Hydrogen blamed for interfering with nickelate superconductors synthesis

Prof. ZHONG Zhicheng’s team at the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the Chinese Academy of Sciences has investigated the electronic structure of the recently discovered nickelate superconductors NdNiO

₂

.

They successfully explained the experimental difficulties in synthesizing superconducting nickelates, in cooperation with Prof. Karsten Held at Vienna University of Technology (TU Wien) in Austria. The findings were published in

Physical Review Letters

(

Phys. Rev. Lett.

).

In August of 2019, high-temperature superconductivity was demonstrated in nickelates (i.e., Sr-doped NdNiO

₂

), which are able to conduct electric current even at high temperatures. This seminal work heralded the nickel age of superconductivity.

However, reproducing these outstanding results appeared to be quite challenging. Other researchers even reported that their nickelates did not have superconducting properties.

To clarify this divergence, the researchers at NIMTE performed calculations based on density functional theory (DFT) and dynamical mean field theory with the help of supercomputers.

The chemical reduction of ABO

₃

(A: rare earth; B: transition metal) with CaH

₂

may result in both ABO

₂

and ABO

₂

H. The topotactic hydrogen (H) in nickelates was found to be energetically favorable for LaNiO

₂

but not for Sr-doped NdNiO

₂

, leading to dramatic consequences for the electronic structure: That of 3

d


⁹

LaNiO

₂

is similar to (doped) cuprates, while 3

d


⁸

LaNiO

₂

H is a two-orbital Mott insulator.

Therefore, H can be incorporated into the material structure of some nickelates and thus completely changes the electronic properties of the material.

Recently, this proposal was verified by researchers from the National University of Singapore (NUS). They dispersed the H that was released in the production process and succeeded in synthesizing superconducting nickelates.

The current study might account for the difficulties in synthesizing nickelate superconductors and explain why some nickelates are superconducting and others are not. In addition, the study offers suggestions for producing nickelate superconductors: with compressive strain and Sr doping, long reaction times to reduce H

₂

pressure, and low temperatures.

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