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Title: | Design of low surface roughness-low residual stress-high optoelectronic merit a-IZO thin films for flexible OLEDs |
Authors: | Kumar, N. Wilkinson, T.M. Packard, C.E. Kumar, M. |
Keywords: | Amorphous films Conductive films Design of experiments Electric conductivity Film growth Indium Light emitting diodes Optoelectronic devices Organic light emitting diodes (OLED) Oxide films Regression analysis Residual stresses Surface roughness Amorphous indium zinc oxide (a-IZO) Flexible organic light - emitting diodes Multi-parameter optimizations Optoelectronic properties Oxygen partial pressure Regression modeling and analysis Statistical design of experiments Transparent conducting oxide |
Issue Date: | 17-Nov-2016 |
Abstract: | The development of efficient and reliable large-area flexible optoelectronic devices demands low surface roughness-low residual stress-high optoelectronic merit transparent conducting oxide (TCO) thin films. Here, we correlate surface roughness-residual stress-optoelectronic properties of sputtered amorphous indium zinc oxide (a-IZO) thin films using a statistical design of experiment (DOE) approach and find a common growth space to achieve a smooth surface in a stress-free and high optoelectronic merit a-IZO thin film. The sputtering power, growth pressure, oxygen partial pressure, and RF/(RF+DC) are varied in a two-level system with a full factorial design, and results are used to deconvolve the complex growth space, identifying significant control growth parameters and their possible interactions. The surface roughness of a-IZO thin film varies over 0.19 nm to 3.97 nm, which is not in line with the general assumption of low surface roughness in a-IZO thin films. The initial regression model and analysis of variance reveal no single optimum growth sub-space to achieve low surface roughness (≤0.5 nm), low residual stress (-1 to 0 GPa), and industrially acceptable electrical conductivity (>1000 S/cm) for a-IZO thin films. The extrapolation of growth parameters in light of the current results and previous knowledge leads to a new sub-space, resulting in a low residual stress of -0.52±0.04 GPa, a low surface roughness of 0.55±0.03 nm, and moderate electrical conductivity of 1962±3.84 S/cm in a-IZO thin films. These results demonstrate the utility of the DOE approach to multi-parameter optimization, which provides an important tool for the development of flexible TCOs for the next-generation flexible organic light emitting diodes applications. |
URI: | http://localhost:8080/xmlui/handle/123456789/384 |
Appears in Collections: | Year-2016 |
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