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Tzitzeklis CA, Gupta JK, Dyer MS, Manning TD, Pitcher MJ, Niu HJ, Savvin S, Alaria J, Darling GR, Claridge JB, Rosseinsky MJ. Computational Prediction and Experimental Realization of p-Type Carriers in the Wide-Band-Gap Oxide SrZn 1- xLi xO 2. Inorg Chem 2018; 57:11874-11883. [PMID: 30198714 DOI: 10.1021/acs.inorgchem.8b00697] [Citation(s) in RCA: 6] [Impact Index Per Article: 1.0] [Reference Citation Analysis] [Abstract] [Track Full Text] [Journal Information] [Subscribe] [Scholar Register] [Indexed: 12/31/2022]
Abstract
It is challenging to achieve p-type doping of zinc oxides (ZnO), which are of interest as transparent conductors in optoelectronics. A ZnO-related ternary compound, SrZnO2, was investigated as a potential host for p-type conductivity. First-principles investigations were used to select from a range of candidate dopants the substitution of Li+ for Zn2+ as a stable, potentially p-type, doping mechanism in SrZnO2. Subsequently, single-phase bulk samples of a new p-type-doped oxide, SrZn1- xLi xO2 (0 < x < 0.06), were prepared. The structural, compositional, and physical properties of both the parent SrZnO2 and SrZn1- xLi xO2 were experimentally verified. The band gap of SrZnO2 was calculated using HSE06 at 3.80 eV and experimentally measured at 4.27 eV, which confirmed the optical transparency of the material. Powder X-ray diffraction and inductively coupled plasma analysis were combined to show that single-phase ceramic samples can be accessed in the compositional range x < 0.06. A positive Seebeck coefficient of 353(4) μV K-1 for SrZn1- xLi xO2, where x = 0.021, confirmed that the compound is a p-type conductor, which is consistent with the pO2 dependence of the electrical conductivity observed in all SrZn1- xLi xO2 samples. The conductivity of SrZn1- xLi xO2 is up to 15 times greater than that of undoped SrZnO2 (for x = 0.028 σ = 2.53 μS cm-1 at 600 °C and 1 atm of O2).
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Affiliation(s)
- Christos A Tzitzeklis
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Jyoti K Gupta
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Matthew S Dyer
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Troy D Manning
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Michael J Pitcher
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Hongjun J Niu
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Stanislav Savvin
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Jonathan Alaria
- Department of Physics , University of Liverpool , Liverpool , L69 7ZE , U.K
| | - George R Darling
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - John B Claridge
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
| | - Matthew J Rosseinsky
- Department of Chemistry, Materials Innovation Factory , University of Liverpool , 51 Oxford Street , Liverpool , L7 3NY , U.K
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