First‐Principles Investigations of Structural, Electronic, and Elastic Properties of ZrSiO3 Perovskite: Layer Dependence, Surface Termination, and Pressure Effects

Zirconium silicate (ZrSiO3) perovskite is a promising material for various technological applications. The structural, electronic, and thermodynamic properties of ZrSiO3 perovskite are studied under different conditions, including pressure and layer configuration variations using density functional...

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Bibliographic Details
Published in:physica status solidi (b) 2024-08, Vol.261 (8), p.n/a
Main Authors: Pokharel, Peshal, Yadav, Shashit Kumar, Pantha, Nurapati, Adhikari, Devendra
Format: Article
Language:English
Subjects:
bandgap evolutions
biomedical applications
layer‐dependent properties
surface relaxations
ZrSiO3 perovskite
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Summary:Zirconium silicate (ZrSiO3) perovskite is a promising material for various technological applications. The structural, electronic, and thermodynamic properties of ZrSiO3 perovskite are studied under different conditions, including pressure and layer configuration variations using density functional theory. The present investigation includes a thorough analysis of 2D perovskite derivatives derived from its basic 3D structure. The bulk and surface‐terminated silicon‐dominant SiO2 and zirconium‐dominant ZrO compounds are found to be mechanically stable with an anisotropy factor above 1. The calculated indirect‐bandgap values for the ZrO termination and SiO2 termination are found to be 2.585 and 1.639 eV, respectively. Moreover, the pore size of the SiO2‐terminated slab model of ZrSiO3 is calculated to be 105.39 μm and that for ZrO‐termination to be 129.30 μm. Thus, the material considered for the study can have potential applications in bone regeneration and tissue engineering. Further, the possibilities for modifying ZrSiO3 for uses in electrical devices, sensors, sustainable energy materials, and even biomedical applications like tissue engineering are intriguingly expanded by the present findings. The bulk and surface‐terminated, silicon‐dominant SiO2 and zirconium‐dominant ZrO compounds are found to be mechanically stable. The calculated pore size of the material finds potential applications in bone regeneration and tissue engineering. It can also be used in electrical devices, sensors, sustainable energy materials, and even biomedical applications.
ISSN:0370-1972
1521-3951
DOI:10.1002/pssb.202400156