The IR-to-visible upconversion fluorescent crystals, Yb:Ho:LiN-bO3, with a constant Ho^3+ concentration (0.1 mol%) and different doping concentrations of Yb^3+ (0.5, 1.5, 2.0, 2.5, 3.0 tool%) are synthesized b...The IR-to-visible upconversion fluorescent crystals, Yb:Ho:LiN-bO3, with a constant Ho^3+ concentration (0.1 mol%) and different doping concentrations of Yb^3+ (0.5, 1.5, 2.0, 2.5, 3.0 tool%) are synthesized by Czochralski method in air atmosphere. X-ray diffraction shows that the obtained crystal is a single phase of LiNbO3 and the rare-earth ions occupied the Li^+ or Nb^5+ sites instead of the interstitial sites. Under 980 nm excitation, green and red emission bands due to the Ho^3+ (^5S2, ^5F4)/^5I8 and Ho^3+ ^5F5/^5I8 energy transitions are observed in these samples, respectively. Power dependence studies on these samples with different Yb^3+ dopant concentrations indicate that the red and green emissions are based on a two-photon process. The intensities of the red and green upconversion fluorescence increase with Yb3+ ions of 0-2.0 mol% because of an increased Yb^3+ sensitization, but decrease at higher concentrations owing to the back-energy transfer between the Yb^3+ and Ho^3+ ions.展开更多
基金Supported by the National Natural Science Foundation of China (10732100)the Natural Science Foundation of Heilongjiang Province (B200903)
文摘The IR-to-visible upconversion fluorescent crystals, Yb:Ho:LiN-bO3, with a constant Ho^3+ concentration (0.1 mol%) and different doping concentrations of Yb^3+ (0.5, 1.5, 2.0, 2.5, 3.0 tool%) are synthesized by Czochralski method in air atmosphere. X-ray diffraction shows that the obtained crystal is a single phase of LiNbO3 and the rare-earth ions occupied the Li^+ or Nb^5+ sites instead of the interstitial sites. Under 980 nm excitation, green and red emission bands due to the Ho^3+ (^5S2, ^5F4)/^5I8 and Ho^3+ ^5F5/^5I8 energy transitions are observed in these samples, respectively. Power dependence studies on these samples with different Yb^3+ dopant concentrations indicate that the red and green emissions are based on a two-photon process. The intensities of the red and green upconversion fluorescence increase with Yb3+ ions of 0-2.0 mol% because of an increased Yb^3+ sensitization, but decrease at higher concentrations owing to the back-energy transfer between the Yb^3+ and Ho^3+ ions.
