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Hauptverfasser: Nedić, Ana-Marija, Christensen, Morten H., Lee, Y., Li, Bing, Ueland, Benjamin G., Fernandes, Rafael M., McQueeney, Robert J., Ke, Liqin, Orth, Peter P.
Format: Preprint
Veröffentlicht: 2022
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Online-Zugang:https://arxiv.org/abs/2212.07511
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author Nedić, Ana-Marija
Christensen, Morten H.
Lee, Y.
Li, Bing
Ueland, Benjamin G.
Fernandes, Rafael M.
McQueeney, Robert J.
Ke, Liqin
Orth, Peter P.
author_facet Nedić, Ana-Marija
Christensen, Morten H.
Lee, Y.
Li, Bing
Ueland, Benjamin G.
Fernandes, Rafael M.
McQueeney, Robert J.
Ke, Liqin
Orth, Peter P.
contents We revisit the intriguing magnetic behavior of the paradigmatic itinerant frustrated magnet $\rm{Sr}\rm{Co}_2\rm{As}_2$, which shows strong and competing magnetic fluctuations yet does not develop long-range magnetic order. By calculating the static spin susceptibility $χ(\mathbf{q})$ within a realistic sixteen orbital Hubbard-Hund model, we determine the leading instability to be ferromagnetic (FM). We then explore the effect of doping and calculate the critical Hubbard interaction strength $U_c$ that is required for the development of magnetic order. We find that $U_c$ decreases under electron doping and with increasing Hund's coupling $J$, but increases rapidly under hole doping. This suggests that magnetic order could possibly emerge under electron doping but not under hole doping, which agrees with experimental findings. We map out the leading magnetic instability as a function of doping and Hund's coupling and find several antiferromagnetic phases in addition to FM. We also quantify the degree of itinerant frustration in the model and resolve the contributions of different orbitals to the magnetic susceptibility. Finally, we discuss the dynamic spin susceptibility, $χ(\mathbf{q}, ω)$, at finite frequencies, where we recover the anisotropy of the peaks at $\mathbf{Q}_π= (π, 0)$ and $(0, π)$ observed by inelastic neutron scattering that is associated with the phenomenon of itinerant magnetic frustration. By comparing results between theory and experiment, we conclude that the essential experimental features of doped SrCo$_2$As$_2$ are well captured by a Hubbard-Hund multiorbital model if one considers a small shift of the chemical potential towards hole doping.
format Preprint
id arxiv_https___arxiv_org_abs_2212_07511
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Competing magnetic fluctuations and orders in a multiorbital model of doped SrCo$_2$As$_2$
Nedić, Ana-Marija
Christensen, Morten H.
Lee, Y.
Li, Bing
Ueland, Benjamin G.
Fernandes, Rafael M.
McQueeney, Robert J.
Ke, Liqin
Orth, Peter P.
Strongly Correlated Electrons
We revisit the intriguing magnetic behavior of the paradigmatic itinerant frustrated magnet $\rm{Sr}\rm{Co}_2\rm{As}_2$, which shows strong and competing magnetic fluctuations yet does not develop long-range magnetic order. By calculating the static spin susceptibility $χ(\mathbf{q})$ within a realistic sixteen orbital Hubbard-Hund model, we determine the leading instability to be ferromagnetic (FM). We then explore the effect of doping and calculate the critical Hubbard interaction strength $U_c$ that is required for the development of magnetic order. We find that $U_c$ decreases under electron doping and with increasing Hund's coupling $J$, but increases rapidly under hole doping. This suggests that magnetic order could possibly emerge under electron doping but not under hole doping, which agrees with experimental findings. We map out the leading magnetic instability as a function of doping and Hund's coupling and find several antiferromagnetic phases in addition to FM. We also quantify the degree of itinerant frustration in the model and resolve the contributions of different orbitals to the magnetic susceptibility. Finally, we discuss the dynamic spin susceptibility, $χ(\mathbf{q}, ω)$, at finite frequencies, where we recover the anisotropy of the peaks at $\mathbf{Q}_π= (π, 0)$ and $(0, π)$ observed by inelastic neutron scattering that is associated with the phenomenon of itinerant magnetic frustration. By comparing results between theory and experiment, we conclude that the essential experimental features of doped SrCo$_2$As$_2$ are well captured by a Hubbard-Hund multiorbital model if one considers a small shift of the chemical potential towards hole doping.
title Competing magnetic fluctuations and orders in a multiorbital model of doped SrCo$_2$As$_2$
topic Strongly Correlated Electrons
url https://arxiv.org/abs/2212.07511