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Theoretical Justification of Structural, Magnetoelectronic and Optical Properties in QFeO3 (Q = Bi, P, Sb): A First-Principles Study

Amna Parveen, Zeesham Abbas, Sajjad Hussain, Shoyebmohamad F. Shaikh, Muhammad Aslam, Jongwan Jung

2023Micromachines11 citationsDOIOpen Access PDF

Abstract

One of the primary objectives of scientific research is to create state-of-the-art multiferroic (MF) materials that exhibit interconnected properties, such as piezoelectricity, magnetoelectricity, and magnetostriction, and remain functional under normal ambient temperature conditions. In this study, we employed first-principles calculations to investigate how changing pnictogen elements affect the structural, electronic, magnetic, and optical characteristics of QFeO3 (Q = Bi, P, SB). Electronic band structures reveal that BiFeO3 is a semiconductor compound; however, PFeO3 and SbFeO3 are metallic. The studied compounds are promising for spintronics, as they exhibit excellent magnetic properties. The calculated magnetic moments decreased as we replaced Bi with SB and P in BiFeO3. A red shift in the values of ε2(ω) was evident from the presented spectra as we substituted Bi with Sb and P in BiFeO3. QFeO3 (Q = Bi, P, SB) showed the maximum absorption of incident photons in the visible region. The results obtained from calculating the optical parameters suggest that these materials have a strong potential to be used in photovoltaic applications.

Topics & Concepts

PnictogenMultiferroicsSpintronicsMaterials scienceCondensed matter physicsMagnetostrictionBlueshiftMagnetic momentPiezoelectricitySemiconductorPhotonicsElectronic structureFerromagnetismNanotechnologyOptoelectronicsMagnetic fieldFerroelectricityPhysicsSuperconductivityPhotoluminescenceQuantum mechanicsDielectricComposite materialMultiferroics and related materialsFerroelectric and Piezoelectric MaterialsHeusler alloys: electronic and magnetic properties