压力对SrNbO3机电性能影响的DFT研究

IF 1.1 4区工程技术 Q4 Engineering

High Temperatures-high Pressures Pub Date : 2020-01-01 DOI:10.32908/hthp.v48.763

Saad Tariq, A. Batool, M. Faridi, M. Jamil, A. Mubarak, Nosheen Akbar

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引用次数: 2

摘要

在密度泛函理论的框架下，结合Wien2k代码中的GGA(广义梯度近似)，对SrNbO3 (SNO)的结构、电子和力学性能进行了研究。发现SNO的自旋极化相在60 GPa时最稳定，计算出的晶格常数为3.801 Å。计算得到的晶格常数和体积模量与文献相符。目前的计算预测，SNO在60 GPa时是稳定的和反铁磁性的。计算得到的电荷密度轮廓和柯西压力表明，SNO含量原子之间的键合性质大部分是离子键，共价键的贡献很小。发现带隙从0 GPa下的间接R-Г隙到60 GPa下更宽的直接Г-Г隙。此外，计算的弹性常数C11、C12和C44表明，该化合物在60 GPa以下稳定，具有延性和各向异性。展望了SNO在光电领域的有益电子和机械应用。

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Influence of pressure on electro-mechanical properties of SrNbO3: A DFT study

In the enclosure of density functional theory along with GGA (generalized gradient approximation), incorporated in Wien2k code has been utilized to explore structural, electronic and mechanical properties of SrNbO3 (SNO). It has been found that spin-polarized phase of SNO is most stable at 60 GPa with the calculated lattice constant of 3.801 Å. The calculated lattice constant and bulk modulus at 0 GPa are found to be in agreement with literature. The present calculations predict that SNO is stable and antiferromagnetic in nature up to 60 GPa. The calculated charge density contours and Cauchy pressure depicts majority of the bonding nature between the content atoms of SNO is ionic with a small contribution of covalent bond. The band-gap is found traverse from indirect R-Г gap under 0 GPa to wider direct Г-Г gap under 60 GPa. Furthermore, calculated elastic constants, C11, C12 and C44 suggest that compound is stable up to 60 GPa and exhibits ductile, anisotropic nature. Beneficial electronic and mechanical applications are predicted for SNO that could be used in optoelectronic applications.

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来源期刊

High Temperatures-high Pressures THERMODYNAMICS-MECHANICS

CiteScore

1.00

自引率

9.10%

发文量

期刊介绍： High Temperatures – High Pressures (HTHP) is an international journal publishing original peer-reviewed papers devoted to experimental and theoretical studies on thermophysical properties of matter, as well as experimental and modelling solutions for applications where control of thermophysical properties is critical, e.g. additive manufacturing. These studies deal with thermodynamic, thermal, and mechanical behaviour of materials, including transport and radiative properties. The journal provides a platform for disseminating knowledge of thermophysical properties, their measurement, their applications, equipment and techniques. HTHP covers the thermophysical properties of gases, liquids, and solids at all temperatures and under all physical conditions, with special emphasis on matter and applications under extreme conditions, e.g. high temperatures and high pressures. Additionally, HTHP publishes authoritative reviews of advances in thermophysics research, critical compilations of existing data, new technology, and industrial applications, plus book reviews.