Title :
Mapping Temperature in OLED Displays Using CCD Thermoreflectance
Author :
Katz, Noomi ; Arango, Adriana ; Hudgings, J.
Author_Institution :
Dept. of Phys., Mount Holyoke Coll., South Hadley, MA, USA
Abstract :
Effective thermal management is essential to engineering organic devices, since heating accelerates their degradation. However, as pixels in organic light-emitting diode (OLED) displays continue to shrink, an important tool for thermal management, infrared thermography, approaches the limits of its spatial resolution. To address this problem, we adapt high-resolution thermoreflectance imaging, which measures minute changes in reflectivity of visible light, to map temperature in a commercial OLED display. We identify a slowly varying thermal signal and find strong evidence of thermal crosstalk, in which a biased pixel heats up its nearest neighbors, even when the neighbors are unbiased. Such crosstalk is indicative of insufficient heat dissipation, which can lead to reduced display lifetime.
Keywords :
CCD image sensors; LED displays; cooling; infrared imaging; light reflection; organic light emitting diodes; temperature measurement; thermal analysis; thermoreflectance; visible spectra; CCD thermoreflectance; OLED displays; heat dissipation; heating; high-resolution thermoreflectance imaging; infrared thermography; organic device engineering; organic light-emitting diode displays; spatial resolution; temperature mapping; thermal crosstalk; thermal management; thermal signal variation; visible light reflectivity; Cameras; Heating; Organic light emitting diodes; Temperature measurement; Timing; Thermal management of electronics; displays; organic light emitting diodes; photothermal effects;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2013.2291841
