Tunable resistivity exponents in the metallic phase of epitaxial nickelates

Abstract: We report a detailed analysis of the electrical resistivity exponent of thin films of NdNiO 3 as a function of epitaxial strain. Thin films under low strain conditions show a linear dependence of the resistivity versus temperature, consistent with a classical Fermi gas ruled by electronphonon interactions. In addition, the apparent temperature exponent, n, can be tuned with the epitaxial strain between n = 1 and n = 3. We discuss the critical role played by quenched random disorder in the value of n. Our work … Show more

“…To gain further insights into the thickness-dependent MIT, we fit the metallic resistivity of the SLs with n ≥ 3 using the power law ρ = ρ 0 + AT α , where the parameter A is determined by the strength of the electron scattering. 44 The power-law exponent α is found to increase from α = 1.0 ± 0.1 for n ≥ 5 to α = 1.90 ± 0.01 for n = 4 and end up with α = 3.14 ± 0.01 for n = 3 ( Figure S5 ). The departure from a linear scaling in perovskite nickelates has been ascribed to a joint effect of epitaxial strain and oxygen vacancies.…”

“…The departure from a linear scaling in perovskite nickelates has been ascribed to a joint effect of epitaxial strain and oxygen vacancies. 44 Considering the fact that all SLs are coherently strained to the NGO substrate, the larger α for n = 3, 4 is probably due to the increasing amounts of oxygen vacancies with ultrathin NNO layers. This can also contribute to the enhanced resistivity and T MIT by creating local disproportionation of NiO 6 octahedra.…”

Spatially Controlled Octahedral Rotations and Metal–Insulator Transitions in Nickelate Superlattices

“…To gain further insights into the thickness-dependent MIT, we fit the metallic resistivity of the SLs with n ≥ 3 using the power law ρ = ρ 0 + AT α , where the parameter A is determined by the strength of the electron scattering. 44 The power-law exponent α is found to increase from α = 1.0 ± 0.1 for n ≥ 5 to α = 1.90 ± 0.01 for n = 4 and end up with α = 3.14 ± 0.01 for n = 3 ( Figure S5 ). The departure from a linear scaling in perovskite nickelates has been ascribed to a joint effect of epitaxial strain and oxygen vacancies.…”

“…The departure from a linear scaling in perovskite nickelates has been ascribed to a joint effect of epitaxial strain and oxygen vacancies. 44 Considering the fact that all SLs are coherently strained to the NGO substrate, the larger α for n = 3, 4 is probably due to the increasing amounts of oxygen vacancies with ultrathin NNO layers. This can also contribute to the enhanced resistivity and T MIT by creating local disproportionation of NiO 6 octahedra.…”

Spatially Controlled Octahedral Rotations and Metal–Insulator Transitions in Nickelate Superlattices

“…2d, a cuprate-like linear-T -resistivity is observed in NNO in a ultra-wide temperature range (about 400 K). In our previous works, we showed that this T -linear behaviour of resistivity can be achieved in optimized NNO films with low epitaxial strain and low oxygen vacancy content [34] and, more interestingly, it has signatures of Planckian dissipation [35]. With the further increase of T, the rise of ρ(T) shows an obvious deviation from the linear dependence, which is caused by the addition of a parallel saturation resistance that takes over the behaviour in the high temperature regime [4,13,29].…”

“…In fact, this compound is attracting significant attention, since superconductivity was reported in the infinite layer system Nd 1−x Sr x NiO 2 [31], and is a remarkable example of a material whose metallic behavior has been particularly difficult to classify [25,32,33]. For the present study we have used high quality epitaxial NNO films grown on LaAlO 3 substrates, which have been characterized in detail in our previous work [34,35]. High-angle annular dark field (HAADF) STEM image shown in Supplementary Section 1 demonstrates the high crystalline quality of the NNO films with an atomically sharp interface with the substrate.…”

Phenomenological classification of metals based on resistivity

“…These perovskite nickelates have been grown by various techniques. The most popular is pulsed laser deposition (PLD) [18][19][20][21], but sputtering [22,23] and molecular beam epitaxy [24] have also been used. At this stage, the main difficulty lies in the stabilization of the unfavorable high 3+ valence of Ni (instead of its most preferred 2+), reproducibility and off-stoichiometry issues have been reported in the literature [25].…”

Thin-Film Aspects of Superconducting Nickelates