Your search keyword '"Rai, Binod K"' showing total 5 results

1. Unconventional magnetic order emerging from competing energy scales in the new RRh3Si7 intermetallics (R = Gd-Yb)

Author

Qian, Long, Lei, Shiming, Rai, Binod K., Huang, C.-L., Hallas, Alannah M., McCandless, Gregory T., Chan, Julia Y., Morosan, E., Qian, Long, Lei, Shiming, Rai, Binod K., Huang, C.-L., Hallas, Alannah M., McCandless, Gregory T., Chan, Julia Y., and Morosan, E.

Abstract

The competition between Ruderman-Kittel-Kasuya-Yosida (RKKY), crystal electric field (CEF), and Kondo energy scales has recently emerged at the heart of complex magnetism in several Ce- or Yb-based intermetallics. Hard axis magnetic order has been observed in a handful of these compounds, independent of the crystal symmetry, size of the ordered moment, or the relative scale of the Kondo and magnetic ordering temperatures. This raises the question of the role of each energy scale in driving the ground state properties. In focusing on a single class of compounds, the rhombohedral R, we compare the anisotropy and magnetic ground states in members of this series with only RKKY interactions (R = Gd), or RKKY and CEF effects (R = Tb-Tm), with the behavior of the R = Yb compound, where all three energy scales (RKKY, CEF, Kondo) are at play. Moreover, we extend the comparison to two other isostructural Kondo systems and , where hard axis magnetic order is also observed. The non-Kondo compounds R (R = Tb-Tm) lack the complexity of magnetic order along the hard CEF axis, pointing to the dominant role of the Kondo effect in driving this magnetic order. However, the CEF-RKKY competition is still responsible for complex magnetic ground states, and it appears that the electronic and magnetic degrees of freedom are entangled in all magnetic members of this series of compounds. ©2021 American Physical Society

Published

2021

2. Intermediate valence to heavy fermion through a quantum phase transition in Yb3(Rh1-xTx)4Ge13 (T = Co, Ir) single crystals.

Author

Rai, Binod K., Oswald, Iain W. H., Chan, Julia Y., and Morosan, E.

Subjects

*FERMIONS, *QUANTUM phase transitions, *YTTERBIUM compounds, *SINGLE crystals, *CRYSTAL growth

Abstract

Single crystals of Yb3(Rh1-xTx )4Ge13 (T = Co, Ir) have been grown using the self-flux method. Powder x-ray diffraction data on these compounds are consistent with the cubic structure with space group Pm3n. Intermediate-valence behavior is observed in Yb3(Rh1-xTx )4Ge13 upon T = Co doping, while T = Ir doping drives the system into a heavy-fermion state. Antiferromagnetic order is observed in the Ir-doped samples Yb3(Rh1-xTx )4Ge13 for 0.5 < x ⩽ 1 with TN = 0.96 K for Yb3Ir3Ge13. With decreasing x, the magnetic order is suppressed towards a quantum critical point around Xc = 0.5, accompanied by non-Fermi-liquid behavior evidenced by logarithmic divergence of the specific heat and linear temperature dependence of the resistivity. The Fermi-liquid behavior is recovered with the application of large magnetic fields. [ABSTRACT FROM AUTHOR]

Published

2016

3. Magnetic Interactions of the Centrosymmetric Skyrmion Material Gd&#95;{2}PdSi&#95;{3}.

Author

Paddison JAM, Rai BK, May AF, Calder S, Stone MB, Frontzek MD, and Christianson AD

Abstract

The experimental realization of magnetic skyrmion crystals in centrosymmetric materials has been driven by theoretical understanding of how a delicate balance of anisotropy and frustration can stabilize topological spin structures in applied magnetic fields. Recently, the centrosymmetric material Gd&#95;{2}PdSi&#95;{3} was shown to host a field-induced skyrmion crystal, but the skyrmion stabilization mechanism remains unclear. Here, we employ neutron-scattering measurements on an isotopically enriched polycrystalline Gd&#95;{2}PdSi&#95;{3} sample to quantify the interactions that drive skyrmion formation. Our analysis reveals spatially extended interactions in triangular planes, and large ferromagnetic interplanar magnetic interactions that are modulated by the Pd/Si superstructure. The skyrmion crystal emerges from a zero-field helical magnetic order with magnetic moments perpendicular to the magnetic propagation vector, indicating that the magnetic dipolar interaction plays a significant role. Our experimental results establish an interaction space that can promote skyrmion formation, facilitating identification and design of centrosymmetric skyrmion materials.

Published

2022

4. Low-carrier density and fragile magnetism in a Kondo lattice system.

Author

Rai BK, H Oswald IW, Ban W, Huang CL, Loganathan V, Hallas AM, Wilson MN, Luke GM, Harriger L, Huang Q, Li Y, Dzsaber S, Chan JY, Wang NL, Paschen S, Lynn JW, Nevidomskyy AH, Dai P, Si Q, and Morosan E

Abstract

Kondo-based semimetals and semiconductors are of extensive current interest as a viable platform for strongly correlated states in the dilute carrier limit. It is thus important to explore the routes to understand such systems. One established pathway is through the Kondo effect in metallic nonmagnetic analogs, in the so called half-filling case of one conduction electron and one 4 f electron per site. Here, we demonstrate that Kondo-based semimetals develop out of conduction electrons with a low-carrier density in the presence of an even number of rare-earth sites. We do so by studying the Kondo material Yb 3 Ir 4 Ge 13 along with its closed-4 f -shell counterpart, Lu 3 Ir 4 Ge 13 . Through magnetotransport, optical conductivity, and thermodynamic measurements, we establish that the correlated semimetallic state of Yb 3 Ir 4 Ge 13 below its Kondo temperature originates from the Kondo effect of a low-carrier conduction-electron background. In addition, it displays fragile magnetism at very low temperatures, which in turn, can be tuned to a Griffiths-phase-like regime through Lu-for-Yb substitution. These findings are connected with recent theoretical studies in simplified models. Our results can pave the way to exploring strong correlation physics in a semimetallic environment.

Published

2019

5. Anomalous Metamagnetism in the Low Carrier Density Kondo Lattice YbRh 3 Si 7 .

Author

Rai BK, Chikara S, Ding X, Oswald IWH, Schönemann R, Loganathan V, Hallas AM, Cao HB, Stavinoha M, Chen T, Man H, Carr S, Singleton J, Zapf V, Benavides KA, Chan JY, Zhang QR, Rhodes D, Chiu YC, Balicas L, Aczel AA, Huang Q, Lynn JW, Gaudet J, Sokolov DA, Walker HC, Adroja DT, Dai P, Nevidomskyy AH, Huang CL, and Morosan E

Abstract

We report complex metamagnetic transitions in single crystals of the new low carrier Kondo antiferromagnet YbRh 3 Si 7 . Electrical transport, magnetization, and specific heat measurements reveal antiferromagnetic order at T N = 7.5 K . Neutron diffraction measurements show that the magnetic ground state of YbRh 3 Si 7 is a collinear antiferromagnet, where the moments are aligned in the ab plane. With such an ordered state, no metamagnetic transitions are expected when a magnetic field is applied along the c axis. It is therefore surprising that high-field magnetization, torque, and resistivity measurements with H ‖ c reveal two metamagnetic transitions at μ 0 H 1 = 6.7 T and μ 0 H 2 = 21 T . When the field is tilted away from the c axis, towards the ab plane, both metamagnetic transitions are shifted to higher fields. The first metamagnetic transition leads to an abrupt increase in the electrical resistivity, while the second transition is accompanied by a dramatic reduction in the electrical resistivity. Thus, the magnetic and electronic degrees of freedom in YbRh 3 Si 7 are strongly coupled. We discuss the origin of the anomalous metamagnetism and conclude that it is related to competition between crystal electric-field anisotropy and anisotropic exchange interactions.

Published

2018