Separation of Kondo lattice coherence from crystal electric field in ${\mathrm{CeIn}}_{3}$ with Nd substitutions

Separation of Kondo lattice coherence from crystal electric field in ${CeIn}_{3}$ with Nd substitutions

Jackson R. Badger, Rumika Miyawaki, Zach E. Brubaker, Peter Klavins, Rena Zieve, Tatsuma D. Matsuda, and Valentin Taufour

Phys. Rev. B 105, 075125 – Published 14 February 2022

Abstract

The ${Ce}_{m} M_{n} {In}_{3 m + 2 n}$ $(m = 1, 2; n = 0, 1)$ family has been one of the most studied families of heavy fermion compounds. This family has revealed many interesting low-temperature physics phenomena, like quantum critical points, heavy fermion superconductivity, and non-Fermi liquid behavior, when these materials are exposed to pressure, magnetic fields, and/or chemical substitution. Here we provide a thorough investigation of the ${Ce}_{1 - x} {Nd}_{x} {In}_{3}$ phase diagram through single crystal synthesis, x-ray diffraction, energy-dispersive spectroscopy, magnetic susceptibility, and electrical resistivity measurements. Previous electrical resistivity measurements on ${CeIn}_{3}$ reveal a broad maximum, $T_{max} \sim 50$ K, which has been associated with the Kondo lattice coherence crossover and/or the crystal electric field depopulation effect as the $4 f$ electrons condense from the high-energy quartet down to the ground state doublet. Our findings show that in the most disordered substitution region, $x = 0.4 - 0.5$ , these features disjoin to reveal two distinct broad humps in electrical resistivity measurements. Magnetic susceptibility and electrical resistivity data on ${Ce}_{1 - x} {Nd}_{x} {In}_{3}$ also reveal the antiferromagnetic ordering competition between ${CeIn}_{3}$ and ${NdIn}_{3}$ , where the $T_{N}$ of ${CeIn}_{3}$ is linearly suppressed to a critical concentration of $x_{Nd} \sim 0.6$ . This concentration is slightly lower than what was previously reported in nonmagnetically substituted ${Ce}_{1 - x} {La}_{x} {In}_{3}$ . Our magnetic susceptibility measurements and subsequent simulations show that in the ${CeIn}_{3}$ antiferromagnetic regime, $x_{Nd} \leq 0.4$ , the Nd ions act as free paramagnets. The large magnitude of the associated paramagnetic response then masks the overlapping antiferromagnetic ordering signature of the Ce ions. Overall our study further sheds light on the underlying crystal electric field and Kondo lattice coherence interactions within the ${Ce}_{m} M_{n} {In}_{3 m + 2 n}$ family and could stimulate further studies of these systems via neutron diffraction or under applied pressure.

Received 8 October 2021
Revised 3 January 2022
Accepted 5 January 2022

DOI:https://doi.org/10.1103/PhysRevB.105.075125

Physics Subject Headings (PhySH)

Antiferromagnetism Electric field effects Kondo effect

Single crystal materials

Resistivity measurements

Condensed Matter, Materials & Applied Physics

Authors & Affiliations

Jackson R. Badger ¹, Rumika Miyawaki², Zach E. Brubaker ^3,*, Peter Klavins ³, Rena Zieve³, Tatsuma D. Matsuda², and Valentin Taufour ³

¹Chemistry Department, University of California, Davis, Davis, California 95616, USA
²Department of Physics, Tokyo Metropolitan University, Hachioji, Tokyo 192-0397, Japan
³Department of Physics and Astronomy, University of California, Davis, Davis, California 95616, USA

^*Present address: Oak Ridge National Laboratory, Oak Ridge, Tennessee 37831, USA.

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Vol. 105, Iss. 7 — 15 February 2022

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Figure 1
(a) PXRD patterns for single crystals when $x_{Nom} = 0$ , 0.3, 0.6, and 1. (b) Cubic lattice parameter $a$ as a function of $x_{Nom}$ within the ${Ce}_{1 - x} {Nd}_{x} {In}_{3}$ series. The unit-cell parameter $a$ for ${CeIn}_{3}$ and ${NdIn}_{3}$ are from [47] and [48], respectively. The inset shows the relationship between $x_{Nom}$ and $x_{EDS}$ . The two dotted lines are the $\pm 5 %$ error region.
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Figure 2
(a) Normalized temperature dependence of $ρ (T) / ρ (300 K)$ for representative single crystals of ${Ce}_{1 - x} {Nd}_{x} {In}_{3}$ . The red arrow shows the low-temperature maximum $T_{coh}$ for $x = 0.4$ . The inset shows examples of the peak associated with the AFM transition in the first-derivative curve, $d ρ (T) / d T$ , from ${CeIn}_{3}, {Ce}_{0.6} {Nd}_{0.4} {In}_{3}$ , and ${NdIn}_{3}$ . The arrows show the midpoint that was selected for $T_{N}^{ρ}$ . (b) $ρ_{mag} (T)$ for ${CeIn}_{3}$ and ${Ce}_{0.55} {Nd}_{0.45} {In}_{3}$ . The log scale is used to show the regions with a $- ln (T)$ relationship (dashed black lines) indicating the CEF depopulation and/or the Kondo lattice coherence effects. The inset shows the zoomed-in low-temperature region for ${Ce}_{0.55} {Nd}_{0.45} {In}_{3}$ where the second maximum, $T_{coh}$ , and $- ln (T)$ region are more easily observed.
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Figure 3
$ρ (T)$ (lines) and $M (T) / H$ (squares) for $x = 0.4$ (green), 0.45 (red), 0.5 (blue), and 0.6 (orange). The purple vertical lines show the location of the $T_{N}$ from $ρ (T)$ data and the black arrows shows the location of $T_{coh}$ .
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Figure 4
Schematics of the temperature dependence of the electrical resistivity for a Kondo lattice (ignoring phonon contributions). (a) the CEF splitting energy $Δ_{CEF}$ is smaller than the Kondo coherence energy scale $T_{coh}$ . (b) $Δ_{CEF}$ and $k_{B} T_{coh}$ are of similar magnitude. (c), (d) $k_{B} T_{coh}$ is smaller than $Δ_{CEF}$ . In cubic symmetry (c), there are two resistivity maxima associated with the coherence and CEF effects. In hexagonal or tetragonal symmetries (d), there can be a third maxima associated with the additional CEF energy splitting.
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Figure 5
(a) Temperature dependence of $M (T) / H$ from selected samples in the ${Ce}_{1 - x} {Nd}_{x} {In}_{3}$ series. These measurements were collected in a $μ_{0} H = 1$ T field. Given the cubic nature of structure, crystal orientation was not accounted for. Inset shows the low-temperature region of the susceptibility curves for $x_{Nd} = 0.2 - 1$ . (b) The experimental data for $x_{Nd} = 0.1, 0.2$ , and 0.3 are shown by the lines with triangles. The solids lines represent the simulated data for the respective values of $x_{Nd}$ . For these simulations, the calculated $μ_{eff}$ for a ${Nd}^{3 +}$ of $3.62 μ_{B}$ and a Curie-Weiss constant of $θ = - 6.67$ K were employed to represent the Nd magnetic contributions. The arrow shows the slight kink where the ${Ce}^{3 +}$ AFM transition is experimentally observed from ${Ce}_{0.9} {Nd}_{0.1} {In}_{3}$ . Inset: the temperature derivative of the $M (T) / H$ curve for $x = 0.1$ which better shows the transition as a maximum.
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Figure 6
Observed features from $ρ (T)$ and $M (T) / H$ curves as a function of $x_{Nd}$ for ${Ce}_{1 - x} {Nd}_{x} {In}_{3}$ . The two AFM regions, ${AFM}_{Ce}$ and ${AFM}_{Nd}$ , show the Nd concentrations where the ${CeIn}_{3}$ and ${NdIn}_{3}$ AFM structures, respectively, are dominant. The dotted black line is the linear fit of $T_{N}^{ρ}$ and $T_{N}^{M}$ for the ${CeIn}_{3}$ region when $x_{Nd} \leq 0.4$ . The solid black line is the linear fit of the second maximum, $T_{coh}$ , for $x = 0.4, 0.45$ , and 0.5.
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Physical Review B

covering condensed matter and materials physics

Separation of Kondo lattice coherence from crystal electric field in ${CeIn}_{3}$ with Nd substitutions

Jackson R. Badger, Rumika Miyawaki, Zach E. Brubaker, Peter Klavins, Rena Zieve, Tatsuma D. Matsuda, and Valentin Taufour

Phys. Rev. B 105, 075125 – Published 14 February 2022

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Physical Review B

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Separation of Kondo lattice coherence from crystal electric field in CeIn3 with Nd substitutions

Jackson R. Badger, Rumika Miyawaki, Zach E. Brubaker, Peter Klavins, Rena Zieve, Tatsuma D. Matsuda, and Valentin Taufour

Phys. Rev. B 105, 075125 – Published 14 February 2022

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Separation of Kondo lattice coherence from crystal electric field in ${CeIn}_{3}$ with Nd substitutions