TY - JOUR
T1 - Chemical pressure effect on the optical conductivity of the nodal-line semimetals ZrSiY (Y= S,Se,Te) and ZrGeY (Y= S,Te)
AU - Ebad-Allah, J.
AU - Afonso, J.F.
AU - M., Krottenm
AU - Hu, J.
AU - Zhu, Y.L.
AU - Mao, Z.Q.
AU - J., Kune
AU - Kuntscher, C.A.
N1 - cited By 0
PY - 2019
Y1 - 2019
N2 - ZrSiS is a nodal-line semimetal, whose electronic band structure contains a diamond-shaped line of Dirac nodes. We carried out a comparative study on the optical conductivity of ZrSiS and the related compounds ZrSiSe, ZrSiTe, ZrGeS, and ZrGeTe by reflectivity measurements over a broad frequency range combined with density functional theory calculations. The optical conductivity exhibits a distinct U shape, ending at a sharp peak at around 10000cm-1 for all studied compounds except for ZrSiTe. The U shape of the optical conductivity is due to transitions between the linearly dispersing bands crossing each other along the nodal line. The sharp high-energy peak is related to transitions between almost parallel bands, and its energy position depends on the interlayer bonding correlated with the c/a ratio, which can be tuned by either chemical or external pressure. For ZrSiTe, another pair of crossing bands appears in the vicinity of the Fermi level, corrugating the nodal-line electronic structure and leading to the observed difference in optical conductivity. The findings suggest that the Dirac physics in ZrXY compounds with X=Si,Ge and Y=S,Se,Te is closely connected to the interlayer bonding. \ 2019 American Physical Society. US.
AB - ZrSiS is a nodal-line semimetal, whose electronic band structure contains a diamond-shaped line of Dirac nodes. We carried out a comparative study on the optical conductivity of ZrSiS and the related compounds ZrSiSe, ZrSiTe, ZrGeS, and ZrGeTe by reflectivity measurements over a broad frequency range combined with density functional theory calculations. The optical conductivity exhibits a distinct U shape, ending at a sharp peak at around 10000cm-1 for all studied compounds except for ZrSiTe. The U shape of the optical conductivity is due to transitions between the linearly dispersing bands crossing each other along the nodal line. The sharp high-energy peak is related to transitions between almost parallel bands, and its energy position depends on the interlayer bonding correlated with the c/a ratio, which can be tuned by either chemical or external pressure. For ZrSiTe, another pair of crossing bands appears in the vicinity of the Fermi level, corrugating the nodal-line electronic structure and leading to the observed difference in optical conductivity. The findings suggest that the Dirac physics in ZrXY compounds with X=Si,Ge and Y=S,Se,Te is closely connected to the interlayer bonding. \ 2019 American Physical Society. US.
U2 - 10.1103/PhysRevB.99.125154
DO - 10.1103/PhysRevB.99.125154
M3 - Article
SN - 2469-9950
VL - 99
JO - Physical Review B
JF - Physical Review B
IS - 12
ER -