Download This PaperCoupling Pyroelectric Fields and Donor Doping to Adjust Curie Temperature and Band Structure to Access to Highly Efficient Batio3 Photoelectrodes for Dye Degradation
26 Pages Posted: 18 Jul 2024
Abstract
Utilizing the pyroelectric and photoelectric properties of ferroelectric semiconductors for pollutant degradation represents an emerging, clean, and sustainable dye degradation technology. However, conventional modification methods, such as defect/morphology engineering and cocatalyst loading, can only incrementally enhance the structural and electronic states of materials to improve their catalytic performance. This study demonstrates that in pyro-photoelectrocatalysis, by introducing isovalent lanthanide ions into BaTiO3 fundamentally reduces the Curie temperature (Tc) of BaTiO3, thereby significantly enhancing the pyroelectric performance of Ba1-xLaxTiO3 at room temperature. Furthermore, we also confirmed that the introduction of heterovalent ions alters the grain size and band structure of BaTiO3. With an x value of 0.2, under the synergistic effect of thermal and photoelectric catalysis, the degradation efficiency for Rhodamine B (RhB) is optimal, reaching 98.8% within 60 minutes. Additionally, the pyro-photoelectrocatalysis measured under 1.23V showed that Ba0.8La0.2TiO3 (0.073 mA/cm²) exhibited a pyro-photoelectrocatalysis current 1.6 times higher than that of pure BaTiO3(0.048 mA/cm²), this research providing a viable method for designing electrodes with superior pyro-photoelectrocatalysis performance.
Keywords: BaTiO3, pyroelectricity, photoelectricity, catalysis, ion doping
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