有机薄膜电致发光器件失效过程的动态观测及分析

对有机薄膜电致发光器件失效的全过程进行了显微动态观察，发现器件工作时，有机层／金属界面形成的气泡逐渐变大变多，最终导致器件完全失效，气泡不仅含有水汽，还存在大量有机气体。     

Improved device reliability in organic light emitting devices by controlling the etching of indium zinc oxide anode

A controllable etching process for indium zinc oxide （IZO） films was developed by using a weak etchant of oxalic acid with a slow etching ratio. With controllable etching time and temperature, a patterned IZO electrode with smoothed surface morphology and slope edge was achieved. For the practical application in organic light emitting devices （OLEDs）, a sup- pression of the leak current in the current-voltage characteristics of OLEDs was observed. It resulted in a 1.6 times longer half lifetime in the IZO-based OLEDs compared to that using an indium tin oxide （ITO） anode etched by a conventional strong etchant of aqua regia.     

基于闭环二苯醚与磷氧基团的主体材料的合成及其在蓝色磷光有机发光二极管中的应用

本文通过多步有机反应制备了化合物9-苯基-9′-（4-二苯基氧化膦）苯基-氧杂蒽[diphenyl（4-（9-phenyl-9H-xanthen-9-yl）phenyl）phosphine oxide,DPPO],低温磷光发射光谱测试表明该化合物具有高的三线态能级（2.88eV）,它可以作为天蓝色磷光发光材料双（4,6-二氟苯基吡啶-N,C2）吡啶甲酰合铱[bis（3,5-difluoro-2-（2-pyridyl）phenyl-（2-carboxypyridyl）iridium（Ⅲ）,FIrpic,ET=2.62eV]的主体材料.将主体材料DPPO用于蓝色磷光有机发光二极管中,该器件在100cd/m2的亮度下,电流效率和流明效率分别达到30.6cd/A和19.2lm/W,最大外量子效率达到13.6%.     

INFLUENCE OF C+-IMPLANTATION DOSE ON BLUE EMISSION AND MICROSTRUCTURES OF Si-BASED POROUS β-SIC

Crystal Si were implanted with different doses of C⁺ from 10¹¹ to 10¹⁷ cm^-2 at an energy of 50 keV. β-SiC precipitates were formed by thermal annealing at 1050 ℃ for 1 h and porous structures were prepared by electrochemical anodization. Under the excitation of ultraviolet, the samples, with C⁺ dose ≥10¹⁵ cm^-2 have intense blue emission which is stronger than the photoluminescence (PL) intensity of reference porous silicon (PS), and increases as C⁺ dose increases; the samples with C⁺ dose ≤10¹⁴ cm^-2 show similar PL spectra to those of PS. The blue peak intensity in PL spectra is correlated with the TO phonon absorption strength of β-SiC in infrared absorption spectra. The transmission electron microscopy study shows that the blue peak is also correlated with the microstructures. Because porous β-SiC is nanometer in size, it is suggested that the quantum confinement effect be responsible for the blue light emission.     

高效大面积有机白光照明研究及其展望

白光有机发光二极管(OLED)是新一代健康节能照明光源,光效性能已超过荧光灯水平。自从OLED技术问世以来,研究人员陆续开展了关于OLED照明的研究工作。本文介绍了OLED照明的特点,以及国内外OLED照明发展现状,讨论了发展OLED照明技术和装备国产化所亟待解决的重大难题和面临的挑战,重点论述了发展高效大面积OLED照明器件制备技术及推动OLED照明产业化的重要意义。     

Pr6O11对SnO2半导体气敏特性的影响

研究了添加Pr_6O_11的SnO_2半导体气敏元件的气敏特性。在丙酮、乙醇、甲烷、一氧化碳等11种气氛中测量结果表明,元件对丙酮、乙醇具有选择性,Pr_6O_(11)的最佳含量为1.0wt％左右。实验还发现,元件的限定工作温度随着Pr_6O_(11)含量的增加而下降,响应时间和恢复时间缩短,灵敏度随被测气体浓度变化的线性范围相应增大。     

嵌埋在多孔硅中硅团簇的拉曼谱

嵌埋在多孔硅中硅团簇的拉曼谱程光煦＊＋刘峰奇＋洪建明＊廖良生＋王广厚＋（南京大学现代分析中心＊及固体微结构物理国家实验室＋南京２１００９３）娄莉华（中国药科大学南京２１０００９）ＲａｍａｎＳｐｅｃｔｒａｏｆＳｉｌｉｃｏｎＣｌｕｓｔｅｒＥｍｂｅｄｄｅｄ...     

有机薄膜电致发光器件工艺检测的一种简便方法——覆膜加热观测法

提出了一种简便易行、并与有机薄膜电致发光器件制备工艺完全兼容的工艺检测方法－－覆膜加热观测法。这种方法是在器件的制备工艺过程中,同时在铟锡氧化物（ITO）电极的各层有机薄膜上覆盖一层不透气的薄膜（如金属Al膜等）,接着进行快速加热,最后对器件表面进行形貌观测。采用这种方法,观察了器件表面气泡的形成过程,观察了加热温度、ITO表面处理以及有机物纯度对敢泡形成的影响。实验表明,覆膜加热观测法能有效地对工艺进行对比检测,从而达到改进工艺、提高器件质量的目的。     

有机小分子发光材料与聚合物发光材料在大气存放条件下的稳定性对比研究

分别采用紫外光电子能谱（UPS）、X光电子能谱（XPS）、原子力显微镜（AFM）、以及光致发光光谱（PL）等方法对在大气存放条件下的8－羟基喹啉铝（Alq)薄膜和聚（9,9－二辛烷基芴）（PFO）薄膜的电子结构、表面形 及发光特性进行了对比。研究结果表明,PFO的电子结构、表面形貌以及发光特性受外界气氛影响极小,是一种非常稳定的聚合物发光材料。这为聚合物发光器件的稳定性提供了有利的条件。     

INFLUENCE OF C+-IMPLANTATION DOSE ON BLUE EMISSION AND MICROSTRUCTURES OF Si-BASED POROUS β-SIC

Crystal Si were implanted with different doses of C⁺ from 10¹¹ to 10¹⁷ cm^-2 at an energy of 50 keV. β-SiC precipitates were formed by thermal annealing at 1050 ℃ for 1 h and porous structures were prepared by electrochemical anodization. Under the excitation of ultraviolet, the samples, with C⁺ dose ≥10¹⁵ cm^-2 have intense blue emission which is stronger than the photoluminescence (PL) intensity of reference porous silicon (PS), and increases as C⁺ dose increases; the samples with C⁺ dose ≤10¹⁴ cm^-2 show similar PL spectra to those of PS. The blue peak intensity in PL spectra is correlated with the TO phonon absorption strength of β-SiC in infrared absorption spectra. The transmission electron microscopy study shows that the blue peak is also correlated with the microstructures. Because porous β-SiC is nanometer in size, it is suggested that the quantum confinement effect be responsible for the blue light emission.