Barium Titanate (BaTiO₃) has been a cornerstone material in ferroelectrics and dielectrics due to its exceptional electrical, optical, and structural characteristics. Historically, doping in BaTiO₃ (BT) has played a crucial role in enhancing its ferroelectric, dielectric, and piezoelectric properties, making it a widely used material in electronic and energy applications. Over the years, research has focused on improving phase stability, optimizing electrical properties, and introducing multifunctionality through various dopants. While doping has led to significant advancements in capacitors, sensors, and memory devices, challenges such as solubility limits, charge compensation, and processing difficulties persist. Recent developments in nanostructuring, defect engineering, and co-doping strategies offer new
pathways to overcome these limitations. Additionally, the push toward environmentally friendly and lead-free materials is shaping the future of doped BT. This article provides a historical perspective on doping strategies, explores key challenges, and discusses emerging approaches that will drive the next generation of BT-based technologies.
Keywords: Barium Titanate (BaTiO₃); Doping; Ferroelectric; Transition Metal; Lanthanide;
