Defect Engineering in Earth-Abundant Cu_(2)ZnSnSe_(4) Absorber Using Efficient Alkali Doping for Flexible and Tandem Solar Cell Applications

To demonstrate flexible and tandem device applications,a low-temperature Cu_(2)ZnSnSe_(4)(CZTSe)deposition process,combined with efficient alkali doping,was developed.First,high-quality CZTSe films were grown at 480℃by a single co-evaporation,which is applicable to polyimide(PI)substrate.Because of the alkali-free substrate,Na and K alkali doping were systematically studied and optimized to precisely control the alkali distribution in CZTSe.The bulk defect density was significantly reduced by suppression of deep acceptor states after the(NaF+KF)PDTs.Through the low-temperature deposition with(NaF+KF)PDTs,the CZTSe device on glass yields the best efficiency of 8.1%with an improved Voc deficit of 646 mV.The developed deposition technologies have been applied to PI.For the first time,we report the highest efficiency of 6.92%for flexible CZTSe solar cells on PI.Additionally,CZTSe devices were utilized as bottom cells to fabricate four-terminal CZTSe/perovskite tandem cells because of a low bandgap of CZTSe(~1.0 eV)so that the tandem cell yielded an efficiency of 20%.The obtained results show that CZTSe solar cells prepared by a low-temperature process with in-situ alkali doping can be utilized for flexible thin-film solar cells as well as tandem device applications.

Donor-acceptor conjugated copolymer with high thermoelectric performance:A case study of the oxidation process within chemical doping

The doping process and thermoelectric properties of donor-acceptor(D-A)type copolymers are investigated with the representative poly([2,6-4,8-di(5-ethylhexylthienyl)benzo[1,2-b;3,3-b]dithiophene]3-fluoro-2-[(2-ethylhexyl)-carbonyl]thieno[3,4-b]thiophenediyl))(PTB7-Th).The PTB7-Th is doped by Fe Cl;and only polarons are induced in its doped films.The results reveal that the electron-rich donor units within PTB7-Th lose electrons preferentially at the initial stage of the oxidation and then the acceptor units begin to be oxidized at a high doping concentration.The energy levels of polarons and the Fermi level of the doped PTB7-Th remain almost unchange with different doping levels.However,the morphology of the PTB7-Th films could be deteriorated as the doping levels are improved,which is one of the main reasons for the decrease of electrical conductivity at the later stage of doping.The best electrical conductivity and power factor are obtained to be 42.3 S·cm^(-1);and 33.9μW·mK^(-1),respectively,in the doped PTB7-Th film at room temperature.The power factor is further improved to 38.3μW·mK^(-1);at 75℃.This work may provide meaningful experience for development of D-A type thermoelectric copolymers and may further improve the doping efficiency.

INFLUENCE OF DOPING COMPONENT ON THE SOL-GEL PROCESS

Si-29 and Li-7 NMR have been used to study the sol-gel process. It has been found that the doping components (such as TlNO3, LiNO2, and Cd(NO3)(2)) could promote the hydrolysis and condensation reactions and their ratio, thus they could influence the gelation time. The lithium species has been demonstrated to remain as free hydration. ions during the whole sot-gel process and not to participate in forming the inorganic network.

二硫化钼自润滑涂层性能及制备工艺的研究进展

MoS_(2)是过渡族金属二硫化物中的一员,其涂层材料因独特的层状结构而表现出优异的摩擦学性能。MoS_(2)自润滑涂层在刀具以及空间部件材料的表面减磨和保护上发挥着重要作用,但是MoS_(2)涂层对湿度的敏感性、附着力差以及耐磨寿命有限等问题限制了其应用。国内外学者在MoS_(2)涂层的摩擦学研究上做了大量工作,目前的研究重点主要是不同温度、湿度、气体介质的多环境下的摩擦学行为分析,以及通过纳米多层体系的设计实现对晶体结构的可控。本文概述了2010年以来有关MoS_(2)自润滑涂层材料的研究进展,主要综述了MoS_(2)自润滑涂层的摩擦学性能以及不同元素掺杂对其性能和结构的影响。总结了MoS_(2)涂层的组成结构、性能、制备工艺,并对其在表面润滑领域的研究和应用前景进行了展望。本文对MoS_(2)自润滑涂层的研究和工程应用具有参考意义。

磁控溅射制备铝、钛掺杂钽氮化合物薄膜的微观结构与电学性能研究

采用反应射频磁控溅射法,在Al_(2)O_(3)陶瓷基片上通过共溅射的方式成功制备了Al-TaN和Ti-TaN薄膜,并通过调节Al和Ti靶的溅射功率以实现了掺杂,研究了掺杂元素变化对薄膜微观结构和电学性能的影响。结果显示,随着掺杂元素Al和Ti的增加,TaN薄膜的粗糙度逐渐增大,晶体结构逐渐向非晶转变;Al元素掺杂时,当Al靶掺杂功率由0 W升至70 W,薄膜电阻率由0.88 mΩ·cm增至82.72 mΩ·cm;Ti元素掺杂时,当Ti靶掺杂功率由0 W升至70 W,电阻率由1.03 mΩ·cm降至0.32 mΩ·cm。此时,随着Al和Ti靶材掺杂功率由0 W升至70 W,薄膜的TCR值分别从-1313×10^(-6)℃^(-1)逐渐负偏至-3831×10^(-6)℃^(-1)和从-1322×10^(-6)℃^(-1)正偏至-404×10^(-6)℃^(-1)。该研究为溅射制备掺杂TaN薄膜提供了深刻的理论和实验基础。

Synergistic catalysis of the N-hydroxyphthalimide on flower-like bimetallic metal-organic frameworks for boosting oxidative desulfurization

Synergic catalytic effect between active sites and supports greatly determines the catalytic activity for the aerobic oxidative desulfurization of fuel oils.In this work,Ni-doped Co-based bimetallic metal-organic framework(CoNi-MOF)is fabricated to disperse N-hydroxyphthalimide(NHPI),in which the whole catalyst provides plentiful synergic catalytic effect to improve the performance of oxidative desulfurization(ODS).As a bimetallic MOF,the second metal Ni doping results in the flower-like morphology and the modification of electronic properties,which ensure the exposure of NHPI and strengthen the synergistic effect of the overall catalyst.Compared with the monometallic Co-MOF and naked NHPI,the NHPI@CoNi-MOF triggers the efficient activation of molecular oxygen and improves the ODS performance without an initiator.The sulfur removal of dibenzothiophene-based model oil reaches 96.4%over the NHPI@CoNi-MOF catalyst in 8 h of reaction.Furthermore,the catalytic product of this aerobic ODS reaction is sulfone,which is adsorbed on the catalyst surface due to the difference in polarity.This work provides new insight and strategy for the design of a strong synergic catalytic effect between NHPI and bimetallic supports toward high-activity aerobic ODS materials.

高压辅助溶胶-凝胶法制备La掺杂TiO_(2)光催化剂及其可见光降解甲基橙研究

根据溶胶-凝胶法和水热法制备TiO_(2)的优点和不足,本工作提出了一种高压辅助溶胶-凝胶法(简称HG法)可控地制备La掺杂TiO_(2)。通过该方法,可以高效制备锐钛矿相La掺杂TiO_(2),且制得样品纯度高,分散性好。通过控制La掺杂比例(0.05%、0.10%、0.15%、0.20%、0.25%,质量分数,下同),可以调控TiO_(2)禁带宽度变化(3.15~2.80 eV);其中,0.20%La掺杂TiO_(2)(0.20%La-TiO_(2))的禁带宽度可达2.80 eV。甲基橙(MO)光催化降解实验结果表明,0.20%La-TiO_(2)的光催化活性优异,其在可见光照射下160 min内对MO的降解率可达92%,是本征TiO_(2)的38.30倍;·O_(2)-是驱动0.20%La-TiO_(2)光催化降解MO的主要活性物质。本工作提出的高压辅助溶胶-凝胶法可为制备高活性TiO_(2)基光催化剂提供有益的方法及条件参考。

基于掺硼金刚石电极的工业废水处理研究进展

工业废水普遍具有可生化性差、污染物种类多、有机物含量高、难降解等特点,常规处理手段难使其达标排放。以电化学高级氧化工艺为代表的污水深度处理工艺处理污水效果显著,是近年来环境工作者的研究热点之一。掺硼金刚石(boron-doped diamond,BDD)电极理化性质优异,是目前电化学高级氧化处理废水最为理想高效的阳极材料,但关于大尺寸BDD电极的应用及处理真实工业废水的研究情况尚未及时总结归纳。本文以基于BDD电极的电化学高级氧化工艺过程为对象,对该过程涉及到的废水特点、工艺原理、BDD电极特点及制备方法、处理案例和工艺参数优化等方面的研究进展进行综述,重点聚焦不同污染体系下的大型实验室装置、中试装置和处理真实工业废水案例,总结了BDD电极材料开发情况和不同类型工艺的技术特点,探讨了工艺优化方面的研究进展和目前限制该技术大规模工业化应用的主要原因。最后对基于BDD电极的电化学高级氧化工艺应用前景和重点发展方向作出了展望。

175 dtex原液着色涤纶预取向丝的制备工艺

采用特殊工艺共混改性路线和在线添加黑母粒技术,研制开发175 dtex原液着色涤纶预取向丝(POY)。对切片和黑母粒的干燥工艺、过滤、纺丝的油嘴选型、冷却条件、卷绕成型等生产工艺进行了研究,确定了175 dtex原液着色涤纶POY的最佳制备工艺,制得的产品综合性能良好,满足后道客户加工要求。

原液着色UHMWPE纤维用炭黑色浆的制备工艺

探讨了不同种类炭黑、超分散剂的选择及用量对炭黑色浆分散稳定性的影响,优化了炭黑色浆的工艺配方,并对色浆的可纺性进行验证,分析了炭黑粒子在纤维中的粒径大小、分散状态和相容性。结果表明:以质量分数为10%的4#炭黑和质量分数为20%的超分散剂A所制备出的炭黑色浆具有良好的耐热贮存稳定性,颜料粒子尺寸可达到纳米级别,且与超高分子质量聚乙烯(UHMWPE)纺丝原液相容性好;该色浆适用于原液着色UHMWPE纤维的生产。

储能与动力电池用橄榄石型正极材料的开发及产业化进展

橄榄石型LiMePO_(4)具有成本低、循环寿命长、安全性好、环境友好等优点,成为应用最广泛的锂离子电池正极材料之一。然而,该类材料存在电子电导率低、Li^(+)扩散差、压实密度低等固有缺陷,阻碍了在储能、电动车、航空等高性能电池的拓展应用。全面总结了LiMePO_(4)正极材料的晶体结构、电子结构、产业化工艺路线、存在问题、改性策略等研究和开发进展,详细分析了掺杂改性、纳米化等提高材料电化学性能的内在机理,梳理了表面包覆、新型结构设计等对材料的保护机制,这几种手段组合使用,可有效提高LiMePO_(4)的电子电导率、离子扩散速率、压实密度,实现更高的倍率性能、更长的循环寿命和更高的能量密度电池设计。最后,对橄榄石型正极材料未来在能量密度提升、成本持续降低、面向固态电池商业化应用等方向的发展前景进行了展望。

MnZn铁氧体材料温度特性研究概要

MnZn铁氧体材料是一种品类多、应用广、用量大的软磁材料,材料的温度特性决定了其工作温度范围,因此必须严格控制其温度特性。MnZn铁氧体材料的温度特性主要取决于材料的居里温度和二峰温度,即晶体结构中亚晶格A、B位上磁性离子间超交换作用的强弱、磁晶各向异性常数K1的补偿作用。本文主要介绍了主配方、制备工艺和掺杂对于居里温度和二峰温度的影响,提出了基于居里温度和二峰温度的经验计算公式快速确定主配方的方法,指出了Co2+过补偿与Fe2+含量的关联性。

Mechanism of Phase Transformation and Formation of Barium Hexafer rite Doped with Rare-Earths in Sol-Gel Process

The phase-transformation in sol-gel preparation of barium hexaferrite and the formation of barium hexaferrite doped with La 3+ were studied by chemical p hase analysis, X-ray diffraction and infrared spectrometry analysis. The expe rimental results show that phase transformation reactions of FeCO 3, Fe 2O 3 and BaFe 2O 4, barium hexaferrite and γ-Fe 2O 3 take place in the heat tr eatment of gel. While the doping lanthanide ion replace barium ion, an equivalen t quantity of Fe 3+ are reduced to Fe 2+ to maintain the charge equili brium.

Effect of Pd doping on the acetone-sensing properties of NdFeO_3

The acetone-sensing properties of the undoped and Pd doped perovskite-type oxides NdFeO3 were investigated from room temperature to 400°C. The perovskite-type NdFeO3 was synthesized by a sol-gel method, and the dopants Pd with the content from 1wt% to 5wt% were implanted into NdFeO3 nanoparticles by thermal diffusion. X-ray diffraction （XRD） and scanning electron microscopy （SEM） techniques show that NdFeO3 is an orthorhombic structure with the average particle size of about 40 nm. A giant acetone-sensing response of 675.7 is observed when the Pd content in NdFeO3 powders is about 3wt%. The response and recovery time of the sensor to the 5×10–4 acetone gas are 16 and 1 s, respectively. At the same time, it performs a good selectivity to acetone gas and may be a new promising material candidate for the acetone-sensor development.

Solution‑Processed Transparent Conducting Electrodes for Flexible Organic Solar Cells with 16.61% Efficiency

Nonfullerene organic solar cells(OSCs)have achieved breakthrough with pushing the efficiency exceeding 17%.While this shed light on OSC commercialization,high-performance flexible OSCs should be pursued through solution manufacturing.Herein,we report a solution-processed flexible OSC based on a transparent conducting PEDOT:PSS anode doped with trifluoromethanesulfonic acid(CF3SO3H).Through a low-concentration and low-temperature CF3SO3H doping,the conducting polymer anodes exhibited a main sheet resistance of 35Ωsq−1(minimum value:32Ωsq−1),a raised work function(≈5.0 eV),a superior wettability,and a high electrical stability.The high work function minimized the energy level mismatch among the anodes,hole-transporting layers and electron-donors of the active layers,thereby leading to an enhanced carrier extraction.The solution-processed flexible OSCs yielded a record-high efficiency of 16.41%(maximum value:16.61%).Besides,the flexible OSCs afforded the 1000 cyclic bending tests at the radius of 1.5 mm and the long-time thermal treatments at 85°C,demonstrating a high flexibility and a good thermal stability.

One-time sintering process to modify xLi2MnO3(1-x)LiMO2 hollow architecture and studying their enhanced electrochemical performances

To solve the critical problems of lithium rich cathode materials, e.g., structure instability and short cycle life, we have successfully prepared a ZrO2-coated and Zr-doping xLi2MnO3·(1–x)LiMO2 hollow architecture via one-time sintering process. The modified structural materials as lithium-ion cathodes present good structural stability and superior cycle performance in LIBs. The discharge capacity of the ZrO2-coated and Zr-doped hollow pristine is 220 mAh g-1 at the 20th cycle at 0.2 C(discharge capacity loss, 2.7%)and 150 m Ah g-1 at the 100 th cycle at 1 C(discharge capacity loss, 17.7%), respectively. However, hollow pristine electrode only delivers 203 m Ah g-1 at the 20 th cycle at 0.2 C and 124 mAh g-1 at the 100 th cycle at 1 C, respectively, and the corresponding to capacity retention is 92.2% and 72.8%, respectively.Diffusion coefficients of modified hollow pristine electrode are much higher than that of hollow pristine electrode after 100 cycles(approach to 1.4 times). In addition, we simulate the adsorption reaction of HF on the surface of ZrO2-coated layer by the first-principles theory. The calculations prove that the adsorption energy of HF on the surface of ZrO2-coated layer is about-1.699 e V, and the ZrO2-coated layer could protect the hollow spherical xLi2MnO3·(1–x)LiMO2 from erosion by HF. Our results would be applicable for systematic amelioration of high-performance lithium rich material for anode with the respect of practical application.

Indium doping effect on properties of ZnO nanoparticles synthesized by sol–gel method

Pure ZnO and indium-doped ZnO(In–ZO) nanoparticles with concentrations of In ranging from 0 to 5% are synthesized by a sol–gel processing technique. The structural and optical properties of ZnO and In–ZO nanoparticles are characterized by different techniques. The structural study confirms the presence of hexagonal wurtzite phase and indicates the incorporation of In^(3+) ions at the Zn^(2+) sites. However, the optical study shows a high absorption in the UV range and an important reflectance in the visible range. The optical band gap of In–ZnO sample varies between 3.16 e V and 3.22 e V. The photoluminescence(PL) analysis reveals that two emission peaks appear: one is located at 381 nm corresponding to the near-band-edge(NBE) and the other is observed in the green region. The aim of this work is to study the effect of indium doping on the structural, morphological, and optical properties of ZnO nanoparticles.

Controlling the electronic structure of SnO_2 nanowires by Mo-doping

Mo-doped SnO2 （MTO） nanowires are synthesized by an in-situ doping chemical vapour deposition method. Raman scattering spectra indicate that the lattice symmetry of MTO nanowires lowers with the increase of Mo doping, which implies that Mo ions do enter into the lattice of SnO2 nanowire. Ultraviolet-visible diffuse reflectance spectra show that the band gap of MTO nanowires decreases with the increase of Mo concentration. The photoluminescence emission of SnO2 nanowires around 580~nm at room temperature can also be controlled accurately by Mo-doping, and it is extremely sensitive to Mo ions and will disappear when the atomic ratio reaches 0.46%.

Influence of Pr^(3+) Doping on the Microstructure of ZnO Quantum Dots

Pr3＋ doped ZnO quantum dots （QDs） were successfully synthesized by sol-gel process. X-ray diffraction （XRD） and X-ray Phtoelectron spectroscopy （XPS） were used to analyze the microstructure variation of ZnO QDs and the chemical environment of Pr3＋ with increasing Pr3＋ doping concentrations. Most of Pr3＋ ions distribute on the surface ofZnO QDs while a few of them penetrate into the ZnO lattice to substitute Zn2＋ which causes the lattice distortion and the change of the crystal size. With increasing concentration of Pr3＋ ions, the crystal size of ZnO QDs firstly increases and then decreases meanwhile the amorphization gradually increases. New Pr-O-Zn bonds formed after Pr3＋ doping and Pr3＋ ions have at least two chemical bonding environments： one is Pr-O-Zn bond and the other is Pr-O bond surrounded by oxygen vacancies.

Synthesis and Microstructure of Doped Alumina Composite Membrane by Sol-Gel Process

The supported membranes of Al 2O 3 and its modification membranes were prepared.Al 2O 3,Al 2O 3 SiO 2 TiO 2 and Al 2O 3 SiO 2 TiO 2 ZrO 2 membranes were mamufatured by the slip casting process using mixing boehmite,silicate,titania and zirconia sols under proper conditions,then the composite membrane was prepared.The structure and characteristics of the membrane were determined by XRD,SEM and AFM measurement.The conditions of preparation of the membrane are discussed.The thickness of the layer is about 1-2μm,the diameter of an average pore is 200-300nm and has a narrow pore distribution without crack forming.By changing the ratios of Al∶Si∶Ti∶Zr(mol),variations of surface pore size of Al 2O 3 SiO 2 TiO 2 ZrO 2 membrane can be gained.