准弹性激光光散射在血细胞检测中的应用

本文利用准弹性激光散射法和细胞电泳法对不同哺乳动物的红细胞,淋巴细胞、粒细胞进行检测,结果表明在一定条件下,不同类型的血细胞平均电泳速度有明显差别。这一结果为光散射法应用于血细胞检测提供了可能性。     

聚合物基片对柔性有机发光器件性能的影响

以聚合物基片柔性ITO膜为透明电极，制备了ITO／TPD／Alq3／Al结构柔性有机发光器件，并与在相同条件下制备的玻璃基片相同结构器件作了比较。研究了不同基片对有机材料及器件性能的影响，指出选择不易吸湿、耐温高、热胀系数小的聚合物材料，提高柔性ITO膜的附着力和导电性，结合柔性ITO膜的具体特性。优化有机层的蒸镀条件，是提高柔性有机发光器件发光亮度和稳定性的重要途径。     

混合溶剂对P3HT:PCBM基太阳能电池的影响

以poly(3-hexylthiophene)(P3HT)为电子给体材料,[6,6]-phenyl-C60-butyric acid methyl ester (PCBM)为电子受体材料,制备了纯氯苯(CB)溶剂、纯氯仿(CF)溶剂和氯苯/氯仿(CB/CF)不同比例混合溶剂的共混体系太阳能电池.研究了不同溶剂及不同比例混合的混合溶剂对电池性能的影响.结果表明:以CB/CF(3/1)为溶剂制备的器件,紫外可见吸收光谱和器件外量子效率曲线显示出红移现象,原子力显微图表明P3HT和PCBM间形成良好的相分离结构.在100 mW/cm2强度光照射下,其开路电压Voc为0.61 V短路电流密度Jsc为9mA/cm2,填充因子FF为57.9％,能量转换效率PCE为3.2％.     

大气压冷等离子体射流灭活子宫颈癌Hela细胞

研究了大气压冷等离子体射流对子宫颈癌Hela细胞的灭活机制. 在倒置显微镜下观察不同等离子体处理条件下的细胞形态, 并通过中性红吸收测试定量测定各个条件下的细胞存活率. 将功率维持在18 W, 在900 mL/min 氩等离子体中添入氧气的百分含量分别为1%, 2%, 4% 和8%的条件下处理Hela细胞, 探讨活性气体氧气在惰性气体氩气中的百分含量对Hela癌细胞灭活效率的影响, 发现添加2%氧气时, 氩/氧等离子体灭活效果最佳, 处理180 s后细胞存活率可降至7%. 当继续添加氧超过2%时, 灭活效果逐渐减弱, 直至8%时, 其效果反而不如单纯氩等离子体. 通过测量等离子体发射光谱, 结果表明活性氧自由基在癌细胞灭活过程中可能起关键作用. 关键词： 大气压冷等离子体射流 Hela癌细胞 存活率 发射光谱     

三元铱配合物磷光体系的白光有机电致发光器件光谱特性研究

将黄光磷光材料bis[2-(4-tertbutylphenyl)benzothiazolato-N,C2’]iridium (acetylacetonate) [(t-bt)₂Ir(acac)]超薄层作为黄光发光层,两个蓝光磷光染料iridium(Ⅲ) bis(4’,6’-difluorophenylpyridinato)tetrakis(1-pyrazolyl)borate (FIr6)和bis[(4,6-difluorophenyl)-pyridinato-N,C2’](picolinate) iridium (Ⅲ) (FIrpic)掺杂层作为蓝光发光层,制备了三元发光层的白光有机电致发光器件。该器件具有三元磷光染料分子协同发光特性,并且利用合适厚度的隔层,将三线态激子束缚在各自激子复合区域内,获得了稳定电致发光光谱,CIE色坐标为(0.29±0.01, 0.34±0.01),处于理想的白光区域。通过器件电学特性的测试,验证了磷光染料在三元发光层器件中电致发光作用的机理,同时结果表明,三元发光层器件由于稳定的激子复合区域而有效减弱了器件效率滚降现象。     

等离子体电极普克尔盒电光开关单脉冲过程数值模拟

采用流体模型对等离子体电极普克尔盒(PEPC)电光开关单脉冲过程进行了数值模拟分析.模型包括带电粒子连续性方程、动量守恒方程、电子平均能量方程及空间电位泊松方程.分别采用隐式指数差分格式，超松弛迭代法(SOR)和经典四阶龙格-库塔法(R-K)对带电粒子连续性方程，泊松方程和电子平均能量方程进行数值求解.模拟分析了PEPC单脉冲过程中的带电粒子浓度、电子温度、空间电场、PEPC的放电电流、晶体两侧电压和开关效率的时间演化特性.模型得出了PEPC中气体放电等离子体的微观物理过程与PEPC宏观参量的关系，对设计 关键词： 等离子体电极普克尔盒 电光开关 数值模拟 气体放电     

超短脉冲激光微束对细胞作用的研究

本文详细地介绍了我们自己设计和安装的一个Nd:YAG超短脉冲激光微束系统,该系统分成二个部分:激光源和显微镜。由电光调Q非稳腔Nd:YAG激光倍频后得到355nm紫外光进入显微镜并由物镜聚焦。同时,这超短脉冲激光微束照射在细胞上并且在细胞上产生一个可以自恢复的小孔。在文中我们还讨论了超短脉冲激光微束与细胞之间作用效应及机理。     

Correlation of band electronic structure with efficiency in perovskite solar cells with vanadium (Ⅳ) oxide thin film buffers

Perovskite solar cells have been studied extensively in the area of perovskite solar cells because they have a comparatively free hysteresis. Through fabrication of a perovskite solar cell based on a vanadium oxide buffer, this study clarified the mechanism of electron and hole transport in the laminated layer upon irradiation with light. The power conversion efficiency (PCE) of the Vanadium (Ⅳ) oxide (VO₂) sputtering process device was approximately 13% and with the spin-coating process was 8.5%. To investigate the physicochemical origin of such PCE differences depending on the process type, comprehensive band alignment and band structure analyses of the actual cell stacks were performed using X-ray photoelectron spectroscopy depth measurements. Accordingly, it was found that the inconsistent valence band offset between the perovskite absorption layer and V₂O₅ layer as a function of the VO₂ process type caused a difference in the hole transport, resulting in the difference in the efficiency.     

Emitting layer analysis of blue thermally activated delayed fluorescence devices using capacitance–voltage method

In this paper, blue thermally activated delayed fluorescence (TADF) organic light-emitting diodes (OLEDs) have been elucidated, with a focus on the degradation characteristics of the emission layer (EML). The operational stability against electrical stress was investigated for two host materials and four doping concentrations, which were used as the EML. The operating stability of the devices was confirmed by comparing the peak capacitance before and after degradation. Devices using bis [2-(diphenyl-phosphino) phenyl] ether oxide (DPEPO) as a host exhibited poor degradation characteristics. However, high stability was confirmed when 3,3-di (9H-carba-zol-9-yl)-biphenyl (mCBP) was used. DPEPO host devices are most resistant against performance degradation when they are doped with 10 wt% 10,10'-(4,4′-sulfonylbis(4,1-phenylene))bis(9,9-dimethyl-9,10-dihydroacridine (DMAC-DPS). We successfully determined the electroluminescence characteristics of the device depending on the host material, as well as the doping concentration, using the capacitance–voltage method.     

Metal grid technologies for flexible transparent conductors in large-area optoelectronics

Mechanically flexible optoelectronic devices such as flexible displays, touch-screens, wearable electronics and solar cells are attracting significant commercial interest. In these devices, a transparent conductor is an essential element that delivers or collects the electrical current to the active material while it allows light to enter or exit from the device. The transparent conductor is composed of a transparent conductive film and a metallic grid providing electrical conduction over the large area. In this article, we review the established processes used by the industry as well as emerging solution-based methods for processing metal grids. Furthermore, we review the issues and potentials of these emerging processes facing for large-area deployment. In the final section, we evaluate three applications of flexible transparent conductors in: perovskite-based solar cells, organic light emitting diodes and electrochromic windows.