Park, Jongwoon
(OLED Lighting Team, National Center for Nanoprocess and Equipment, Korea Institute of Industrial Technology, Gwangju 500-480, Republic of Korea)
,
Lee, Jongho
(OLED Lighting Team, National Center for Nanoprocess and Equipment, Korea Institute of Industrial Technology, Gwangju 500-480, Republic of Korea)
,
Noh, Yong-Young
(Department of Chemical Engineering, Hanbat National University, Daejeon 305-71, Republic of Korea)
Graphical abstract(Left) Surface temperature distribution of transparent OLEDs with the Cr metal lines on ITO but without the Al metal lines on the transparent Al/Ag cathode. (Right) OLEDs with both of them at the average luminance of 2000nit. Insets are thermal images.Highlights► The effect...
Graphical abstract(Left) Surface temperature distribution of transparent OLEDs with the Cr metal lines on ITO but without the Al metal lines on the transparent Al/Ag cathode. (Right) OLEDs with both of them at the average luminance of 2000nit. Insets are thermal images.Highlights► The effect of metallic grids on the performance of large-area OLED lighting panels. ► Cr, Mo/Al/Mo, or Cu metal lines formed on ITO anode and Al metal lines on a cathode. ► Cu metal lines show the best device performance due to its highest conductivity. ► Transparent OLEDs require metallic grids not only on anode but also on cathode. ► A round-shaped panel with hexagonal grids shows the most uniform heat distribution. AbstractWe investigate the effects of auxiliary metal electrodes on the optical and thermal properties of large-area (30×120mm2) opaque and transparent white OLED lighting panels. Enlarging their emission area inevitably entails a non-uniform current distribution due to the limiting conductivity of transparent electrodes, causing local heat generation. To tackle it, we have used grid patterned Cr, Mo/Al/Mo, or Cu metal lines (0.15mm in width) as auxiliary metal electrodes on an ITO anode. Among those, Cu metal grids exhibit the highest luminous efficacy with the least heat generation, and the most uniform light distribution by virtue of its lowest sheet resistance, followed by Mo/Al/Mo and then Cr metal grids. It is also found that local heat generation appears more seriously in large-area transparent OLED panels. With attempt to suppress it, we have also deposited Al metal lines (2mm in width) on a semitransparent Al/Ag cathode by thermal evaporation, which brings in a highly uniform heat distribution. Furthermore, we study the effect of the shape of the light-emitting area on the luminance and heat distributions. A round-shaped OLED panel with a hexagonal metal grid exhibits highly homogeneous luminance and surface temperature distributions.
Graphical abstract(Left) Surface temperature distribution of transparent OLEDs with the Cr metal lines on ITO but without the Al metal lines on the transparent Al/Ag cathode. (Right) OLEDs with both of them at the average luminance of 2000nit. Insets are thermal images.Highlights► The effect of metallic grids on the performance of large-area OLED lighting panels. ► Cr, Mo/Al/Mo, or Cu metal lines formed on ITO anode and Al metal lines on a cathode. ► Cu metal lines show the best device performance due to its highest conductivity. ► Transparent OLEDs require metallic grids not only on anode but also on cathode. ► A round-shaped panel with hexagonal grids shows the most uniform heat distribution. AbstractWe investigate the effects of auxiliary metal electrodes on the optical and thermal properties of large-area (30×120mm2) opaque and transparent white OLED lighting panels. Enlarging their emission area inevitably entails a non-uniform current distribution due to the limiting conductivity of transparent electrodes, causing local heat generation. To tackle it, we have used grid patterned Cr, Mo/Al/Mo, or Cu metal lines (0.15mm in width) as auxiliary metal electrodes on an ITO anode. Among those, Cu metal grids exhibit the highest luminous efficacy with the least heat generation, and the most uniform light distribution by virtue of its lowest sheet resistance, followed by Mo/Al/Mo and then Cr metal grids. It is also found that local heat generation appears more seriously in large-area transparent OLED panels. With attempt to suppress it, we have also deposited Al metal lines (2mm in width) on a semitransparent Al/Ag cathode by thermal evaporation, which brings in a highly uniform heat distribution. Furthermore, we study the effect of the shape of the light-emitting area on the luminance and heat distributions. A round-shaped OLED panel with a hexagonal metal grid exhibits highly homogeneous luminance and surface temperature distributions.
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