Your search keyword '"Denlinger JD"' showing total 4 results

1. Electronic structure in a transition metal dipnictide TaAs 2 .

Author

Regmi S, Huang CY, Khan MA, Wang B, Pradhan Sakhya A, Hosen MM, Thompson J, Singh B, Denlinger JD, Ishigami M, Mitchell JF, Kaczorowski D, Bansil A, and Neupane M

Abstract

The family of transition-metal dipnictides has been of theoretical and experimental interest because this family hosts topological states and extremely large magnetoresistance (MR). Recently,TaAs2, a member of this family, has been predicted to support a topological crystalline insulating state. Here, by using high-resolution angle-resolved photoemission spectroscopy (ARPES), we reveal both closed and open pockets in the metallic Fermi surface (FS) and linearly dispersive bands on the (2‾01) surface, along with the presence of extreme MR observed from magneto-transport measurements. A comparison of the ARPES results with first-principles computations shows that the linearly dispersive bands on the measured surface ofTaAs2are trivial bulk bands. The absence of symmetry-protected surface state on the (2‾01) surface indicates its topologically dark nature. The presence of open FS features suggests that the open-orbit fermiology could contribute to the extremely large MR ofTaAs2., (Creative Commons Attribution license.)

Published

2023

2. Experimental electronic structure of the metallic pyrochlore iridate Bi₂Ir₂O₇.

Author

Wang Q, Cao Y, Wan XG, Denlinger JD, Qi TF, Korneta OB, Cao G, and Dessau DS

Abstract

Angle-resolved photoemission measurements have been performed on Bi2Ir2O7 single crystals, a metallic end-member of the family of pyrochlore iridates. The density of states, the Fermi surface, and the near-Fermi-level band dispersion in the plane perpendicular to the (1, 1, 1) direction were all measured and found to be in rough overall agreement with our LDA + SOC density functional calculations. Assuming that this same calculation approach will extend to other members of the pyrochlore iridates, the overall agreement we found increases the possibility that some of the novel predicted phases such as quantum spin-ice or Weyl Fermion states will exist in this family of compounds.

Published

2015

3. Angle-resolved photoemission spectroscopy observation of anomalous electronic states in EuFe2As(2-x)P(x).

Author

Richard P, Capan C, Ma J, Zhang P, Xu N, Qian T, Denlinger JD, Chen GF, Sefat AS, Fisk Z, and Ding H

Abstract

We used angle-resolved photoemission spectroscopy to investigate the electronic structure and the Fermi surface of EuFe2As2, EuFe2As1.4P0.6 and EuFe2P2. We observed doubled core level peaks associated with the pnictide atoms. Using K atoms evaporated at the surface to affect the surface quality, we show that one component of these doubled peaks is related to a surface state. Nevertheless, strong electronic dispersion along the c-axis, especially pronounced in EuFe2P2, is observed for at least one band, thus indicating that the Fe states, albeit probably affected at the surface, do not form pure two-dimensional surface states. We determine the evolution of the Fermi surface as a function of the P content and reveal that the hole Fermi surface pockets enlarge with increasing P content. We also show that the spectral weight near the Fermi level of EuFe2P2 is reduced as compared to that of EuFe2As2 and EuFe2As1.4P0.6. Finally, we identify the electronic states associated with the Eu(2+) f states and show an anomalous jump in EuFe2P2.

Published

2014

4. Photoemission spectroscopy and the unusually robust one-dimensional physics of lithium purple bronze.

Author

Dudy L, Denlinger JD, Allen JW, Wang F, He J, Hitchcock D, Sekiyama A, and Suga S

Subjects

Computer Simulation, Thermal Conductivity, Lithium chemistry, Models, Chemical, Models, Molecular, Photoelectron Spectroscopy methods, Rheology methods, Solutions chemistry

Abstract

Temperature-dependent photoemission spectroscopy in Li(0.9)Mo(6)O(17) contributes to evidence for one-dimensional (1D) physics that is unusually robust. Three generic characteristics of the Luttinger liquid are observed: power law behavior of the k-integrated spectral function down to temperatures just above the superconducting transition, k-resolved lineshapes that show holon and spinon features, and quantum critical (QC) scaling in the lineshapes. Departures of the lineshapes and the scaling from expectations in the Tomonaga-Luttinger model can be partially described by a phenomenological momentum broadening that is presented and discussed. The possibility that some form of 1D physics obtains even down to the superconducting transition temperature is assessed.

Published

2013