P. Menegasso, J. Souza, I. Vinograd, Z. Wang, S. Edwards, P. Pagliuso, N. Curro, R. Urbano
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引用次数: 1
摘要
在重费米子物质中,原子核和电子自旋之间的超精细相互作用依赖于f电子轨道和远处原子核周围轨道之间的杂化。在CeMIn$_5$ (M=Rh, Ir, Co)中,与两个铟位点的超精细耦合以及Ce处的晶体电场都强烈依赖于过渡金属。我们测量了一系列的CeRh$_{1-x}$Ir$_x$In$_5$晶体,发现超精细耦合反映了基态ce4 $f$波函数的轨道各向异性。这些发现提供了直接的证据,证明在该体系中,定位到流动的转变主要是Ce-In平面外的杂交。
Hyperfine couplings as a probe of orbital anisotropy in heavy-fermion materials
The transferred hyperfine interaction between nuclear and electron spins in an heavy fermion material depends on the hybridization between the $f$-electron orbitals and those surrounding a distant nucleus. In CeMIn$_5$ (M=Rh, Ir, Co), both the hyperfine coupling to the two indium sites as well as the crystalline electric field at the Ce are strongly dependent on the transition metal. We measure a series of CeRh$_{1-x}$Ir$_x$In$_5$ crystals and find that the hyperfine coupling reflects the orbital anisotropy of the ground state Ce 4$f$ wavefunction. These findings provide direct proof that the localized to itinerant transition is dominated by hybridization out of the Ce-In plane in this system.
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