Abstract
The nature of superconductivity in heavy-fermion materials is a subject under intense debate, and controlling this many-body state is central for its eventual understanding. Here, we examine how proximity effects may change this phenomenon, by investigating the effects of an additional metallic layer on the top of a Kondo-lattice, and allowing for pairing in the former. We analyze a bilayer Kondo Lattice Model with an on-site Hubbard interaction, $-U$, on the additional layer, using a mean-field approach. For $U=0$, we notice a drastic change in the density-of-states due to multiple-orbital singlet resonating combinations. It destroys the well-known Kondo insulator at half filling, leading to a metallic ground state, which, in turn, enhances antiferromagnetism through the polarization of the conduction electrons. For $U\neq 0$, a superconducting Kondo state sets in at zero temperature, with the occurrence of unconventional pairing amplitudes involving $f$-electrons. We establish that this remarkable feature is only possible due to the proximity effects of the additional layer. At finite temperatures we find that the critical superconducting temperature, $T_c$, decreases with the interlayer hybridization. We have also established that a zero temperature superconducting amplitude tracks $T_c$, which reminisces the BCS proportionality between the superconducting gap and $T_c$.
Highlights
The Kondo lattice model (KLM) [1,2] and its closely related periodic Anderson model (PAM) are believed to capture some of the basic aspects of magnetism in heavy-fermion materials [3,4,5,6]
A quantum phase transition between these two tendencies takes place in the ground state, and many important physical concepts have emerged as a result of thorough investigations of these phase boundaries for the KLM, especially on a two-dimensional lattice [4,11,12,13,14,15,16,17,18,19]
Before proceeding with the effects caused by having |U | on the additional metallic layer, it is worth recalling what happens in the case of a single-layer KLM with an attractive interaction in the d band, in the regime where d and f electrons are strongly hybridized into singlets [24]
Summary
The Kondo lattice model (KLM) [1,2] and its closely related periodic Anderson model (PAM) are believed to capture some of the basic aspects of magnetism in heavy-fermion materials [3,4,5,6]. A quantum phase transition between these two tendencies takes place in the ground state, and many important physical concepts have emerged as a result of thorough investigations of these phase boundaries for the KLM, especially on a two-dimensional lattice [4,11,12,13,14,15,16,17,18,19] Another fascinating aspect of the heavy-fermion class of materials is the proximity of (and sometimes coexistence with) superconductivity and magnetic order in several compounds [20].
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