摘要
Infrared emissivity was studied in Zn0.99M0.01O(M is Mn,Fe or Ni) and Zn1-xCoxO(x=0.01,0.02,0.03 and 0.04) powders synthesized by solid-state reaction at various temperatures.XRD patterns confirm the wurtzite structure of the prepared samples.No peaks of other phases arising from impurities are detected in Mn-and Co-doped ZnO,but the peaks of ZnFe2O4 and NiO are observed in Zn0.99Fe0.01O and Zn 0.99 Ni 0.01 O.The SEM observations indicate that with larger grain sizes than those of Zn0.99Fe0.01O and Zn0.99Ni0.01O,Co-doped ZnO exhibits smooth grain surfaces.The infrared absorption spectra show that infrared absorptions related to oxygen in Zn0.99M0.01O are much stronger than those in Co-doped ZnO.Co ions are dissolved into the ZnO lattice with Co2+ state from XPS spectra analysis.The infrared emissivity results imply that the emissivity of Zn0.99Ni0.01 O is the highest(0.829) and that of Zn 0.99 Co 0.01 O is the lowest(0.784) at 1 200 C.The emissivity of Zn0.99Co0.01O decreases to the minimum(0.752) at 1 150 C and then increases with growing calcination temperature.As the Co doping content grows,the emissivity of Co-doped ZnO calcined at 1 200 C falls to 0.758 in the molar fraction of 3% and then ascends.
Infrared emissivity was studied in Zno.99Mo.olO (M is Mn, Fe or Ni) and Znl_xCoxO (x=0.01, 0.02, 0.03 and 0.04) powders synthesized by solid-state reaction at various temperatures. XRD patterns confirm the wurtzite structure of the prepared samples. No peaks of other phases arising from impurities are detected in Mn- and Co-doped ZnO, hut the peaks of ZnFe204 and NiO are observed in Zno.99Feo.010 and Zno.99Nio.o10. The SEM observations indicate that with larger grain sizes than those of Zn0.99Feo.010 and Zno.99Ni0.010, Co-doped ZnO exhibits smooth grain surfaces. The infrared absorption spectra show that infrared absorptions related to oxygen in Zn0.99M0.010 are much stronger than those in Co-doped ZnO. Co ions are dissolved into the ZnO lattice with Co2+ state from XPS spectra analysis. The infrared emissivity results imply that the emissivity of Zno.99Ni0.010 is the highest (0.829) and that of Zno.99C00.010 is the lowest (0.784) at 1 200 ℃. The emissivity of Zno.99Co0.010 decreases to the minimum (0.752) at 1 150 ℃ and then increases with growing calcination temperature. As the Co doping content grows, the emissivity of Co-doped ZnO calcined at 1 200 ℃ falls to 0.758 in the molar fraction of 3% and then ascends.
基金
Project(2009K06_03) supported by the Scientific and Technological Program of Shaanxi Province,China
