金屬膜在太陽能與顯示器上應用相當廣泛。為了增加吸收效率或對比度,勢必要將抗反射膜應用在金屬基板上。然而一般玻璃或塑膠等介電質基板與金屬等不透光基板之抗反射膜的設計有非常大的差異,又因為金屬膜的光學常數會隨著厚度與微結構的改變而有所不同。本實驗利用SiO2 和Nb2O5作為介電質材料,鈮Nb作為金屬膜材料來設計抗反射膜。 研究使用金屬-介電質結構做兩種設計設計: air/SiO2 /Nb/ SiO2/Al, air/SiO2/Nb2O5/Nb/Nb2O5/Al。可見光波段400~700 nm的平均反射率小於0.4%。使用高折射率材料的設計之總厚度140 nm比單純使用SiO2的低折射率設計少了20%,且兩種設計之厚度都遠小於使用塗料塗佈吸收層的厚度。 太陽能吸收的應用設計波段選擇太陽光譜強度範圍400~1800 nm,平均反射率約1%,吸收率約99%。在紅外光8000 nm以上也有85%以上之反射率,降低了熱輻射放射量。 此外,軟性顯示器OLED也與此種抗反射膜結合在PI基板上,處理過的元件在可見光400~700 nm照度反射率RD=3.4%,未處理過的元件之RD=79.8%,成功降低了16倍以上,在對比度有顯著的提升。 Normally metallic films are required for solar energy and display related coatings. To increase the absorbing efficiency or contrast, it is necessary to apply an antireflection coating (ARC) on the metal substrate. However, the design of a metal substrate is very different from the design of a dielectric substrate, since the optical constant of metallic thin film is very dependent on its thickness and microstructure. In this study, we design and fabricate ARCs on Al substrates using SiO2 and Nb2O5 as the dielectric materials and Nb for the metal films. It had the following metal-dielectric structure: air/SiO2 /Nb/ SiO2/Al , air/SiO2/Nb2O5/Nb/Nb2O5/Al. A total thickness is less than 20% than only using a low refractive index material for the dielectric layer, the average reflection is below 0.4% from 400-700nm, which is much thinner than the typical printed absorber. In this study, we obtain an average reflection for the solar absorber of less than 1% and a total absorbance of about 99% from 400-1800 nm. In addition, we also successfully fabricated an OLED device on PI substrate composed of the ARC film and a highly reflective cavity. The total luminance reflectance RD of the measured device is less than 5%. The RD of the untreated device is about 80%, 16 times higher than treated device.
