Magnetoelastic coupling, negative thermal expansion, and two-dimensional magnetic excitations in FeAs

We present a temperature-dependent investigation of the local structure and magnetic dynamics of the FeAs binary. The magnetic susceptibility χ(T) result shows an anomalous broad feature up to 550 K, with χ continuing to increase above the Néel antiferromagnetic ordering temperature (TN=70K), peakin...

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Bibliographic Details
Published in:Physical review. B 2021-03, Vol.103 (9), p.1, Article 094431
Main Authors: Niedziela, J. L., Sanjeewa, L. D., Podlesnyak, A. A., DeBeer-Schmitt, L., Kuhn, S. J., de la Cruz, C., Parker, D. S., Page, K., Sefat, A. S.
Format: Article
Language:English
Subjects:
Antiferromagnetism
Arsenides
Breeding grounds
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
Crystal structure
Distribution functions
Dynamic structural analysis
Excitation
Inelastic neutron scattering
Inelastic scattering
Iron
Iron-based superconductors
Magnetic permeability
Magnetic properties
Magnetic transitions
Magnetic variations
Magnons
Neutron pair-distribution function analysis
Neutron scattering
Neutrons
Superconductors
Temperature
Temperature dependence
Thermal expansion
Transition metals
Unconventional superconductivity
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Summary:We present a temperature-dependent investigation of the local structure and magnetic dynamics of the FeAs binary. The magnetic susceptibility χ(T) result shows an anomalous broad feature up to 550 K, with χ continuing to increase above the Néel antiferromagnetic ordering temperature (TN=70K), peaking at ∼250 K, then decreasing gently above. It is remarkable that this peak susceptibility temperature corresponds to the onset of anisotropic negative thermal expansion in both the a and c axes, suggesting that magnetic interactions are affecting the structure even well above the Néel point. A systematic investigation into local bonding correlations, from time-of-flight neutron pair distribution function analyses, shows the octahedral volume around each Fe site growing monotonically while adjacent octahedra tilt toward one another before relaxing away past this peak in the anomalous magnetic susceptibility. We use inelastic-neutron scattering to map spin-wave excitations in FeAs at temperatures above and below the TN. We find magnetic excitations near TN to be very different from the excitations in the ground state at 1.5 K. Spin waves measured at 1.5 K are three dimensional (3D), however, in the vicinity of the magnetic transition, the magnetic fluctuations clearly indicate two-dimensional (2D) character in this intrinsically 3D crystal structure. Unlike the undoped 2D parents of iron-arsenide superconductors, where the magnetic correlations are considerably weaker along the c axis than in the ab plane, inelastic neutron scattering here shows that the spin fluctuations in the 3D FeAs binary are nearly 2D in the bc plane at 90 K. These results demonstrate the importance of short-range correlations in understanding the magnetic properties of transition-metal binaries, and suggest how 2D excitations, even in a 3D structure, can potentially become a breeding ground for unconventional superconductivity.
ISSN:2469-9950
2469-9969
DOI:10.1103/PhysRevB.103.094431