The latest developments in the multifunctional uses of bismuth phosphate-based materials for photoluminescence, photocatalysis, electrochemical characteristics, and their biological applications have been emphasised and discussed from this angle. BiPO4 has become a desirable material with opportunities to investigate a wide range of applications because of its unique structural, optical, and catalytic properties. When compared to their pristine counterparts, these materials, which are based on bismuth phosphate and doped with various metal ions, display improved physicochemical features that enhance their luminescence capability. The amazing abilities and enormous potential of these chemicals in electrochemical energy storage have been made clear by recent research articles. Large channels and cavities in the open-framework architectures of metal phosphates provide them good charge storage capacity and ion conductivity. More effective photocatalysts are much preferred for a straightforward and affordable treatment than the commonly utilised TiO2, in order to monitor and validate a photocatalyst. Nowadays, it’s well acknowledged that BiPO4 is a better photocatalyst than TiO2 in the UV range and has two advantages over TiO2 in terms of antibacterial inactivation and biological activities. Enhancers and sensitisers can be added to materials to introduce new functions, change the electronic structure, modify surface properties, and improve overall performance. This makes the materials interesting candidates for a variety of technological applications.

中文翻译：

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磷酸铋基材料协同效应研究进展：光催化、光致发光、电化学性能及其生物学应用


从这个角度强调了磷酸铋基材料在光致发光、光催化、电化学特性及其生物学应用方面的多功能用途的最新进展。BiPO4 由于其独特的结构、光学和催化特性，已成为一种理想的材料，有机会研究广泛的应用。与原始材料相比，这些基于磷酸铋并掺杂了各种金属离子的材料显示出改进的物理化学特性，增强了其发光能力。最近的研究文章已经清楚地表明了这些化学物质在电化学储能中的惊人能力和巨大潜力。金属磷酸盐的开放框架结构中的大通道和空腔为它们提供了良好的电荷存储容量和离子电导率。为了监测和验证光催化剂，比常用的 TiO2 更有效的光催化剂更受青睐，是一种简单且负担得起的处理方法。如今，众所周知，BiPO4 在紫外线范围内是比 TiO2 更好的光催化剂，并且在抗菌灭活和生物活性方面比 TiO2 具有两个优势。可以在材料中添加增强剂和敏化剂，以引入新功能、改变电子结构、改变表面特性并提高整体性能。这使得这些材料成为各种技术应用的有趣候选者。