Mn-doped MgFeO3 for UV–visible optoelectronics: A combined experimental and DFT study

This study investigates the synthesis and property tuning of Mn-doped MgFeO₃ perovskites, focusing on their structural, electronic, and optical behaviors. Samples with 1 %, 3 %, and 6 % Mn doping were synthesized using a co-precipitation method. X-ray diffraction (XRD) confirmed the successful incorporation of Mn without disrupting the orthorhombic perovskite phase (Pnma space group), while changes in lattice constants and crystallite size were observed. X-ray fluorescence (XRF) verified elemental composition, and infrared (IR) spectroscopy supported the structural integrity through vibrational mode analysis. Electronic structure calculations revealed p-type semiconducting behavior in the down-spin channel, indicating spin-dependent charge transport. UV–visible spectroscopy, supported by DFT-based optical calculations, showed strong absorption in the UV–visible range up to 600 nm (∼2 eV), with intense UV absorption. The band gap showed a slight increase with Mn addition, from 1.80 eV (undoped) to 1.97 eV (6 % Mn), suggesting good band edge stability. Optical anisotropy was evident, with directional variation in absorption along the xx, yy, and zz crystallographic axes. These findings demonstrate that Mn-doped MgFeO₃ combines spin-polarized p-type conductivity, broad and intense optical absorption, and anisotropic behavior, making it a strong candidate for UV–visible polarization-sensitive photodetectors and other advanced optoelectronic sensing applications.