Hydrides with the perovskite structure: General bonding and stability considerations and the new representative CaNiH3

Toyoto Sato; Dag Noréus; Hiroyuki Takeshita; Ulrich Häussermann

doi:10.1016/j.jssc.2005.08.026

Hydrides with the perovskite structure: General bonding and stability considerations and the new representative CaNiH₃

Toyoto Sato, Dag Noréus, Hiroyuki Takeshita, Ulrich Häussermann

Research output: Contribution to journal › Article › peer-review

38 Citations (Scopus)

Abstract

The stability and electronic structure of perovskite hydrides ABH ₃ were investigated by means of first-principles density functional calculations. Two types of perovskite hydrides are distinguished: (1) When A and B are alkali and alkaline earth metals, the hydrides are ionic compounds with calculated band gaps of around 2 eV and higher. Their stability trend follows basically the concept of Goldschmidt's tolerance factor. (2) When A is one of the heavier alkaline earth metals (Ca, Sr, Ba) and B a transition metal, stable compounds ABH₃ result only when B is from the Fe, Co, or Ni groups. This stability trend is basically determined by effects associated with d band filling of both the transition metal and the hydride. In contrast to group (1) perovskites, the transition metal-containing compounds are metals. The synthesis of CaNiH₃ and its structure determination from CaNiD₃ is reported. This compound is a type (2) perovskite hydride with a fully occupied hydrogen position (CaNiD₃: a=3.551(4) Å, d_Ni-D=1. 776(2) Å). Its stability is discussed with respect to transition metal hydrides with complex anions (e.g., Mg₂NiH₄, Na ₂PdH₂, Sr₂PdH₄).

Original language	English
Pages (from-to)	3381-3388
Number of pages	8
Journal	Journal of Solid State Chemistry
Volume	178
Issue number	11
DOIs	https://doi.org/10.1016/j.jssc.2005.08.026
Publication status	Published - 2005 Nov
Externally published	Yes

Keywords

First-principles calculations
Metal hydrides
Perovskite structure

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Ceramics and Composites
Condensed Matter Physics
Physical and Theoretical Chemistry
Inorganic Chemistry
Materials Chemistry

Access to Document

10.1016/j.jssc.2005.08.026

Cite this

@article{fc8f22437fa449a9aa5ce6c9e10eec29,

title = "Hydrides with the perovskite structure: General bonding and stability considerations and the new representative CaNiH3",

abstract = "The stability and electronic structure of perovskite hydrides ABH 3 were investigated by means of first-principles density functional calculations. Two types of perovskite hydrides are distinguished: (1) When A and B are alkali and alkaline earth metals, the hydrides are ionic compounds with calculated band gaps of around 2 eV and higher. Their stability trend follows basically the concept of Goldschmidt's tolerance factor. (2) When A is one of the heavier alkaline earth metals (Ca, Sr, Ba) and B a transition metal, stable compounds ABH3 result only when B is from the Fe, Co, or Ni groups. This stability trend is basically determined by effects associated with d band filling of both the transition metal and the hydride. In contrast to group (1) perovskites, the transition metal-containing compounds are metals. The synthesis of CaNiH3 and its structure determination from CaNiD3 is reported. This compound is a type (2) perovskite hydride with a fully occupied hydrogen position (CaNiD3: a=3.551(4) {\AA}, dNi-D=1. 776(2) {\AA}). Its stability is discussed with respect to transition metal hydrides with complex anions (e.g., Mg2NiH4, Na 2PdH2, Sr2PdH4).",

keywords = "First-principles calculations, Metal hydrides, Perovskite structure",

author = "Toyoto Sato and Dag Nor{\'e}us and Hiroyuki Takeshita and Ulrich H{\"a}ussermann",

note = "Funding Information: Financial support has been obtained from the HYSTORY project under the European Commission 5FP EESD program and by the Swedish Research Council (VR). H{\aa}kan Rundl{\"o}f, NFL, Studsvik, Sweden, is acknowledged for collecting the powder neutron diffraction data.",

year = "2005",

month = nov,

doi = "10.1016/j.jssc.2005.08.026",

language = "English",

volume = "178",

pages = "3381--3388",

journal = "Journal of Solid State Chemistry",

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publisher = "Academic Press Inc.",

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TY - JOUR

T1 - Hydrides with the perovskite structure

T2 - General bonding and stability considerations and the new representative CaNiH3

AU - Sato, Toyoto

AU - Noréus, Dag

AU - Takeshita, Hiroyuki

AU - Häussermann, Ulrich

N1 - Funding Information: Financial support has been obtained from the HYSTORY project under the European Commission 5FP EESD program and by the Swedish Research Council (VR). Håkan Rundlöf, NFL, Studsvik, Sweden, is acknowledged for collecting the powder neutron diffraction data.

PY - 2005/11

Y1 - 2005/11

N2 - The stability and electronic structure of perovskite hydrides ABH 3 were investigated by means of first-principles density functional calculations. Two types of perovskite hydrides are distinguished: (1) When A and B are alkali and alkaline earth metals, the hydrides are ionic compounds with calculated band gaps of around 2 eV and higher. Their stability trend follows basically the concept of Goldschmidt's tolerance factor. (2) When A is one of the heavier alkaline earth metals (Ca, Sr, Ba) and B a transition metal, stable compounds ABH3 result only when B is from the Fe, Co, or Ni groups. This stability trend is basically determined by effects associated with d band filling of both the transition metal and the hydride. In contrast to group (1) perovskites, the transition metal-containing compounds are metals. The synthesis of CaNiH3 and its structure determination from CaNiD3 is reported. This compound is a type (2) perovskite hydride with a fully occupied hydrogen position (CaNiD3: a=3.551(4) Å, dNi-D=1. 776(2) Å). Its stability is discussed with respect to transition metal hydrides with complex anions (e.g., Mg2NiH4, Na 2PdH2, Sr2PdH4).

AB - The stability and electronic structure of perovskite hydrides ABH 3 were investigated by means of first-principles density functional calculations. Two types of perovskite hydrides are distinguished: (1) When A and B are alkali and alkaline earth metals, the hydrides are ionic compounds with calculated band gaps of around 2 eV and higher. Their stability trend follows basically the concept of Goldschmidt's tolerance factor. (2) When A is one of the heavier alkaline earth metals (Ca, Sr, Ba) and B a transition metal, stable compounds ABH3 result only when B is from the Fe, Co, or Ni groups. This stability trend is basically determined by effects associated with d band filling of both the transition metal and the hydride. In contrast to group (1) perovskites, the transition metal-containing compounds are metals. The synthesis of CaNiH3 and its structure determination from CaNiD3 is reported. This compound is a type (2) perovskite hydride with a fully occupied hydrogen position (CaNiD3: a=3.551(4) Å, dNi-D=1. 776(2) Å). Its stability is discussed with respect to transition metal hydrides with complex anions (e.g., Mg2NiH4, Na 2PdH2, Sr2PdH4).

KW - First-principles calculations

KW - Metal hydrides

KW - Perovskite structure

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