Three-photon-induced blue emission with narrow bandwidth from hot flower-like ZnO nanorods

ZnO nanorods (NRs) self-organized into flowers were synthesized at different temperatures ranging from 100 degrees C to 180 degrees C by using the hydrothermal method. The existence of Zn interstitials (Zni) was confirmed by X-ray photoelectron spectroscopy and a larger amount of Zni was found in the ZnO NRs prepared at higher temperatures. A redshift of the emission peak of more than 15 nm was observed for the ZnO NRs under single photon excitation. The nonlinear optical properties of the flower-like ZnO NRs were characterized by using focused femtosecond laser light and strong three-photon-induced luminescence was observed at an excitation wavelength of similar to 750 nm. More interestingly, a large redshift of the emission peak was observed with increasing excitation intensity, resulting in efficient blue emission with a narrow bandwidth of similar to 30 nm. It was confirmed that the large redshift originates from the heating of the ZnO NRs to a temperature of more than 800 degrees C and the closely packed ZnO NRs in the flowers play a crucial role in heat accumulation. The stable and efficient three-photon-induced blue emission from such ZnO NRs may find potential applications in the fields of optical display, high-temperature sensors and light therapy of tumors. (C) 2015 Optical Society of America