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有机电致发光技术被认为是可能替代液晶的新一代显示技术,白光有机发光器件由于可应用于液晶显示的背光源、普通照明、特殊光源以及实现全彩色有机发光显示而倍受瞩目。本文对白光有机电致发光器件的结构、工作原理等进行了简单的概述并总结了白光有机发光器件的最新进展。 相似文献
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白光有机电致发光器件在显示和照明领域有着极大的应用前景,受到人们广泛的关注。本文对白光有机电致发光器件的结构、工作原理、工艺流程、存在的问题等进行了简单的概述,力求总结出制备白光有机发光器件的新途径。 相似文献
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以Bphen:Li/WO3作为电荷产生层制备了低压、高效有机叠层白光器件.实验中,首先在器件中引入高导电性的载流子注入和传输层,有效降低了器件的驱动电压,然后通过电荷产生层垂直堆叠两个低压白光器件,获得了低压、高效有机叠层白光器件.叠层器件性能与单发光单元的器件相比较.其亮度及效率均有大幅提高,叠层器件的最大电流效率达到了17cd/A,在相同的电流密度下,叠层器件的效率约为传统器件的2.3倍.同时由于在叠层结构中引入了高导电性的载流子传输层,有效降低了器件的驱动电压,显著改善了白光器件的流明效率.叠层器件的流明效率相对于单发光单元器件提高了53%. 相似文献
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以Bphen:Li/WO3作为电荷产生层制备了低压、高效有机叠层白光器件. 实验中,首先在器件中引入高导电性的载流子注入和传输层,有效降低了器件的驱动电压,然后通过电荷产生层垂直堆叠两个低压白光器件,获得了低压、高效有机叠层白光器件. 叠层器件性能与单发光单元的器件相比较,其亮度及效率均有大幅提高,叠层器件的最大电流效率达到了17cd/A,在相同的电流密度下,叠层器件的效率约为传统器件的2.3倍,同时由于在叠层结构中引入了高导电性的载流子传输层,有效降低了器件的驱动电压,显著改善了白光器件的流明效率.叠层器件的流明效率相对于单发光单元器件提高了53%. 相似文献
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微腔结构顶发射有机白光器件 总被引:2,自引:1,他引:1
结合微腔效应,通过调节不同发光层的厚度制作了顶发射有机白光器件.器件结构为Si/Ag/Ag2O/m-MTDATA/NPB/DPVBi/DCJTB:Alq3/Alq3/LiF/Al/Ag,其中DPVBi,DCJTB与Alq3的掺杂层分别作为蓝光和红光发光层,在选定490 nm的谐振波长时,通过调节DPVBi和掺杂层的厚度来实现对器件发光色度的调节.当DPVBi厚度为1 nm,电压为9 V时,器件的色坐标为(0.33,0.34),非常接近白光等能点.此项工作为利用微腔效应制作高效率高亮度顶发射白光器件奠定了基础. 相似文献
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多层白色有机发光器件的结构和性能优化 总被引:1,自引:0,他引:1
以红、蓝、绿为基,制备了不同发光层组合次序的有机发光器件,研究了各发光层的顺序及厚度对器件性能的影响,并在此基础上构成了白色有机发光器件.通过改变关键发光层的厚度,来调节不同颜色之间的平衡,从而达到色度很好的向色;由于关键发光层的厚度很薄,因此得到的器件在高电压的色度漂移也很小.优化的白光器件在200 mA/cm2时,电流效率为3.78 cd/A,色坐标为x=0.345,y=0.323.根据激子产生和扩散理论,讨论了器件性能对于各发光层的厚度及激子扩散长度的依赖关系,拟合结果与实验结果吻合. 相似文献
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By changing the thickness of hole transport layer to control the cavity length, a top-emitting white organic light-emitting diode (TWOLED) with three individual narrow peaks matching well with the three primary color filters has been successfully realized. It is very important to carefully design the multimode microcavity for the achievement of the three-peak spectrum. Compared with the bottom-emitting white organic light-emitting diodes (BWOLEDs), the TWOLEDs exhibit improved color purity and a wider color gamut due to the narrow emissive spectrum. The maximum current efficiency and power efficiency of TWOLED reach 28.9 cd/A and 27.5 lm/W, respectively. It is predicted that this kind of three-peak TWOLEDs is suitable for the high-quality display application. 相似文献
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A monolithic white light-emitting diode (LED) with blue and yellow light active regions has been de-signed and studied. With the AlxGa1-xN/InyGa1-yN distributed Bragg reflector (DBR) resonant-cavity, the extraction efficiency and power of the yellow light are enhanced so that high quality white light can be obtained. 相似文献
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A monolithic white light-emitting diode (LED) with blue and yellow light active regions has been designed and studied. With the AlxGa1-xN/InyGa1-yN distributed Bragg reflector (DBR) resonant-cavity, the extraction efficiency and power of the yellow light are enhanced so that high quality white light can be obtained. 相似文献
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Four carbazole-based bipolar host materials are utilized for solution-processed phosphorescent organic light-emitting diodes (PhOLEDs). These bipolar materials consist of an electron-donor unit (carbazole) linking to a fluorene unit bearing various electron-acceptor units (oxadiazole, cyano, and benzimidazole) via a saturated carbon, giving sufficiently high triplet energies due to the lack of direct electronic coupling between the donor and acceptor(s). The resulting physical properties and bipolar characteristics render the realization of efficient solution-processed green and white OLEDs feasible. The best green light-emitting device based on bipolar host CzFCBI incorporating a stepwise hole-injection/transporting system exhibit a low drive voltage, a maximum external quantum efficiency of 14.0%, a current efficiency of 49.0 cd/A, and a power efficacy of 55.0 lm/W. Moreover, the CzFOXa-based two-component (blue–orange) white light-emitting device shows a warmish-white emission with a maximum external quantum efficiency of 6.9% and stable chromaticity coordinates at different luminance levels and yield a high color rendering index (CRI) reaching 76 at a luminance of 1000 cd/m2. 相似文献
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利用蓝色有机发光二极管(BOLED)激发色彩转换膜的方法,制备了一种新型的白色有机电致发光器件(WOLED)。BOLED的发光层采用CBP主体掺杂高效蓝色荧光染料N-BDAVBi来制备;色彩转换膜是将橙红色荧光颜料VQ-D24均匀分散到A、B环氧树脂中涂敷、固化而成。通过调整与分析转换膜的厚度和荧光颜料的掺杂比例来优化白光器件的发光光谱,获得了色稳定性较高的WOLED。当驱动电压由7V升至14V时,WOLED的色坐标(CIE)仅在(0.33,0.32)和(0.34,0.28)间变化,器件最高电流效率约为7.3cd/A(4.35mA/cm2),最高亮度为12000cd/m2(14V)。 相似文献
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