Abstract

Achieving precise control over emission characteristics, such as wavelength and lifetime, is critical to unlocking the full potential of luminescent nanomaterials for diverse applications. In this work, we present a strategy for fine-tuning the optical properties of upconversion nanocrystals by engineering parts-per-million (ppm)-doping-level lanthanide impurities. We show that even trace impurities (∼10 ppm, fewer than 10 atoms per nanocrystal), which are only a hundredth of the conventionally studied doping levels and were previously considered negligible, serve as efficient energy traps in energy migration-based upconversion processes. By introducing controlled trapping centers via minimal impurity doping, we successfully regulate the upconversion emission colors and lifetimes with high precision. Moreover, we find that high-purity nanocrystals exhibit significantly greater lifetime changes in response to surface interactions, enabling an energy-transfer-based ultrasensitive spectrum and lifetime sensing. This approach facilitates the development of upconversion-based DNA sensors with detection limits over an order of magnitude lower than those of conventional methods, highlighting the potential of these nanocrystals as highly effective nanoprobes for interference-resistant biosensing in complex environments.