Synthesis and optical properties of a Y 3 (Al/Ga) 5 O 12 :Ce 3+ ,Cr 3+ ,Nd 3+ persistent luminescence nanophosphor: a promising near-infrared-II nanoprobe for biological applications

Persistent luminescence nanophosphors (PLNPs) emitting in the second near-infrared window (1000-1700 nm, NIR-II) are emerging as one promising class of in vivo bio-imaging agents due to their unique advantages including non-autofluorescence and low optical scattering in tissues. Currently, it remains a great challenge to synthesize nanosized lanthanide-doped inorganic NIR-II phosphors with a good persistent luminescence performance. Herein, we present a salt microemulsion method for synthesizing Ce , Cr , Nd codoped Y (Al/Ga) O nanocrystals, which generate multi-wavelength persistent luminescence in the visible (∼508 nm, 5d → 4f of Ce ), the first near-infrared window (∼890 nm, F → I of Nd ) and NIR-II (∼1063 nm, F → I of Nd ) regions. Under illumination of a 410 nm diode (3 W) for 10 min, the observed duration time of NIR-II persistent luminescence is as long as 60 min at room temperature. Moreover, the persistent luminescence can be excited efficiently by multiple excitation sources including a blue diode, white LEDs and an X-ray generator, which is crucial for deep tissue imaging applications. By comparing the penetration depth between NIR-I and NIR-II persistent luminescence through chicken breast, we prove that NIR-II photons exhibit a deeper optical penetration length (3.9 mm) than that of the NIR-I ones (2.5 mm). In addition, the NIR signals can still be detected 3 min after ceasing the excitation source by a small animal imaging system (InGaAs detector) when the thickness of the covering chicken breast is 20 mm. These results show great promise for Y (Al/Ga) O :Ce ,Cr ,Nd nanocrystals as a PLNP for bio-imaging applications with deep penetration depth and a high signal-to-noise ratio.