Electronic structure of the kagome compound CaTi3Bi4 using high-field torque magnetometry and density functional theory

Kyryl Shtefiienko; Cole Phillips; Brenden R. Ortiz; David E. Graf; Keshav Shrestha

doi:10.1103/5fp5-xd6m

Electronic structure of the kagome compound CaTi₃Bi₄ using high-field torque magnetometry and density functional theory

Kyryl Shtefiienko
, Cole Phillips
, Brenden R. Ortiz
, David E. Graf
, Keshav Shrestha

Correlated Electron Materials

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

Abstract

We report systematic torque magnetometry measurements to investigate the electronic properties of the newly discovered kagome compound CaTi₃Bi₄. Electrical transport, magnetic susceptibility, and thermal measurements reveal no evidence of a magnetic ground state in this material. Torque data obtained in magnetic fields up to 41.5 T exhibit clear de Haas–van Alphen (dHvA) oscillations, with nine distinct frequencies ranging from 13 to 6164 T. Angular-dependent dHvA measurements show that, with the exception of the lowest frequency (13 T), all observed frequencies nearly follow a 1/cos θ dependence, where θ is the angle between the crystallographic c axis and the magnetic field direction. This behavior is characteristic of quasi-two-dimensional Fermi-surface sheets with nearly circular cross sections. To further elucidate the electronic structure, we performed density functional theory (DFT) calculations of the band structure and Fermi surface. The calculated bands reveal the presence of multiple Dirac points (DP), flat bands (FB), and van Hove singularities (VHS) near the Fermi level. The resulting Fermi surface consists of several quasi-two-dimensional cylindrical sheets, consistent with the experimentally observed 1/cos θ dependence. Notably, the theoretical dHvA frequencies, derived from extremal Fermi-surface cross-sectional areas, agree well with the experimental values and reproduce their angular dependence. Remarkably, all experimentally observed frequencies are captured by the DFT predictions. Pressure-dependent calculations up to 10 GPa show that the electronic features—DP, FB, and VHS—evolve systematically with pressure. In particular, the VHS shifts closer to the Fermi level, demonstrating that pressure acts as an effective tuning parameter in this material. These combined experimental and theoretical results provide a comprehensive understanding of the electronic structure of CaTi₃Bi₄ and demonstrate how pressure can be used to tune its key electronic features, offering valuable guidance for exploring related kagome materials.

Original language	English
Article number	045128
Pages (from-to)	1-9
Number of pages	9
Journal	Physical Review B
Volume	113
Issue number	4
DOIs	https://doi.org/10.1103/5fp5-xd6m
State	Published - Jan 16 2026

Funding

This work was supported in part by the U.S. Department of Energy, Office of Science, Office of Workforce Development for Teachers and Scientists (WDTS) under the Visiting Faculty Program (VFP) at Los Alamos National Laboratory, administered by the Oak Ridge Institute for Science and Education. The work at West Texas A&M University (WTAMU) is supported by the Killgore Undergraduate and Graduate Student Research Grants, the Welch Foundation (Grant No. AE-0025) and the National Science Foundation (Award No. 2336011). The computations were performed on the WTAMU HPC cluster, which was funded by the National Science Foundation (NSF CC* GROWTH 2018841). Work by B.R.O. is supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES), Materials Sciences and Engineering Division. A portion of this work was performed at the National High Magnetic Field Laboratory, which is supported by National Science Foundation Cooperative Agreement No. DMR-2128556 and the State of Florida.

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title = "Electronic structure of the kagome compound CaTi3Bi4 using high-field torque magnetometry and density functional theory",

abstract = "We report systematic torque magnetometry measurements to investigate the electronic properties of the newly discovered kagome compound CaTi3Bi4. Electrical transport, magnetic susceptibility, and thermal measurements reveal no evidence of a magnetic ground state in this material. Torque data obtained in magnetic fields up to 41.5 T exhibit clear de Haas–van Alphen (dHvA) oscillations, with nine distinct frequencies ranging from 13 to 6164 T. Angular-dependent dHvA measurements show that, with the exception of the lowest frequency (13 T), all observed frequencies nearly follow a 1/cos θ dependence, where θ is the angle between the crystallographic c axis and the magnetic field direction. This behavior is characteristic of quasi-two-dimensional Fermi-surface sheets with nearly circular cross sections. To further elucidate the electronic structure, we performed density functional theory (DFT) calculations of the band structure and Fermi surface. The calculated bands reveal the presence of multiple Dirac points (DP), flat bands (FB), and van Hove singularities (VHS) near the Fermi level. The resulting Fermi surface consists of several quasi-two-dimensional cylindrical sheets, consistent with the experimentally observed 1/cos θ dependence. Notably, the theoretical dHvA frequencies, derived from extremal Fermi-surface cross-sectional areas, agree well with the experimental values and reproduce their angular dependence. Remarkably, all experimentally observed frequencies are captured by the DFT predictions. Pressure-dependent calculations up to 10 GPa show that the electronic features—DP, FB, and VHS—evolve systematically with pressure. In particular, the VHS shifts closer to the Fermi level, demonstrating that pressure acts as an effective tuning parameter in this material. These combined experimental and theoretical results provide a comprehensive understanding of the electronic structure of CaTi3Bi4 and demonstrate how pressure can be used to tune its key electronic features, offering valuable guidance for exploring related kagome materials.",

author = "Kyryl Shtefiienko and Cole Phillips and Ortiz, \{Brenden R.\} and Graf, \{David E.\} and Keshav Shrestha",

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AU - Shtefiienko, Kyryl

AU - Phillips, Cole

AU - Ortiz, Brenden R.

AU - Graf, David E.

AU - Shrestha, Keshav

PY - 2026/1/16

Y1 - 2026/1/16

N2 - We report systematic torque magnetometry measurements to investigate the electronic properties of the newly discovered kagome compound CaTi3Bi4. Electrical transport, magnetic susceptibility, and thermal measurements reveal no evidence of a magnetic ground state in this material. Torque data obtained in magnetic fields up to 41.5 T exhibit clear de Haas–van Alphen (dHvA) oscillations, with nine distinct frequencies ranging from 13 to 6164 T. Angular-dependent dHvA measurements show that, with the exception of the lowest frequency (13 T), all observed frequencies nearly follow a 1/cos θ dependence, where θ is the angle between the crystallographic c axis and the magnetic field direction. This behavior is characteristic of quasi-two-dimensional Fermi-surface sheets with nearly circular cross sections. To further elucidate the electronic structure, we performed density functional theory (DFT) calculations of the band structure and Fermi surface. The calculated bands reveal the presence of multiple Dirac points (DP), flat bands (FB), and van Hove singularities (VHS) near the Fermi level. The resulting Fermi surface consists of several quasi-two-dimensional cylindrical sheets, consistent with the experimentally observed 1/cos θ dependence. Notably, the theoretical dHvA frequencies, derived from extremal Fermi-surface cross-sectional areas, agree well with the experimental values and reproduce their angular dependence. Remarkably, all experimentally observed frequencies are captured by the DFT predictions. Pressure-dependent calculations up to 10 GPa show that the electronic features—DP, FB, and VHS—evolve systematically with pressure. In particular, the VHS shifts closer to the Fermi level, demonstrating that pressure acts as an effective tuning parameter in this material. These combined experimental and theoretical results provide a comprehensive understanding of the electronic structure of CaTi3Bi4 and demonstrate how pressure can be used to tune its key electronic features, offering valuable guidance for exploring related kagome materials.

AB - We report systematic torque magnetometry measurements to investigate the electronic properties of the newly discovered kagome compound CaTi3Bi4. Electrical transport, magnetic susceptibility, and thermal measurements reveal no evidence of a magnetic ground state in this material. Torque data obtained in magnetic fields up to 41.5 T exhibit clear de Haas–van Alphen (dHvA) oscillations, with nine distinct frequencies ranging from 13 to 6164 T. Angular-dependent dHvA measurements show that, with the exception of the lowest frequency (13 T), all observed frequencies nearly follow a 1/cos θ dependence, where θ is the angle between the crystallographic c axis and the magnetic field direction. This behavior is characteristic of quasi-two-dimensional Fermi-surface sheets with nearly circular cross sections. To further elucidate the electronic structure, we performed density functional theory (DFT) calculations of the band structure and Fermi surface. The calculated bands reveal the presence of multiple Dirac points (DP), flat bands (FB), and van Hove singularities (VHS) near the Fermi level. The resulting Fermi surface consists of several quasi-two-dimensional cylindrical sheets, consistent with the experimentally observed 1/cos θ dependence. Notably, the theoretical dHvA frequencies, derived from extremal Fermi-surface cross-sectional areas, agree well with the experimental values and reproduce their angular dependence. Remarkably, all experimentally observed frequencies are captured by the DFT predictions. Pressure-dependent calculations up to 10 GPa show that the electronic features—DP, FB, and VHS—evolve systematically with pressure. In particular, the VHS shifts closer to the Fermi level, demonstrating that pressure acts as an effective tuning parameter in this material. These combined experimental and theoretical results provide a comprehensive understanding of the electronic structure of CaTi3Bi4 and demonstrate how pressure can be used to tune its key electronic features, offering valuable guidance for exploring related kagome materials.

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JO - Physical Review B

JF - Physical Review B

IS - 4

M1 - 045128

ER -

Electronic structure of the kagome compound CaTi₃Bi₄ using high-field torque magnetometry and density functional theory

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