Recent advances in the development and applications of lanthanide-based luminescent materials: a comprehensive review
Jinyang Li, Xiaohong Tian, Wei Bao, Jiaojiao Zhao, Zihao Jiang
Abstract
Lanthanide-based luminescent materials are valued for their unusual optical properties, including narrow emission bands, long luminescence lifetimes, and high resistance to photobleaching. These features make them ideal for applications in energy conversion, sensing, security, and bioimaging technologies. Recent advancements have focused on enhancing their performance through the integration of lanthanide ions into nanoparticles, hybrid systems, and metal–organic frameworks, thereby broadening their applications in diverse fields. This review presents the fundamental principles of lanthanide luminescence, encompassing the electronic structure of lanthanide ions, energy transfer mechanisms, and the selection of host materials. It reviews recent developments in synthesis methods, including both conventional and green chemistry approaches, aimed at producing high-quality luminescent materials with tunable characteristics. Additionally, the importance of advanced characterization techniques for assessing material performance is emphasized. The applications of these materials are vast, spanning biomedical imaging, optoelectronics, environmental sensing, and anti-counterfeiting. However, challenges, including low absorption efficiency, surface quenching, toxicity concerns, and scalability issues, are still persistent. Overcoming these challenges through the development of improved sensitizers, biocompatible designs, and sustainable synthesis routes will be crucial for the continued success and expansion of lanthanide luminescent materials. Future advancements in multifunctional systems and smart materials will further advance their impact across various high-tech sectors, including energy, security, and human healthcare.