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A substantial hybridization between correlated Ni-d orbital and itinerant electrons in infinite-layer nickelates
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Journal Article
A substantial hybridization between correlated Ni-d orbital and itinerant electrons in infinite-layer nickelates
2020
Overview
The discovery of unconventional superconductivity in hole doped NdNiO
2
, similar to CaCuO
2
, has received enormous attention. However, different from CaCuO
2
,
R
NiO
2
(
R
= Nd, La) has itinerant electrons in the rare-earth spacer layer. Previous studies show that the hybridization between Ni-
d
x
2
−
y
2
and rare-earth-
d
orbitals is very weak and thus
R
NiO
2
is still a promising analog of CaCuO
2
. Here, we perform first-principles calculations to show that the hybridization between Ni-
d
x
2
−
y
2
orbital and itinerant electrons in
R
NiO
2
is substantially stronger than previously thought. The dominant hybridization comes from an interstitial-
s
orbital rather than rare-earth-
d
orbitals, due to a large inter-cell hopping. Because of the hybridization, Ni local moment is screened by itinerant electrons and the critical
U
Ni
for long-range magnetic ordering is increased. Our work shows that the electronic structure of
R
NiO
2
is distinct from CaCuO
2
, implying that the observed superconductivity in infinite-layer nickelates does not emerge from a doped Mott insulator.
The discovery of superconductivity in doped NdNiO
2
has generated excitement due to similarities with cuprates. Here, the authors use first-principles calculations to show that different from cuprates, a hybridization between Ni
d
-orbitals and itinerant electrons in NdNiO
2
disfavours magnetism by screening Ni moment, as in Kondo systems.
Publisher
Nature Publishing Group UK,Nature Publishing Group
