长链双烷基次膦酸作为共吸附剂修饰TiO_2光阳极

对TiO2/染料/电解质界面进行修饰是提高染料敏化太阳电池(DSC)性能的有效手段,其中引入共吸附剂有机小分子和染料共同吸附在TiO2表面是一种简单有效提高DSC性能的方法.本文合成了长链的双正十二烷基次膦酸(DDdPA)作为染料的共吸附剂应用于染料敏化太阳电池.通过红外光谱(FT-IR)表征DDdPA在TiO2表面的吸附;借助电化学阻抗谱(EIS)及强度调制光电流谱(IMPS)/强度调制光电压谱(IMVS)等技术表征了电子的传输与复合动力学过程.研究发现,DDdPA可以很好地与染料共同吸附在TiO2表面;与二(3,3-二甲基丁基)次膦酸(DINHOP)相比,DDdPA的引入可以更好地抑制TiO2/染料/电解质界面处的电子复合;在优化浓度配比下,DDdPA的引入有效提高了器件的电子寿命,使TiO2导带边负移约30 mV,最终使器件的开路电压提高了47 mV,光电转换效率提升约10%.     

锌掺杂对TiO2染料敏化电池光阳极中电荷俘获态分布及电子复合过程的影响

基于瞬态光电压和瞬态光电流技术研究了锌掺杂的TiO2染料敏化太阳能电池中电子复合及传输的动力学行为.通过实验获得了不同阳极掺杂条件下的电子复合时间常数与电子收集时间常数,考察了锌掺杂对电池阳极材料导带能级和电子俘获态的影响.研究结果表明,锌的掺杂在提高TiO2导带能级的同时延长了俘获态电子的复合时间常数,从而大大提高了电池的开路电压.     

有序宏孔-介孔TiO_2薄膜的制备及其在染料敏化太阳能电池中的应用

我们使用表面活性剂P123和聚苯乙烯球双模板技术,合成了多级有序的宏孔/介孔TiO2薄膜,并将其与P25多孔薄膜复合形成双层结构的染料敏化太阳能电池光阳极.实验结果表明,宏孔/介孔TiO2薄膜层的引入,有效地提高了光阳极对太阳光的散射以及捕获能力,从而提高了染料敏化太阳能电池的光电转化效率.与使用单一P25光阳极的染料敏化太阳能电池相比,双层TiO2结构的染料敏化太阳能电池所产生的短路光电流密度从7.49上升到了10.65mA/cm2,开路电压也从0.65提高到了0.70V.在太阳光强度为AM1.5时所测得的光电转化效率表明,双层TiO2结构的染料敏化太阳能电池的光电转化效率为5.55%,比单层P25结构的染料敏化太阳能电池的光电转化效率提升了83%.     

聚合物/TiO2杂化纳米纤维微孔膜的制备及其在染料敏化太阳能电池中的应用

利用静电纺丝技术,制备了不同的聚合物/TiO2杂化纳米纤维微孔膜,吸附液体电解质后形成聚合物/TiO2杂化纳米纤维微孔膜准固态电解质,应用于制备准固态染料敏化太阳能电池(DSSCs).测试了电纺聚合物纳米纤维微孔膜电解质的吸液率、孔隙率、离子电导率等参数,研究了纳米纤维微孔膜准固态电解质DSSCs的光伏性能.结果显示,TiO2的掺入可提高聚合物/TiO2杂化纳米纤维微孔膜对液态电解质的浸润扩散性能,从而提高纳米纤维微孔膜对液态电解质的吸附能力.组装的DSSCs的光电转换效率可达液态电解质的90%以上,并具有较好的长期工作稳定性.     

高相转变温度的离子凝胶电解质基准固态染料敏化太阳电池

染料敏化太阳电池(DSC)以其低价、高效等优势, 成为学术界和工业界的研究热点. 传统液态电解质由于易挥发、易泄漏等问题, 导致基于液态电解质的电池难以保持长期稳定, 影响光伏技术的应用. 本文合成了N,N'-1,5-戊二基双月桂酰胺, 将其作为有机小分子胶凝剂(LMOG)胶凝离子液体电解质(ILE)制备了离子凝胶电解质(IGE)并组装成准固态电池(QS-DSCs). 差示扫描量热测试显示该凝胶电解质的相转变温度(T_gel)为104.7℃, 具有良好的本征热稳定性.利用循环伏安法、电化学阻抗谱、调制光电压/光电流谱分别研究了液态电池和准固态电池内部电子传输和复合动力学过程. 结果表明, 凝胶电解质的三维网络结构加速了TiO₂光阳极/电解质界面电子与电解质中I₃^-的复合过程, 使电子寿命降低, 导致准固态电池的光电转换效率略低于液态电池. 在AM1.5 (100 mW·cm^-2)及50℃条件下的加速老化测试结果显示, 持续老化1000 h后其光电转换效率(η)无衰减,而液态电池的光电转换效率衰减为初始值的86%, 表明准固态电池具有良好的光热稳定性.     

纳米氧化镍浓度对磁性准固态染料敏化太阳能电池的影响

以琼脂糖为聚合物基质,N-甲基-2-吡咯烷酮(NMP)为溶剂,磁性纳米氧化镍颗粒作为添加剂用于制备染料敏化太阳能电池(DSSC)的磁性聚合物电解质。通过SEM与离子电导率测试研究不同纳米氧化镍掺杂浓度对磁性聚合物电解质的影响,并对相应的染料敏化太阳能电池进行光电性能测试与电化学交流组抗谱(EIS)测试,结果表明:1.0wt%的纳米氧化镍掺杂浓度为最优掺杂浓度,在此浓度下聚合物电解质的表面形貌较为平整,同时电解质具备最高离子电导率(2.43×10-3S.cm-1);染料敏化太阳能电池的光电效率与电子寿命均随着纳米氧化镍掺杂浓度的增加而先增加后降低,并都在纳米氧化镍掺杂浓度为1.0wt%达到最大,此时电池的光电效率为1.63%、开路电压为0.57 V、短路电流密度为5.8 mA.cm-2、填充因子为0.53。     

基于偏氟乙烯-六氟丙烯共聚物凝胶电解质的染料敏化太阳电池光电性能研究

采用偏氟乙烯-六氟丙烯共聚物[P(VDF-HFP)]胶凝3-甲氧基丙腈基液体电解质, 成功制备了凝胶电解质并组装成准固态染料敏化太阳电池. 差示扫描量热测试结果表明凝胶电解质的溶液-凝胶转变温度(TSG)为71 ℃. 利用电化学方法分析了凝胶电解质中 电对的表观扩散系数及电导率低于液体电解质的原因, 同时结合暗态伏安法考察了电池内部TiO2多孔薄膜电极/电解质界面处的暗反应, 分析了凝胶化对电池光伏性能的影响. 进一步老化实验结果表明凝胶电池的稳定性明显优于液体电池.     

染料敏化太阳能电池用琼脂糖基磁性聚合物电解质的电化学性能

以琼脂糖为聚合物基质,N-甲基吡咯烷酮为溶剂,磁性纳米粒子四氧化三铁为无机纳米颗粒添加剂制备了用于染料敏化太阳能电池(DSSC)的磁性聚合物电解质.通过研究不同小分子表面活性剂,聚乙二醇(PEG200)、曲拉通(TritonX-100)、乙酰丙酮和三者混合的表面活性剂对掺杂有1%(w)Fe3O4的磁性聚合物电解质离子电导率的影响,发现PEG200的加入可有效提高琼脂糖基磁性聚合物电解质的离子电导率.同时,对不同PEG200浓度添加下的电解质进行离子电导率测试研究发现:当PEG200加入量为61.8%(w)时,电解质具有最佳的离子电导率(2.88×10-3S·cm-1);对染料敏化太阳能电池进行电化学交流阻抗谱(EIS)测试的结果表明:染料敏化太阳能电池的电子寿命和复合电阻随着PEG200浓度的增加是先增大后减小,最大的电子寿命和复合电阻出现在PEG200浓度为68.3%(w)处.     

CulnS2量子点敏化太阳能电池中尺寸依赖的电子注入和光电性质

研究了CulnS2(CIS)量子点敏化太阳能电池(QDSSCs)的电子注入和器件性能与粒子尺寸之间的依赖关系.首先合成了不同尺寸的CulnS2量子点(QDs),制备了CulnS2量子点敏化的TiO2薄膜,并组装了量子点敏化太阳能电池.通过循环伏安法确定了CulnS2量子点的能级位置.采用时间分辨荧光光谱分析测量了CulnS2量子点到TiO2薄膜的电子转移速率和效率.结果发现,随着粒子尺寸从4.0 nm减小到2.5nm,电子注入速率略微增加而电子注入效率减小,同时量子点敏化太阳能电池的开路电压基本不变,而光电转换效率、短路电流和填充因子(FF)均减小.上述研究结果表明量子点敏化太阳能电池性能的优化可以通过改变量子点的尺寸来实现.     

N,N-二甲基碘化铵:染料敏化太阳能电池钙钛矿前驱体电解质的高效添加剂

钙钛矿前驱体（PbI₂和CH₃NH₃I）分散体系，作为一种新型染料敏化太阳能电池（Dye-sensitized Solar Cells，DSSCs）电解质，光电流和光电压的继续提升是其发展过程中亟待解决的问题.在本工作中，研究发现，通过引入二甲基碘化铵（DMAI）作为钙钛矿前驱体电解质的高效添加剂，可将光电流密度从12.85 mA·cm^-2急剧提升至19.19 mA· cm^-2.借助阻抗和塔菲尔曲线分析，发现其光电流的增加与TiO₂半导体导带的向上移动对不平衡载流子复合的抑制作用具有一定的相关性.进一步通过叔丁基吡啶的调节作用，可将光电转换效率提高到8.46%，超过了传统的碘电解质.也为染料敏化太阳能电池的研究开辟了新的途径.     

Molecular engineering and theoretical investigation of organic sensitizers based on indoline dyes for quasi-solid state dye-sensitized solar cells

Novel indoline dyes, I-1-I-4, with structural modification of π-linker group in the D-π-A system have been synthesized and fully characterized. Molecular engineering through expanding the π-linker segment has been performed. The ground and excited state properties of the dyes have been studied by means of density functional theory (DFT) and time-dependent DFT (TD-DFT). Larger π-conjugation linkers would lead to broader spectral response and higher molar extinction coefficient but would decrease dye-loaded amount on TiO(2) electrode and LUMO level. While applied in DSSCs, the variation trends in short-circuit current density (J(sc)) and open-circuit voltage (V(oc)) were observed to be opposite to each other. The internal reasons were studied by experimental data and theoretical calculations in detail. Notably, I-2 showed comparable photocurrent values with liquid and quasi-solid state electrolyte, which suggested through molecular engineering of organic sensitizers the dilemma between optical absorption and charge diffusion lengths can be balanced well. Through studies of photophysical, electrochemical, and theoretical calculation results, the internal relations between chemical structure and efficiency have been revealed, which serve to enhance our knowledge regarding design and optimization of new sensitizers for quasi-solid state DSSCs, providing a powerful strategy for prediction of photovoltaic performances.     

Quantification of the effect of 4-tert-butylpyridine addition to I-/I3- redox electrolytes in dye-sensitized nanostructured TiO2 solar cells

Addition of 4-tert-butylpyridine (4TBP) to redox electrolytes used in dye-sensitized TiO2 solar cells has a large effect on their performance. In an electrolyte containing 0.7 M LiI and 0.05 M I2 in 3-methoxypropionitrile, addition of 0.5 M 4TBP gave an increase of the open-circuit potential of 260 mV. Using charge extraction and electron lifetime measurements, this increases could be attributed to a shift of the TiO2 band edge toward negative potentials (responsible for 60% of the voltage increase) and to an increase of the electron lifetime (40%). At a lower 4TBP concentration the shift of the band edge was similar, but the effect on the electron lifetime was less pronounced. The working mechanism of 4TBP can be summarized as follows: (1) 4TBP affects the surface charge of TiO2 by decreasing the amount of adsorbed protons and/or Li+ ions. (2) It decreases the recombination of electrons in TiO2 with triiodide in the electrolyte by preventing triiodide access to the TiO2 surface and/or by complexation with iodine in the electrolyte.     

Anionic structure-dependent photoelectrochemical responses of dye-sensitized solar cells based on a binary ionic liquid electrolyte

Room temperature ionic liquids (RTILs) have been used as electrolytes to investigate the anionic structure dependence of the photoelectrochemical responses of dye-sensitized solar cells (DSCs). A series of RTILs with a fixed cation structure coupling with various anion structures are employed, in which 1-methyl-3-propylimidazolium iodide (PMII) and I(2) are dissolved as redox couples. It is found that both the diffusivity of the electrolyte and the photovoltaic performance of the device show a strong dependence on the fluidity of the ionic liquids, which is primarily altered by the anion structure. Further insights into the structure-dependent physical properties of the employed RTILs are discussed in terms of the reported van der Waals radius, the atomic charge distribution over the anion backbones, the interaction energy of the anion and cation, together with the existence of ion-pairs and ion aggregates. Particularly, both the short-circuit photocurrent and open-circuit voltage exhibit obvious fluidity dependence. Electrochemical impedance and intensity-modulated photovoltage/photocurrent spectroscopy analysis further reveal that increasing the fluidity of the ionic liquid electrolytes could significantly decrease the diffusion resistance of I(3)(-) in the electrolyte, and retard the charge recombination between the injected electrons with triiodide in the high-viscous electrolyte, thus improving the electron diffusion length in the device, as well as the photovoltaic response. However, the variation of the electron diffusion coefficients is trivial primarily due to the effective charge screening of the high cation concentration.     

P(VDF-HFP)基凝胶电解质染料敏化纳米TiO2薄膜太阳电池

采用循环伏安法(CV)研究了凝胶电解质中I₃-/I-氧化还原行为,凝胶电解质中I₃-/I-的表观扩散系数和相应的稳态扩散电流明显低于液体电解质.通过对阴/阳离子的结合能和孔穴阻塞作用的研究解释了凝胶电解质电导率较液体电解质发生变化的原因.制备的凝胶电解质电池具有较高的光电转换效率(6.6%),其短路电流密度(Jsc)仅比液体电解质电池低0.3-0.4 mA/cm²,电池效率也仅低约0.6%.     

Recent research progress on quasi-solid-state electrolytes for dye-sensitized solar cells

Dye-sensitized solar cells(DSSCs) are the most promising, low cost and most extensively investigated solar cells. They are famous for their clean and efficient solar energy conversion. Nevertheless this, long-time stability is still to be acquired. In recent years research on solid and quasi-solid state electrolytes is extensively increased. Various quasi-solid electrolytes, including composites polymer electrolytes, ionic liquid electrolytes,thermoplastic polymer electrolytes and thermosetting polymer electrolytes have been used. Performance and stability of a quasi-solid state electrolyte are between liquid and solid electrolytes. High photovoltaic performances of QS-DSSCs along better long-term stability can be obtained by designing and optimizing quasi-solid electrolytes. It is a prospective candidate for highly efficient and stable DSSCs.     

Double-layer coating of SrCO3/TiO2 on nanoporous TiO2 for efficient dye-sensitized solar cells

Surface modification plays a crucial role in improving the efficiency of dye-sensitized solar cells (DSSCs), but the reported surface treatments are in general superior to the untreated TiO(2) but inferior to the typical TiCl(4)-treated TiO(2) in terms of solar cell performance. This work demonstrates a two-step treatment of the nanoporous titania surface with strontium acetate [Sr(OAc)(2)] and TiCl(4) in order, each step followed by sintering. An electronically insulating layer of SrCO(3) is formed on the TiO(2) surface via the Sr(OAc)(2) treatment and then a fresh TiO(2) layer is deposited on top of the SrCO(3) layer via the TiCl(4) treatment, corresponding to a double layer of Sr(OAc)(2)/TiO(2) coated on the TiO(2) surface. As compared to the typical TiCl(4)-treated DSSC, the Sr(OAc)(2)-TiCl(4) treated DSSC improves short-circuit photocurrent (J(sc)) by 17%, open-circuit photovoltage (V(oc)) by 2%, and power conversion efficiency by 20%. These results indicate that the Sr(OAc)(2)-TiCl(4) treatment is better than the often used TiCl(4) treatment for fabrication of efficient DSSCs. Charge density at open circuit and controlled intensity modulated photocurrent/photovoltage spectroscopy reveal that the two electrodes show almost same conduction band level but different electron diffusion coefficient and charge recombination rate constant. Owing to the blocking effect of the SrCO(3) layer on electron recombination with I(3)(-) ions, the charge recombination rate constant of the Sr(OAc)(2)-TiCl(4) treated DSSC is half that of the TiCl(4)-treated DSSC, accounting well for the difference of their V(oc). The improved J(sc) is also attributed to the middle SrCO(3) layer, which increases dye adsorption and may improve charge separation efficiency due to the blocking effect of SrCO(3) on charge recombination.     

Mg(OOCCH(3))(2) as an electrolyte additive for quasi-solid dye-sensitized solar cells: with the purpose of enhancing both the photovoltage and photocurrent by modifying the TiO(2)/dye/electrolyte interfaces

The interface modification effect within quasi-solid dye-sensitized solar cells and the photovoltaic performance were investigated after the introduction of Mg(OOCCH(3))(2) as an additive into a polymer gel electrolyte. Electrochemical impedance spectroscopy showed that the addition of Mg(OOCCH(3))(2) into the polymer gel electrolyte can efficiently retard charge recombination at the TiO(2)/electrolyte interface. Mg(OOCCH(3))(2) in the electrolyte can also contribute to the enhancement of the incident photon-to-electron conversion efficiency by modifying the dye molecules. This results in an improvement in the photovoltage and photocurrent due to a barrier layer at the TiO(2)/electrolyte interface and the promotion of charge injection at the dye/TiO(2) interface, respectively. Photovoltaic measurements reveal that a conversion efficiency enhancement from 4.05% to 4.96% under 100 mW cm(-2) is obtained after the amount of Mg(OOCCH(3))(2) added was optimized.     

Effect of Surface Protonation on Device Performance and Dye Stability of Dye-sensitized TiO2 Solar Cell

A flat thin TiO₂ film was employed as the photo-electrode of a dye sensitized solar cell (DSSC), on which only a geometrical mono-layer of dye was attached. The effect of sur-face protonation by HCl chemical treatment on the performance of DSSCs was studied. The results showed that the short-circuit current Jsc increased significantly upon the HCl treatment, while the open-circuit voltage Voc decreased slightly. Compared to the untreated DSSC, the Jsc and energy conversion efficiency was increased by 31% and 25%, respectively, for the 1 mol/L HCl treated cell. TiO₂ surface protonation improved electronic coupling between the chemisorbed dye and the TiO₂ surface, resulting in an enhanced electron in-jection. The decreased open-circuit voltage after TiO₂ surface protonation was mainly due to the TiO₂ conduction band edge downshift and was partially caused by increased electron recombination with the electrolyte. In situ Raman degradation study showed that the dye stability was improved after the TiO₂ surface protonation. The increased dye stability was contributed by the increased electron injection and electron back reaction with the electrolyte under the open-circuit condition.     

The influence of dye structure on charge recombination in dye-sensitized solar cells

Replacing the nonyl groups on the solar cell dye Ru(4,4'-carboxylic acid-2,2'-bipyridine)(4,4'-dinonyl-2,2'-bipyridine)(NCS)(2) (Z-907) with amino groups results in a marked decrease in solar cell performance. This is despite the fact that the amino derivative (Z-960) has more favourable light absorption characteristics than Z-907 when used with thick nanocrystalline TiO(2) layers. Electron transfer to the electrolyte from the exposed fluorine-doped tin oxide (FTO) substrate is particularly fast in cells employing the Z-960 dye if a compact TiO(2) blocking layer is not used. The kinetics of electron transfer from the nanocrystalline TiO(2) layer in DSCs employing Z-960 are comparable to those of bare TiO(2) and ca. 2 to 5 times faster than for cells employing Z-907. The faster charge recombination in cells employing Z-960 lowers open-circuit photovoltage and results in very significant charge collection losses that lower short-circuit photocurrent. Voltammetric measurements show that surface modification of FTO electrodes with Z-960 results in slightly more facile charge transfer to acceptor species in triiodide/iodide electrolytes in the dark. A simpler molecule, p-aminobenzoic acid, more dramatically catalyses this charge transfer reaction. Conversely, chemical modification of FTO electrodes with Z-907 or p-toluic acid retards charge transfer kinetics. Similar results are obtained for nanocrystalline TiO(2) electrodes modified with these benzoic acid derivatives. These results strongly imply that surface adsorbed molecules bearing amino groups, including dye molecules, can catalyse charge recombination in dye-sensitized solar cells.