Theory of the Susceptibility of CeB6

Nickerson, J. Charles; White, Robert M.

doi:10.1063/1.1657507

Cited by 28 publications

(6 citation statements)

References 4 publications

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“…The goal of this review is to draw a coherent picture from the myriad of investigations which have been done into CeB 6 and its doped derivatives such as Ce 1−x La x B 6 since its original synthesis in 1932 [1]. Following its discovery, much attention was paid to its potential as a cathode material [2], with some early interest in the following decades regarding its physical behaviour [3][4][5][6] before modern condensed matter physics became interested in its magnetic ordering phenomena.…”

Section: Introductionmentioning

confidence: 99%

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce_1−xLa_xB₆

2016

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Cerium hexaboride is a cubic f-electron heavy-fermion compound that displays a rich array of low-temperature magnetic ordering phenomena which have been the subject of investigation for more than 50 years. Its complex behaviour is the result of competing interactions, with both itinerant and local electrons playing important roles. Investigating this material has proven to be a substantial challenge, in particular because of the appearance of a 'magnetically hidden order' phase, which remained elusive to neutron-scattering investigations for many years. It was not until the development of modern x-ray scattering techniques that the long suspected multipolar origin of this phase was confirmed. Doping with non-magnetic lanthanum dilutes the magnetic cerium sublattice and reduces the f-electron count, bringing about substantial changes to the ground state with the emergence of new phases and quantum critical phenomena. To this day, Ce1-x La x B6 and its related compounds remain a subject of intense interest. Despite the substantial progress in understanding their behaviour, they continue to reveal new and unexplained physical phenomena. Here we present a review of the accumulated body of knowledge on this family of materials in order to provide a firm standpoint for future investigations.

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Section: Introductionmentioning

confidence: 99%

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce_1−xLa_xB₆

2016

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“…Cross section view of the cryogcuic lraradoy lialance. Legend: 1) Eleutroriic balance vacuum jar, 2) sample ~I ' C C Y S port, 3) glass-to-metal O-ring seal, 4) elcctrieal conilcetor, 5 ) safrty valve, 6) vacuum chamber, 7) magnet pole cap, 8 ) tare weight pan, 9) liquid helium bayonet connector; 10) helium pumping port, 11) deaar cvacurtion valve, 12 The susccptibilities of the light rare earth hexaborides, with the exception of SmB,, can be reasonably described by Curie-Weiss laws with effective moments close to the Hund freeion values. I n the case of SmB,, the susceptibility has unusual behavior that has been attributed by Ment,h et al [5] and Cohen et, al.…”

Section: Introductionmentioning

confidence: 99%

Magnetic properties of CeB6, PrB6, EuB6, and GdB6

Hacker

Shimada

Chung

1971

Phys. Stat. Sol. (a)

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The results of a study of the magnetic properties of the hexaborides of cerium, praseodymium, europium, and gadolinium at temperatures from 7 to 300 °K are reported. The susceptibility of CeB6 obeys a Curie‐Weiss law, χ = C/(T – θ), above 200 °K with a moment of 2.51 μβ and θ = −82 °K. PrB6 obeys a Curie‐Weiss law above 100 °K with a moment of 3.64 μβ and θ = −41 °K. The reciprocal susceptibility of PrB6 shows a minimum at 8.3 °K associated with an antiferromagnetic transition. Europium hexaboride is ferromagnetic at low temperatures with a Curie point of 8.8 °K. The initial reciprocal susceptibility in the range from 9 to 14 °K varies at (T – TC)1,20. Above 30 °K the susceptibility of EuB6 accurately obeys a Curie‐Weiss law with θ = −0.5 °K and μeff = 7.90 μβ. Magnetization curves and isotherms of σ2 vs. H/σ are given for EuB6 for temperatures just above the Curie point. The susceptibility of GdB6 obeys a Curie‐Weiss law above 70 °K with θ = −66.5 °K and μeff = 7.98 μβ. Further, an antiferromagnetic transition exists at (16.4 ± 0.2) °K. Finally, X‐ray diffraction data were obtained for the four compounds yielding lattice constants of 4.140 Å, 4.131 Å, 4.175 Å, and 4.109 Å for CeB6, PrB6, EuB6, and GdB6 respectively.

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“…36 Initially Ce 3+ multiplet 4f 1 was thought to be split by the crystalline electric field into a Γ 7 ground state with a Γ 8 excited state. 38 However, this was later reversed to the Γ 8 quartet ground state, which is four-fold degenerate with 2-orbital and 2-spin degrees of freedom, located 46 meV below the Γ 7 doublet state. 23,39,40 Our present results give ∼62 meV separation between Γ 7 and Γ 8 , reflecting experimentally findings.…”

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Revealing the Nature of Antiferroquadrupolar Ordering in Cerium Hexaboride: CeB6

et al. 2019

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Cerium-hexaboride (CeB6) f-electron compound displays a rich array of low-temperature magnetic phenomena, including 'magnetically hidden' order, identified as multipolar in origin via advanced x-ray scattering. From first-principles electronic-structure results, we find that the antiferroquadrupolar (AFQ) ordering in CeB6 arises from crystal-field splitting and yields band structure in agreement with experiments. With interactions of p-electrons between Ce and B6 being small, the electronic state of CeB6 is suitably described as Ce(4f 1 ) 3+ (e − )(B6) 2− . The AFQ state of orbital spins is caused by an exchange interaction induced through spin-orbit interaction, which also splits J=5/2 state into Γ8 ground state and Γ7 excited state. Within the smallest antiferromagnetic (111) configuration, an orbital-ordered AFQ state appears during charge self-consistency, and supports the appearance of 'hidden' order. Hydrostatic pressure (either applied or chemically induced) stabilizes the AFM (AFQ) states over a ferromagnetic one, as observed at low temperatures. arXiv:1809.06257v2 [cond-mat.mtrl-sci]

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Theory of the Susceptibility of CeB6

Cited by 28 publications

References 4 publications

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce_1−xLa_xB₆

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce_1−xLa_xB₆

Magnetic properties of CeB6, PrB6, EuB6, and GdB6

Revealing the Nature of Antiferroquadrupolar Ordering in Cerium Hexaboride: CeB6

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Theory of the Susceptibility of CeB6

Cited by 28 publications

References 4 publications

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce1−xLaxB6

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce1−xLaxB6

Magnetic properties of CeB6, PrB6, EuB6, and GdB6

Revealing the Nature of Antiferroquadrupolar Ordering in Cerium Hexaboride: CeB6

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Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce_1−xLa_xB₆

Multipolar phases and magnetically hidden order: review of the heavy-fermion compound Ce_1−xLa_xB₆