Abstract
In this research, we have explored the structural, morphological, electrical, and magnetic properties of Mn2+ substituted polycrystalline Ba0.4Ca0.4Sr0.2MnxTi1−xO3 (where x = 0.0, 0.05, 0.10, 0.15, and 0.20) ceramic samples prepared by the standard solid-state reaction system. The x-ray diffraction pattern of the 20% Mn-doped BCSMTO sample has confirmed a cubic to tetragonal structural phase transition. The lattice parameter is found to increase at 15% and 20% Mn concentrations, which is caused due to the inequality in ionic radii of cations. Scanning electron microscope analysis exhibited that, with the increase in Mn contents (x = 0.0–0.15), the average grain size of the samples gets bigger but then significantly decreased at 20% Mn substitution. Dielectric constants for all the samples are higher for lower frequency regions and remain independent at a higher frequency domain. The initial permeability remains almost constant at lower frequencies and then sharply falls at the cut-off frequency, which is in agreement with the Globus model. Among all the studied samples, the 10% Mn-doped ceramic sample shows the highest relative quality factor with significantly demolished loss (tan δM). At room temperature, the M–H loop for the 10% Mn-doped sample demonstrates a domination of diamagnetic nature at a higher magnetic field. The decrement in saturation magnetization with Mn addition suggests that the double-exchange interactions in tetragonal BaTiO3 may have been weakened. The outcome of this analysis emphasizes the impact of Mn as a doping element with 10% concentration in Ba0.4Ca0.4Sr0.2MnxTi1−xO3 that provides enhanced structural and electrical properties, which are associated with homogeneous grain size, reduced porosity, and lower tangent loss.
Highlights
In recent years, polycrystalline ferroelectric ceramics have received considerable attention compared to single crystals because of their ease of preparation and acquisition of various desired properties by compositional modifications.1,2 Ferroelectric ceramics or ferroelectrics refer to the group of dielectrics having the property of spontaneous polarization
In the electronic industry, BaTiO3 powders have been widely used for multilayer ceramic capacitor (MLCC) production, which is relevant for various applications, such as infrared detectors, waveguide modulators, piezoelectric transducers, and ferroelectric memory gate dielectrics
Mn substituted BCSMTO ceramic samples sintered at a temperature of 1200 ○C clearly illustrate that the diffracted planes reflect a very lower intensity for x = 0.00 and x = 0.15 compositions
Summary
Scitation.org/journal/adv temperature is brought down to around 400 K, the precious stone structure of BTO changes from cubic to tetragonal due to the ionic relocation of titanium (Ti) particles, and it goes to a ferroelectric state. This transformation occurs close to room temperature, and these limited stable temperature scopes of the ferroelectric tetragonal stage are hindrances for ferroelectric and piezoelectric applications.. It is demonstrated that doping can transform the BTO structure into a double perovskite form, which can blend dopants on both A-site and B-site and this aspect can influence a huge change in its magnetic and dielectric properties at room temperature and it can even display multiferroicity..
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