UTe<sub>2</sub>: a nearly insulating half-filled j=5/2, 5f<sup>3</sup> heavy fermion metal.
ORAL
Abstract
Correlated band theory implemented as a combination of
density functional theory with exact diagonalization of the Anderson
impurity model [DFT+U(ED)] is applied to UTe2.
The small gap for U=0, is converted for U=3 eV to a flat band
semimetal with small heavy-carrier Fermi surfaces that will make properties sensitive to
pressure, magnetic field, and off-stoichiometry, as observed experimentally.
The Green's function identification gives a mass enhancement
of the order of 12 for already heavy (flat) bands,
consistent with the common heavy fermion characterization of UTe2. The
predicted Kondo temperature around 100 K matches the experimental values.
The calculated uranium moment <M2>1/2 of
3.5 μB is consistent with the experimental Curie-Weiss values.
The U=3 eV electronic structure is compared
with angle-integrated and angle-resolved photoemission spectra, with
agreement that there is strong
5f character at, and for several hundred meV below, the Fermi energy.
UTe2 displays similarities to UPt3 with its 5f dominated Fermi
surfaces rather than a strongly localized Kondo lattice system.
density functional theory with exact diagonalization of the Anderson
impurity model [DFT+U(ED)] is applied to UTe2.
The small gap for U=0, is converted for U=3 eV to a flat band
semimetal with small heavy-carrier Fermi surfaces that will make properties sensitive to
pressure, magnetic field, and off-stoichiometry, as observed experimentally.
The Green's function identification gives a mass enhancement
of the order of 12 for already heavy (flat) bands,
consistent with the common heavy fermion characterization of UTe2. The
predicted Kondo temperature around 100 K matches the experimental values.
The calculated uranium moment <M2>1/2 of
3.5 μB is consistent with the experimental Curie-Weiss values.
The U=3 eV electronic structure is compared
with angle-integrated and angle-resolved photoemission spectra, with
agreement that there is strong
5f character at, and for several hundred meV below, the Fermi energy.
UTe2 displays similarities to UPt3 with its 5f dominated Fermi
surfaces rather than a strongly localized Kondo lattice system.
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Presenters
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Alexander Shick
Condensed Matter Theory, Institute of Physics, Czech Academy of Sciences
Authors
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Alexander Shick
Condensed Matter Theory, Institute of Physics, Czech Academy of Sciences
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Shin-ichi Fujimori
Materials Sciences Research Center, Japan Atomic Energy Agency
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Warren Pickett
Department of Physics, University of California Davis, University of California, Davis