TY - JOUR
T1 - Highly color-stable solution-processed multilayer WOLEDs for lighting application
AU - Köhnen, Anne
AU - Irion, Mayra
AU - Gather, Malte Christian
AU - Rehmann, Nina
AU - Zacharias, Philipp
AU - Meerholz, Klaus
N1 - This work was funded by the German Ministry for Science and Education (BMBF) through the HOBBIT project. The authors gratefully acknowledge technical support from Aurélie Falcou, Heinrich Becker, Frank Meyer (Merck OLED Materials GmbH). A.K. acknowledges financial support from the Fonds der Chemischen Industrie.
PY - 2010/3/5
Y1 - 2010/3/5
N2 - White organic and especially polymeric light emitting devices (WPLEDs) have received particular attention due to their potential to provide cost-effective and simply manufactured solid-state light sources. The largest acceptable variation of Commission Internationale de L'Eclairage (CIE) coordinates is typically specified as Δx,y < 0.01 for general illumination purposes and even down to Δx,y < 0.005 by the automotive industry. Over the last few years great progress has been made regarding color-stability of OLEDs. In the first publications large color shifts of about Δx,y = 0.2,0.1 were reported. Current publications present devices with CIE variations as small as Δx,y = 0.02,0.02 or better, even for polymeric OLEDs. Here, we present a highly color-stable white fluorescent multilayer OLED consisting of a two-layer (yellow EML/blue EML) stack. The devices show white emission with CIE values of 0.324,0.346. Because of their extremely well-balanced electron and hole distribution, these devices show nearly no change in their CIE values (± 0.009,0.006) between 100 and 10 000 nits. Brightness in that range can be obtained at low voltages (4–8 V), at the same time providing a high efficiency of 6 cd A−1. In addition, due to the broad spectral width of the emission the devices exhibit a color rendering index of 84. This value complies favourably with actual demands for ambient lighting. The extrapolated half-brightness lifetime at an initial brightness of 100 cd m−2 exceeds 1000 h. All systems include the crosslinking of each layer either photo-chemically or thermally to enable the solution-processed complex multilayer OLED-structures.
AB - White organic and especially polymeric light emitting devices (WPLEDs) have received particular attention due to their potential to provide cost-effective and simply manufactured solid-state light sources. The largest acceptable variation of Commission Internationale de L'Eclairage (CIE) coordinates is typically specified as Δx,y < 0.01 for general illumination purposes and even down to Δx,y < 0.005 by the automotive industry. Over the last few years great progress has been made regarding color-stability of OLEDs. In the first publications large color shifts of about Δx,y = 0.2,0.1 were reported. Current publications present devices with CIE variations as small as Δx,y = 0.02,0.02 or better, even for polymeric OLEDs. Here, we present a highly color-stable white fluorescent multilayer OLED consisting of a two-layer (yellow EML/blue EML) stack. The devices show white emission with CIE values of 0.324,0.346. Because of their extremely well-balanced electron and hole distribution, these devices show nearly no change in their CIE values (± 0.009,0.006) between 100 and 10 000 nits. Brightness in that range can be obtained at low voltages (4–8 V), at the same time providing a high efficiency of 6 cd A−1. In addition, due to the broad spectral width of the emission the devices exhibit a color rendering index of 84. This value complies favourably with actual demands for ambient lighting. The extrapolated half-brightness lifetime at an initial brightness of 100 cd m−2 exceeds 1000 h. All systems include the crosslinking of each layer either photo-chemically or thermally to enable the solution-processed complex multilayer OLED-structures.
U2 - 10.1039/B924968K
DO - 10.1039/B924968K
M3 - Article
SN - 0959-9428
VL - 20
SP - 3301
EP - 3306
JO - Journal of Materials Chemistry
JF - Journal of Materials Chemistry
IS - 16
ER -