi Ming Yu, Zeying Zhang^*, Xiaotian Wang^*

^*Corresponding author for this work

School of Physics

Research output: Contribution to journal › Article › peer-review

37 Citations (Scopus)

Abstract

In this study, using symmetry analysis, we reveal that symmetry-enforced three-nodal surfaces (NSs) and Dirac nodal-line (DNL) net phonons can coexist in two candidate space groups (SGs) - with SG Nos. 61 and 205 - out of 230 SGs. The phononic DNL net in SGs 61 and 205 contains three phononic DNLs, which share phononic nodal point R in the momentum space and lie at the hinge between two of the three ki(i=x,y,z) planes. More interestingly, using first-principle calculations, we find that the realistic materials ZnSb (with SG No. 61) and RuS2, P2Pt, and OsS2 (with SG No. 205) exhibit three NSs and DNL net phonons. In addition, we report that obvious phononic surface states can be observed in these mentioned realistic materials and will benefit their experimental detection. We hope that the proposed realistic materials can be viewed as ideal platforms to realize the DNL net and three-NSs phonons in solid-state materials.

Original language	English
Article number	124203
Journal	Physical Review Materials
Volume	5
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevMaterials.5.124203
Publication status	Published - Dec 2021

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title = "Coexistence of symmetry-enforced phononic Dirac nodal-line net and three-nodal surfaces phonons in solid-state materials: Theory and materials realization",

abstract = "In this study, using symmetry analysis, we reveal that symmetry-enforced three-nodal surfaces (NSs) and Dirac nodal-line (DNL) net phonons can coexist in two candidate space groups (SGs) - with SG Nos. 61 and 205 - out of 230 SGs. The phononic DNL net in SGs 61 and 205 contains three phononic DNLs, which share phononic nodal point R in the momentum space and lie at the hinge between two of the three ki(i=x,y,z) planes. More interestingly, using first-principle calculations, we find that the realistic materials ZnSb (with SG No. 61) and RuS2, P2Pt, and OsS2 (with SG No. 205) exhibit three NSs and DNL net phonons. In addition, we report that obvious phononic surface states can be observed in these mentioned realistic materials and will benefit their experimental detection. We hope that the proposed realistic materials can be viewed as ideal platforms to realize the DNL net and three-NSs phonons in solid-state materials.",

author = "Jianhua Wang and Hongkuan Yuan and Yu, {Zhi Ming} and Zeying Zhang and Xiaotian Wang",

note = "Publisher Copyright: {\textcopyright} 2021 American Physical Society.",

year = "2021",

month = dec,

doi = "10.1103/PhysRevMaterials.5.124203",

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T2 - Theory and materials realization

AU - Wang, Jianhua

AU - Yuan, Hongkuan

AU - Yu, Zhi Ming

AU - Zhang, Zeying

AU - Wang, Xiaotian

PY - 2021/12

Y1 - 2021/12

N2 - In this study, using symmetry analysis, we reveal that symmetry-enforced three-nodal surfaces (NSs) and Dirac nodal-line (DNL) net phonons can coexist in two candidate space groups (SGs) - with SG Nos. 61 and 205 - out of 230 SGs. The phononic DNL net in SGs 61 and 205 contains three phononic DNLs, which share phononic nodal point R in the momentum space and lie at the hinge between two of the three ki(i=x,y,z) planes. More interestingly, using first-principle calculations, we find that the realistic materials ZnSb (with SG No. 61) and RuS2, P2Pt, and OsS2 (with SG No. 205) exhibit three NSs and DNL net phonons. In addition, we report that obvious phononic surface states can be observed in these mentioned realistic materials and will benefit their experimental detection. We hope that the proposed realistic materials can be viewed as ideal platforms to realize the DNL net and three-NSs phonons in solid-state materials.

AB - In this study, using symmetry analysis, we reveal that symmetry-enforced three-nodal surfaces (NSs) and Dirac nodal-line (DNL) net phonons can coexist in two candidate space groups (SGs) - with SG Nos. 61 and 205 - out of 230 SGs. The phononic DNL net in SGs 61 and 205 contains three phononic DNLs, which share phononic nodal point R in the momentum space and lie at the hinge between two of the three ki(i=x,y,z) planes. More interestingly, using first-principle calculations, we find that the realistic materials ZnSb (with SG No. 61) and RuS2, P2Pt, and OsS2 (with SG No. 205) exhibit three NSs and DNL net phonons. In addition, we report that obvious phononic surface states can be observed in these mentioned realistic materials and will benefit their experimental detection. We hope that the proposed realistic materials can be viewed as ideal platforms to realize the DNL net and three-NSs phonons in solid-state materials.

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Coexistence of symmetry-enforced phononic Dirac nodal-line net and three-nodal surfaces phonons in solid-state materials: Theory and materials realization

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