磁场对基于Co铁磁薄膜的有机发光器件效率和电流的影响

制备结构为ITO/Co/NPB/Alq₃/LiF/Al的有机发光器件,测量了室温下磁场对器件发光效率和电流的影响.发现磁场强度小于80 mT时,器件发光效率随磁场强度的增加而增大,最大为18.8%,随磁场强度的继续增加发光效率的增强趋于饱和.效率的增加是Co的自旋极化的注入和磁场效应共同作用的结果,其中自旋极化注入起主要作用.在磁场强度小于60 mT时电流随磁场增强而增加,最大为6.9%,随磁场强度的进一步增加电流的增加有所减弱.产生这种现象的原因可归结为磁场相关的单线态极化子对的解 关键词： 有机电致发光 自旋极化 磁场效应     

盖革模式下反偏压对雪崩光电二极管贯穿特性的影响

利用无源抑制技术,研究了盖革模式下雪崩光电二极管（APD）的电流一电压特性。发现光电流和暗电流的一个显著区别是暗电流不反映贯穿特性,这是光生栽流子和热载流子有不同统计分布的实验证据,也说明在盖革模式下,暗计数增加比光子探测效率增加更快的原因是由于载流子收集效率不同引起的。根据其贯穿特性适当选择盖革模式下APD的反偏压可提高单光子探测器的信噪比。     

有机/无机复合结构光电导型器件的光激发机制

制备了PVK/ZnS有机无机复合的光电导型器件 ,器件结构分别为Glass/ITO/PVK/Al;Glass/ITO/ZnS/Al;Glass/ITO/ZnS/PVK/Al。通过研究此复合器件在外加电场作用下的稳态光电导激发谱 ,得到了基本光激发过程。把PVK/ZnS的吸收谱和器件的光电导谱进行比较 ,知道虽然两者的吸收对器件光电流都有贡献 ,但有效部分在PVK和ZnS的界面处。最大光电流对外加电场的依赖性与器件的暗电流和光电流谱为此提供了证据     

基于电场调控的高性能紫外无机-有机复合结构光电探测器

通过溶液旋涂制备了结构为ITO/ZnO/P3HT:ITIC/Ag的紫外无机-有机复合结构光电探测器,混合膜中聚合物给体(P3HT)和非富勒烯小分子受体(ITIC)的质量比为100:1.由于载流子传输通道不连续,器件在零偏压下的暗电流密度很小,为5.8×10-10 A·cm-2,为器件实现外加电场可调和光电流倍增提供了条...     

氮化物抛物量子阱中磁极化子的能量

利用改进的Lee-Low-Pines(LLP)方法和变分法研究了在外磁场作用下氮化物无限抛物量子阱中自由极化子的能级,得到了极化子基态能量随量子阱阱宽和外磁场变化的规律,对GaN/Al_0.3Ga_0.7N抛物量子阱进行了数值计算.结果表明:外磁场对极化子的能量有明显的影响,极化子基态能量随阱宽的增强而减小,随磁场的增强而增大,并且电子-声子相互作用对氮化物量子阱中极化子能量的贡献是很大的.     

聚合物发光器件中激子的解离与复合效率

对聚合物发光器件中极化子激子的形成与解离过程进行了详细探讨,提出了极化子激子解离的理论模型及解离概率的解析式,分析了激子解离后正、负极化子的输运过程,认为是极化子的链间跃迁实现了聚合物的电导,计算并讨论了内量子效率随外加电场、温度及杂质浓度的变化关系.该模型较好地解释了有关实验现象. 关键词： 聚合物发光器件 极化子激子 激子解离 内量子效率     

PEDOT:PSS薄膜的山梨醇掺杂对光电池性能的影响

采用共混-旋涂技术在ITO导电玻璃上制备出经山梨醇掺杂的PEDOT:PSS导电膜,将所制得的薄膜作为空穴传输层用于有机太阳能电池研究.通过对比分析掺杂前后光电池暗电流曲线与光电流曲线的变化,考察了山梨醇掺杂对器件光伏性能的影响,并就其中的影响机理进行了讨论分析.结果表明,山梨醇的加入,可以明显提高光电池的短路电流,填充因子以及能量转换效率.较未掺杂器件,8wt %山梨醇掺杂条件下,器件短路电流由8.82 mA/cm²增加至11.27 mA/cm²,FF由0.43 关键词： PEDOT:PSS薄膜 山梨醇 有机太阳能电池 性能     

1.7 MeV电子辐照对CdTe太阳电池电流传输特性影响的图谱分析

研究了1.7 MeV的电子辐照对具有Anti-radiation glass/ITO/ZnO/CdS/CdTe/ZnTe/ZnTe∶Cu/Ni结构的碲化镉多晶薄膜太阳电池器件性能的影响。 抗辐照玻璃的使用, 有效防止了普通玻璃受辐照后性能变化对测试结果的影响。 利用光、 暗I-V, C-V, QE, AS等测试手段, 分析了包括开路电压、 短路电流、 转换效率在内的电池性能。 通过对比研究暗电流密度、 分析了辐照对电池电流传输特性的影响。 辐照后短路电流下降很大, 电池效率明显降低。 反向饱和电流密度有所增加, 表明太阳电池的pn结特性受到损伤, 而二极管理想因子几乎不变, 说明太阳电池电流的输运机制未发生了变化。 量子效率曲线证明是由于太阳电池结区损伤影响了光生载流子的收集。 辐照使载流子浓度下降为原来的40.6%。 导纳谱研究最终发生辐照会引入Cd2+缺陷能级, 其位置为Et-Ev=(0.58±0.02)eV, 俘获截面为1.78×10-16 cm2, 表明辐照会影响光生载流子的产生, 增加了载流子复合的概率, 使得反向暗电流增大, 最终导致电池的短路电流衰减。     

自旋注入有机物的扩散理论

根据自旋注入半导体的相关理论， 考虑到有机体内可能同时含有带自旋的单极化子和不带自旋的双极化子两种载流子，从扩散 理论和欧姆定律出发，建立了自旋注入有机体的唯象模型.通过计算发现，适当选择铁磁层极化率或两层的电导率可以使得有机层内电流具有高的自旋极化.进一步研究了单极化子浓度等因素对注入电流极化的影响. 关键词： 自旋电子学 自旋注入 有机聚合物 极化子     

纳米硅结构中分裂能级对光电输运特性的影响

基于电子在分裂能级系统中同时存在的共振隧穿和子带输运过程,结合光生载流子作用提出了纳米硅结构中的光电输运理论模型.利用该模型计算了纳米硅结构在光照条件下的电流密度、电场强度及电子浓度分布.结果表明,光生电子在具有分裂能级的纳米硅中是以共振隧穿为主要输运方式.在此基础上,详细研究了光电流与吸收系数、外加偏压以及纳米硅层层数之间的关系,发现在特定的外界条件下光电流会出现跳变增加的现象,其物理原因是纳米硅结构中电场强度的二次分布.     

磁场对有机电致发光的影响

制备了常规有机发光二极管ITO/NPD/Alq₃/LiF/Al，测量了该器件发光的磁场效应.发现尽管在1T范围内的磁场对发光层Alq₃的光致发光没有影响，但磁场作用下器件的电致发光(MEL)却呈现出明显的磁效应，且MEL与器件的偏压有很强的依赖关系：在小偏压时，随着磁场的增加MEL是单调递增，且在大小约为40kA/m的磁场下达到饱和，之后即使磁场增大到约1T 的情况下也没有变化；但当偏压变大时，MEL则呈现先增加，在40kA/m处达到峰值后却又减弱，而且偏压越大该MEL的减弱则越明显.对所观察到的实验结果进行了定形解释，即三线态激子相互淬灭产生单线态激子和三线态激子与器件中的非平衡载流子相互作用是此效应的物理机理. 关键词： 有机发光 磁场效应 激子淬灭     

Peak and steady-state photocurrents in a molecular diode

It has been shown that the time evolution of a photocurrent under the conditions of the irradiation of a photochromic molecule by moderate-intensity light includes the fast and slow stages of the kinetic process. The fast stage corresponds to an increase in the current and is associated with the charging of the molecule, which is in a singlet excited state after a phototransition. The slow stage includes electron transfer between electrodes involving both charged and excited (singlet and triplet) states of the molecule. When the exchange interaction of unpaired electrons on the HOMO and LUMO levels of the photoexcited molecule is weak, the steady-state photocurrent is close in magnitude to the maximum transient current, whereas the steady-state current is suppressed when the exchange interaction is strong. The reason is that a molecule in the triplet state can block electron transfer between electrodes. The conditions have been found under which such blocking is a manifestation of the peak transient photocurrent that is formed immediately after the beginning of the irradiation of the molecule.     

Time-dependent photocurrent of a CdTe nanoparticle film under the above-gap illumination

Time-dependent photocurrent of a solid film of 1-thioglycerol-capped CdTe nanoparticles under the illumination of the 325-nm wavelength light is characterized to investigate the transport mechanism of photo-generated charge carriers in this nanoparticle film. Under the illumination of the above-gap light, photocurrent rises rapidly, and subsequently it decays or rises slowly, depending on the magnitude of bias voltage. A careful investigation into the variation in the magnitude of the current measured as a function of time while the light was switched on and off periodically reveals that rapidly and slowly respondent photocurrents overlap in the time-dependent photocurrent. Charge carriers contributing to the rapidly and slowly respondent photocurrents are electrons and holes separated from a fraction of excitons excited by the above-gap light. The transport behaviors of these charge carriers may explain the monotonously decay and slow rising of the photocurrent after its rapidly rising under the illumination for the solid film at unbiased and biased voltage, respectively.     

聚合物/TiO2分层光电导型器件的电荷传输特性

研究了聚合物PVK与TiO₂分层光电导器件的电荷传输特性,分别比较了两种器件:器件S₁(ITO/TiO₂/PVK/Al)和器件S₂(ITO/PVK/TiO₂/Al)。实验发现,器件S₁的暗电流远小于器件S₂的暗电流,S₁的正向峰值光电流约是其反向峰值光电流的4倍,而S₂的正向和反向峰值光电流都基本与S₁的反向峰值光电流相近。这是由于PVK/TiO₂界面处有效的电荷转移、恰当的电荷传输层、器件各层间能级匹配及其与电极功函数的匹配影响了光电流的强度大小。由此判断,器件S₁的性能要优于器件S₂。随电压的增大,S₁结构的光电导响应谱在短波区域的拖尾增大,而S₂结构几乎没有拖尾,这可能是两种结构的吸收和陷阱能级的差别造成的。     

Low-frequency noise properties of p-type GaAs/AlGaAs heterojunction detectors

We have measured and analyzed, at different temperatures and bias voltages, the dark noise spectra of GaAs/AlGaAs heterojunction infrared photodetectors, where a highly doped GaAs emitter is sandwiched between two AlGaAs barriers. The noise and gain mechanisms associated with the carrier transport are investigated, and it is shown that a lower noise spectral density is observed for a device with a flat barrier, and thicker emitter. Despite the lower noise power spectral density of flat barrier device, comparison of the dark and photocurrent noise gain between flat and graded barrier samples confirmed that the escape probability of carriers (or detectivity) is enhanced by grading the barrier. The grading suppresses recombination owing to the higher momentum of carriers in the barrier. Optimizing the emitter thickness of the graded barrier to enhance the absorption efficiency, and increase the escape probability and lower the dark current, enhances the specific detectivity of devices.     

Photostimulated currents and magnetic spin effects in organic <Emphasis Type="Italic">p-n</Emphasis> polymeric heterostructures

Generation of charged current carriers in photovoltaic cells with polymeric p-n heterostructures as an active layer was studied. Photo- and thermofield stimulation of Pool-Frenkel type states at the p-n interface of polymeric heterostructures based on p (doped polyimides) and n type (doped carbazolyl-containing polymers and polyesteramides) was found to cause the generation of current carriers and observation of photostimulated currents. These states are interpreted as stabilized pairs of charges consisting of carriers captured by deep charged centers with the opposite sign. They are presumably formed at the interface as a result of an irreversible photochemical reaction of the free radical type of a radical-ion pair, which appears in the phototransfer of an electron from a donor polyimide fragment to an excited dopant particle. The effectiveness of the formation and accumulation of these states was found to increase as the surface area and the degree of interface development (sharp, diffuse, volume) grew. Photostimulated currents were shown to influence the photovoltaic characteristics of cells based on polymeric p-n heterostructures: an increase in short circuit photocurrent (by more than an order of magnitude for a volume interface and by several times for a diffusion interface) was observed, and free running voltage increased (to 1.2–1.4 V). This allows the energy effectiveness of photovoltaic cells to be substantially increased at a moderate increase in temperature (by no more than 20–30°C), in particular, because of nonactinic light source IR radiation. The formation of ion-radical pairs and their relation to Pool-Frenkel states is substantiated by observed positive magnetic field influence (H < 1 kOe, T = 293−323 K) on the yield of luminescence of dopant particles and photostimulated current (magnetic spin effects by the hyperfine interaction mechanism).     

Phenomena caused by the capture of carriers injected into illuminated cadmium selenide single crystals

The current-voltage characteristics of the dark current and the photocurrent excited by light from the edge region of the fundamental absorption have been measured for CdSe single crystals fitted with sandwichtype indium-gallium electrodes and guard rings to eliminate surface currents. At a certain voltage, the photocurrent characteristics show a tendency toward saturation, due to the filling of traps by charge carriers injected from the cathode, which causes a reduction of the conduction-electron mobility.     

紫外光辐照对TiO2纳米线电输运性能的影响及磁阻效应研究

采用溶胶凝胶法以及静电纺丝法, 利用热处理工艺, 成功制备出了多晶锐钛矿型TiO₂纳米线, 通过两线法在室温下测试单根TiO₂纳米线的V-I曲线来研究其电输运性能及磁阻效应. 结果表明: 在无光照环境下其V-I曲线为不过零点的直线, 零场电阻较大, 在磁场作用下电阻下降, 表现出负磁阻效应; 紫外光辐照环境下TiO₂纳米线载流子浓度增加使得电阻变小, 然而在磁场作用下电阻增大, 表现为正磁阻效应. 紫外光辐照导致的载流子浓度变化, 使得负磁阻转变为正磁阻, 我们将磁阻变化归结为d电子局域导致的负磁阻与能带劈裂导致的正磁阻两种机理相互竞争的结果.     

InGaN/GaN多量子阱LED载流子泄漏与温度关系研究

通过测量光电流,直接观察了InGaN/GaN量子阱中载流子的泄漏程度随温度升高的变化关系。当LED温度从300K升高到360K时,在相同的光照强度下,LED的光电流增大,说明在温度上升之后,载流子从量子阱中逃逸的数目更多,即载流子泄漏比例增大。同时,光电流的增大在激发密度较低的时候更为明显,而且光电流随温度的增加幅度与激发光子的能量有关。用量子阱-量子点复合模型能很好地解释所观察到的实验现象。实验结果直接证明,随着温度的升高,InGaN/GaN量子阱中的载流子泄漏将显著增加,而且在低激发密度下这一效应更为明显。温度升高导致的载流子泄漏增多是InGaN多量子阱LED发光效率随温度升高而降低的重要原因。     

Current-voltage analysis of a-Si:H Schottky diodes

Direct current (dc)-voltage (I-V) characteristics of the hydrogenated amorphous silicon (a-Si:H) Schottky diode have been measured at different temperatures under dark and light. From the fourth quadrant of illuminated characteristics, fill factor (FF) values were obtained for each temperature measured (173-297 K). We have found that FF increases very little as the temperature is decreased. The measured data from I-V characteristics has been analyzed in detail. In particular, from dark I-V characteristics obtained, the density of state (DOS) near the Fermi level was determined using a simple model based on the space-charge limited current (SCLC). On the other hand, from the illuminated I-V characteristics, the density of carriers was calculated for each temperature using the analysis of diode equation as known. A comparison of the carrier density and the measured photocurrent as a function of the reverse temperature was also made and a good correspondence was obtained.