绿色双溶剂法制备高效稳定钙钛矿太阳能电池

采用毒性小、环境友好的乙二醇甲醚(ethylene glycol monomethyl ether,EGME)与水混合的双溶剂(体积比为1∶1)溶解CsBr,通过提高CsBr的溶解度,减少了后续CsBr的甲醇溶液的旋涂遍数,简化了电池制备流程。通过优化CsBr的甲醇溶液的旋涂遍数发现,在旋涂1遍200 mg·mL^-1 CsBr的水/EGME溶液的基础上旋涂2遍15 mg·mL^-1 CsBr的甲醇溶液,所制备的CsPb-Br₃钙钛矿太阳能电池(perovskite solar cells,PSCs)拥有最佳的性能,实现了1.44 V的开路电压(open-circuit voltage,V_OC),6.26mA·cm^-2的短路电流密度(short circuit current density,J_SC),74.57%的填充因子(fill factor,FF)及最高6.72%的光电转换效率(pho-toelectric conversion efficiency,PCE)。     

绿色双溶剂法制备高效稳定钙钛矿太阳能电池

采用毒性小、环境友好的乙二醇甲醚(ethylene glycol monomethyl ether,EGME)与水混合的双溶剂(体积比为1∶1)溶解CsBr,通过提高CsBr的溶解度,减少了后续CsBr的甲醇溶液的旋涂遍数,简化了电池制备流程。通过优化CsBr的甲醇溶液的旋涂遍数发现,在旋涂1遍200 mg·mL^-1 CsBr的水/EGME溶液的基础上旋涂2遍15 mg·mL^-1 CsBr的甲醇溶液,所制备的CsPb-Br₃钙钛矿太阳能电池(perovskite solar cells,PSCs)拥有最佳的性能,实现了1.44 V的开路电压(open-circuit voltage,V_OC),6.26mA·cm^-2的短路电流密度(short circuit current density,J_SC),74.57%的填充因子(fill factor,FF)及最高6.72%的光电转换效率(pho-toelectric conversion efficiency,PCE)。     

I2界面修饰对全无机CsPbBr3钙钛矿太阳能电池性能的影响

通过在 CsPbBr₃薄膜上旋涂一次 I₂的异丙醇溶液以修饰 CsPbBr₃吸光层,钝化 CsPbBr₃层表面缺陷,改善 CsPbBr₃薄膜形貌。同时通过利用环境友好的绿色溶剂水溶解 CsBr,显著提高了其溶解度,减少了旋涂次数,简化了电池制备流程。实验结果表明,在CsPbBr₃钙钛矿太阳能电池(perovskite solar cells,PSCs)中,使用5 mg·mL^-1 I₂的异丙醇溶液界面修饰的器件具有最佳光伏性能,其最高开路电压(open-circuit voltage,V_OC)为1.55 V,短路电流密度(short circuit current density,J_SC)为7.45 mA·cm^-2,填充因子(fill factor,FF)为85.54%,光电转换效率(photoelectric conversion efficiency,PCE)达到了9.88%。     

I2界面修饰对全无机CsPbBr3钙钛矿太阳能电池性能的影响

通过在 CsPbBr₃薄膜上旋涂一次 I₂的异丙醇溶液以修饰 CsPbBr₃吸光层,钝化 CsPbBr₃层表面缺陷,改善 CsPbBr₃薄膜形貌。同时通过利用环境友好的绿色溶剂水溶解 CsBr,显著提高了其溶解度,减少了旋涂次数,简化了电池制备流程。实验结果表明,在CsPbBr₃钙钛矿太阳能电池(perovskite solar cells,PSCs)中,使用5 mg·mL^-1 I₂的异丙醇溶液界面修饰的器件具有最佳光伏性能,其最高开路电压(open-circuit voltage,V_OC)为1.55 V,短路电流密度(short circuit current density,J_SC)为7.45 mA·cm^-2,填充因子(fill factor,FF)为85.54%,光电转换效率(photoelectric conversion efficiency,PCE)达到了9.88%。     

g-C3N4/双钙钛矿复合材料的制备及氧催化性能

通过溶胶-凝胶法制备出不同Ni掺杂比例的双钙钛矿Sr_2Ni_xCo_(2-x)O_6(x=0.2,0.4,0.6,0.8),通过热分解法制备出具有层状结构的纳米颗粒g-C_3N_4,并制备其复合物催化剂。将双钙钛矿和g-C_3N_4分别制备成双功能电极片,用于测试其对氧还原(ORR)和氧析出(OER)的催化活性,然后选取具有最佳氧催化活性的Ni掺杂比例x=0.4的双钙钛矿与一定重量比例的g-C_3N_4进行复合,测试复合催化剂的氧催化活性。结果表明,复合后的催化剂催化效果明显优于单一催化剂,当g-C_3N_4添加量占双钙钛矿的30%(w/w)时复合催化剂催化氧还原反应的最大电流密度为395.7 mA·cm~(-2)(-0.6 V vs Hg/HgO),氧析出反应的最大电流密度为372.0mA·cm~(-2)(1 V vs Hg/HgO),这表明g-C_3N_4与Sr_2Ni_(0.4)Co_(1.6)O_6复合后协同催化能够提高双钙钛矿的氧催化活性。     

LaF3纳米线的低温溶剂热法制备及形成机理

LaF₃ nanowires with high aspect ratios have been prepared via a low-temperature solvothermal method using LaCl₃ and KF or NH₄F as starting materials in absolute alcohol at 160 ℃ for 12 h. XRD pattern and TEM images show that the products are hexagonal structure with diameter of 80 nm and length up to 8 μm. The lanthanum sources played most important roles, reaction temperature and time also played important roles in the morphology control of final LaF₃ products. The optimal conditions for ideal LaF₃ nanowire are at a reaction temperature of 160 ℃ and reaction time for 14 h using LaCl₃ and NH₄F as starting materials. A possible formation mechanism for LaF₃ nanowires is proposed.     

溶剂热法制备Bi2S3纳米材料

0引言纳米材料具有特殊的结构和性能,可广泛应用于化学、物理学、电子学、光学、机械和生物医药学等领域[1￣5]。其中一维或准一维纳米结构体系或纳米材料的研究既是研究其它低维材料的基础,又与纳米电子器件及微型传感器密切相关,是近年来国内外研究的前沿[6￣9]。近年来,人们虽然做了许多尝试来制备一维纳米结构材料,但合成这类材料特别是合成半导体一维纳米材料仍然是一个巨大的挑战。随着维数的减小,半导体材料的电子能态发生变化,其光、电、声、磁等方面性能与常规体材料相比有着显著的不同[10￣12]。Bi2S3是一种重要的半导体材料,受…     

平板结构高效钙钛矿太阳能电池的旋涂溶液溶剂工程

自2009年首次应用于太阳能电池中以来,有机铅卤化物钙钛矿材料得到了极大关注.据文献报道,有机铅卤化物钙钛矿材料在不同结构的太阳能电池中都得到了应用,其中与有机太阳能电池类似的平板结构钙钛矿具有结构简单、制备容易等优点,非常适合用于柔性电池和多节电池等各种应用.在平板结构的太阳能电池中,制备高质量的钙钛矿薄膜至关重要.真空热蒸镀法虽然可以制备厚度均匀的钙钛矿薄膜,获得高的器件性能,但是设备成本较高,不利于大规模生产.而在溶液法中,早期的一步旋涂法和两步法由于没有多孔金属氧化物的支撑,很难制备均匀的钙钛矿平板薄膜;而气相辅助的两步法虽然制备的薄膜比较均匀,但反应时间却比较长.程一兵研究组采用在旋涂N,N-二甲基甲酰胺(DMF)溶液时滴加氯苯使钙钛矿快速析出结晶的方法,制备了高质量的均匀的CH3NH3PbI3薄膜. Seok研究组采用1,4-丁内酯(GBL)和二甲基亚砜(DMSO)的混和溶剂,在旋涂时滴加甲苯的方法,在多孔二氧化钛上也制得了均匀的CH3NH3PbI3薄膜,取得了很高转化效率(16.7%),但缺少对不同溶剂比例的细致研究,另外,也没有对平板结构电池性能进行研究.
　　本文采用DMF-DMSO和GBL-DMSO作为混合溶剂在二氧化钛致密层上旋涂制备了平板结构的钙钛矿薄膜,并且对混合溶剂的比例对器件性能的影响进行了详细的考察和优化.当纯DMF或纯GBL作为旋涂溶剂时,得到的CH3NH3PbI3钙钛矿薄膜含有大量不连续的晶粒,表面的覆盖度很差,对入射光的吸收远弱于连续均匀的薄膜.而且XRD结果表明,纯DMF或纯GBL作为旋涂溶剂的薄膜残留有前驱体的杂质,对器件性能非常不利.而采用DMSO作为旋涂溶剂时,制得的薄膜表面则比较均匀,几乎达到100%的覆盖.这主要是由于在旋涂溶液中形成了PbI2-CH3NH3I-DMSO的中间相,这样可以避免纯DMF或纯GBL溶剂蒸发时PbI2和CH3NH3I的剧烈反应,因此退火后制得的CH3NH3PbI3薄膜非常均匀.然而由于纯DMSO的高粘度和低挥发速度,并不是非常适合作为旋涂溶剂,因此我们将DMF和GBL加入到DMSO中形成混合溶剂来考察对制备的钙钛矿薄膜质量和器件性能的影响.扫描电镜结果表明,加入20%~40%体积分数的DMF时,形成的薄膜表面非常均匀而且晶粒尺寸很大,达到微米级别,这样有利于减少晶界处的复合,提高电池性能.继续增加DMF比例会导致晶粒减小,晶界和孔隙增多,薄膜表面也更加粗糙.而加入GBL时得到的晶粒要远小于加入DMF时的尺寸,并且随着GBL比例的增加,薄膜的表面变得更加粗糙,孔隙明显增多,严重影响电池性能. XRD结果表明,纯DMSO和混合溶剂制得的薄膜都没有前驱体的残留.紫外可见吸收光谱表明,随着DMF比例的增加,吸收逐渐增强;而随着GBL比例的增加,吸收逐渐减弱.这主要由于不同比例溶剂制得的薄膜厚度有所差异造成的.
　　由相关的薄膜制备的平板结构太阳能电池I-V测试表明：当使用DMF-DMSO混合溶剂时,随着DMF比例由0%增至40%,短路电流和开路电压逐渐增加,填充因子略微减小,总体上导致光电转化效率逐渐增大.随着DMF继续增多,开路电压和填充因子的减小导致转化效率逐渐降低.而当使用GBL-DMSO混合溶剂时,主要受到短路电流的影响,电池的效率明显低于含DMF的混合溶剂的情况,而且随着GBL增多,电池效率逐渐降低.电池的最高转化效率达到了16.5%,最高功率点下固定电压扫描得到的稳态效率也达到了14.4%,高于报道中采用类似结构的电池的性能.由于在整个电池制备过程中,整个实验过程都低于100°C,该方法非常适合未来推广到柔性太阳能电池和多节太阳能电池上.     

溶剂热法制备BiFeO_3基纳米颗粒光催化剂及其性能

以聚酰胺-胺(PAMAM)树形分子为稳定剂,采用溶剂热法制得了纯相BiFeO_3纳米颗粒(A)和BiFeO_3/Bi_(25)FeO_(40)/Fe_2O_3复合纳米颗粒(B),并采用HRTEM、XRD、UV-Vis、SQUID对其结构和性能进行了表征。2种颗粒结晶良好,粒径小于10 nm,能有效光催化降解亚甲基蓝,磁性回收率分别为74.6%(A)和90.2%(B)。BiFeO_3/Bi_(25)FeO_(40)/Fe_2O_3复合纳米颗粒的光催化与磁性能均优于纯相BiFeO_3纳米颗粒,是因为复合纳米颗粒含有多种相,相界面存在异质结构有利于光生载流子的分离和迁移,并且对可见光的吸收能力更强。     

La1-xSrxCoO3(x=0,0.2,0.4,0.6,0.8)钙钛矿型氧化物的催化性能及改性

通过溶胶-凝胶法制备出A位Sr掺杂的钙钛矿型氧化物La_(1-x)Sr_xCoO_3(x=0,0.2,0.4,0.6,0.8),并将其作为催化剂应用于双功能氧电极中。测试结果表明,A位Sr的掺杂的La_(1-x)Sr_xCoO_3比LaCoO_3具有更高的电催化活性,并且La_(0.6)Sr_(0.4)CoO_3在氧还原和氧析出反应中均表现出最优的催化性能,最大电流密度分别达到0.244 A·cm~(-2)(-0.6 V vs Hg/HgO)和0.303 A·cm~(-2)(1 V vs Hg/HgO)。为进一步提高催化剂的催化活性,将水热法制备的α-MnO_2纳米管与La_(0.6)Sr_(0.4)CoO_3复合作为双功能催化剂。当α-MnO_2的质量分数为40%时,比起单一的α-MnO_2或钙钛矿氧化物,α-MnO_2/La_(0.6)Sr_(0.4)CoO_3复合材料表现出协同效应,有更好的双功能电催化活性,使双效氧电极具有更好的电化学性能及稳定性。     

乙二醇辅助水热法制备不同形貌的CaTiO_3/CaTiO_3:Pr微晶

对乙二醇存在下水热法制备CaTiO3微晶的形貌进行了研究。对所得样品用X射线衍射、扫描电子显微镜(SEM)、热重分析及红外光谱(FTIR)进行了表征。结果表明,制备的CaTiO3微晶随着乙二醇和水配比的不同,可以形成立方体、三维十字架形及正十二面体等规整的外形。乙二醇在晶粒表面的配位吸附对这些不同形貌的形成有决定的作用。所得样品粒度分布均匀,基本不团聚。掺杂少量Pr3+离子后对样品的微观形貌基本不影响,在200℃低温水热获得的CaTiO3∶Pr样品就有明显的荧光和长余辉发光性能。样品在900℃煅烧后其外形并不发生变化,也不会团聚,但发光性质得到大幅度提高。     

A review on two-dimensional (2D) and 2D-3D multidimensional perovskite solar cells: Perovskites structures,stability, and photovoltaic performances

Perovskite solar cells (PSCs) fabricated with two-dimensional (2D) halide and 2D-3D mixed-halide materials are remarkable for their optoelectronic properties. The 2D perovskite structures are extremely stable but show limited charge transport and large bandgap for solar cell applications. To overcome these challenges, multidimensional 2D-3D perovskite materials are used to maintain simultaneously, a long-term stability, and high performance. In this review, we discuss the recent progress and the advantages of 2D and 2D-3D perovskite materials as absorber for solar cell applications. First, we discuss the structure and the unique properties of 2D and multidimensional 2D-3D perovskites materials. Second, the stability of 2D and 2D-3D mixed perovskites and the perspects of PSCs are hashed out.     

Advanced composite gel electrolytes prepared with titania nanotube fillers in polyethylene glycol for the solid-state dye-sensitized solar cell

A novel inorganic–organic composite solid electrolyte is prepared by using TiO₂ nanotubes (TiNTs) as filler in polyethylene glycol (PEG) and effectively used for the fabrication of solid-state dye-sensitized solar cells (DSSCs). Comparably high conversion efficiency 4.43% has been observed by using the newly designed inorganic–organic (PEG–TiNTs) composite solid electrolyte. By performing several experiments by using PEG–TiNTs composite solid electrolytes, it was observed that the appropriate ratios of TiNTs and PEG are important to obtain higher conversion efficiency. Moreover, the morphologies, chemical interactions of PEG and TiNTs and their performance to the DSSCs are studied extensively by FESEM, DSC, and XPS measurements.     

Synthesis and electrochemical properties of chemically substituted LiMn2O4 prepared by a solution-based gel method

Lithium manganese oxide, LiMn(2)O(4), and its substituted samples LiM(0.05)Mn(1.95)O(4) (M=Al, Co, and Zn) were first prepared by a cost-saving and effective new solution-based gel method using a mixture of acetate and ethanol as the chelating agent. The physical properties of the synthesized samples were investigated by thermogravimetry/differential thermal analysis, X-ray diffraction, and scanning electronic microscopy. The as-prepared powders were used as positive materials for a lithium-ion battery, whose charge/discharge properties and cycle performance were examined. The results revealed that all the substituted samples had better cycle performance than pure LiMn(2)O(4). Among these synthesized materials, the LiCo(0.05)Mn(1.95)O(4) sample had the best cycle performance. After 30 cycles, its capacity loss was only 3%. Therefore, cyclic voltammetry and electrochemical impedance spectroscopy were employed to characterize the reactions of Li ion insertion into and extraction from LiCo(0.05)Mn(1.95)O(4) electrodes.     

Orientation control of perovskite thin films on glass substrates by the application of a seed layer prepared from oxide nanosheets

Orientation control of perovskite compounds was investigated by the application of a seed layer prepared from oxide nanosheets. An aqueous suspension of oxide nanosheets was prepared by the exfoliation of a layered compound of KCa₂Nb₃O₁₀ oxide grains. A seed layer composed of (TBA)Ca₂Nb₃O₁₀ nanosheets (TBA = tetrabutylammonium) was formed on a glass substrate by simply dip coating it in the suspension. Two kinds of perovskite compounds, LaNiO₃ (LNO) and Pb(Zr,Ti)O₃ (PZT) with a preferred orientation of (00l) were successfully grown on this seeded glass substrate. In this study, the relation between lattice mismatch and electrical properties is investigated. A large, oriented PZT film with a size of 5 ×4 cm shows an improved P-E hysteresis behavior by use of this orientation control.     

两步电泳沉积制备TiO2光阳极用于高效染料敏化太阳能电池

采用不同沉积电压制备TiO₂光阳极,研究电压对薄膜沉积速率、厚度和形貌的影响。通过台阶仪、光学照片、扫描电子显微镜（SEM）、电化学交流阻抗谱、开路电压衰减曲线对光阳极和电池进行系统表征,并测试了染料敏化太阳能电池器件的电流密度-电压（J-V）曲线,计算其光电转换效率。结果表明,提高沉积电压时,光阳极薄膜的沉积速率加快,膜厚也增加,但是电压过高时,薄膜会有裂缝和覆盖不全的问题,这会对电池的效率造成负面影响。综合考虑低沉积电压条件下薄膜均匀无裂缝和高沉积电压条件下沉积速率快的优点,采用先30 V电压、后60 V电压的电泳沉积方式来制备光阳极,结果呈现协同效果,既降低了制备时间又得到高质量的薄膜,在无其他修饰的情况下,电池的光电转换效率可以达到7.29%。