Modulating J-V hysteresis of planar perovskite solar cells and mini-modules via work function engineering

Commercialization of perovskite solar cells(PSCs) requires the development of high-efficiency devices with none current density-voltage(J-V) hysteresis. Here, electron transport layers(ETLs) with gradual change in work function(WF) are successfully fabricated and employed as an ideal model to investigate the energy barriers, charge transfer and recombination kinetics at ETL/perovskite interface. The energy barrier for electron injection existing at ETL/perovskite is directly assessed by surface photovoltage microscopy, and the results demonstrate the tunable barriers have significant impact on the J-V hysteresis and performance of PSCs. By work function engineering of ETL, PSCs exhibit PCEs over 21% with negligible hysteresis. These results provide a critical understanding of the origin reason for hysteresis effect in planar PSCs, and clear reveal that the J-V hysteresis can be effectively suppressed by carefully tuning the interface features in PSCs. By extending this strategy to a modified formamidinium-cesium-rubidium(FA-Cs-Rb) perovskite system, the PCEs are further boosted to 24.18%. Moreover, 5 cm × 5 cm perovskite mini-modules are also fabricated with an impressive efficiency of 20.07%, demonstrating compatibility and effectiveness of our strategy on upscaled devices.

Establishment of Master Cell Stock and Working Cell Bank of MDCK Lines and Selection and Evaluation of the Lines as Candidate Viral Substrates for Approval Production of Combinational Canine Attenuated-live Virus Vaccines

Under the prerequisite that the incidence of cancer or tumor in negative-control nude mice inoculated subcutaneously with primary feline or canine kidney cell cultures purified in vitro at passage 3 was 0 (0/22) and 0 (0/10), respectively. The incidence of the progressively-growing malignant tumor(MT) in positive-control nude mice inoculated subcutaneously with Hela cell cultures of KB, X, or NM20/X strain was 10/ 10, 25/25 and 5/51, respectively. The results showed that the incidence of tumor in nude mice with di-and hy-perploid YB strain of MDCK cell during 17 - 23 passages, with hyper- and hypoploid KA strain of MDCK cell during 6-8 passages, with hypoploid WB strain of MDCK cell on passage 6, with hyper-and hypoploid H strain of MDCK cell during 8-24 passages was 2/24, 6/10, 5/10 and 10/15, respectively. The chromosomal analysis results showed that the ratio of difference in the rate of modal chromosome number between high(mcs + n) and lowest (mcs)passages was not more than 5 - 15% and the structure aberrations was generally 0 -3 %. These results proved that the genetic characteristics of chromosomal number of cell lines determines their tumorigenicity, but it is species-specific. MDCK line has tumorigenicity no matter what its chromosome kary-otype is, at least it has very low tumorigenicity even when its modal chromosome number is hypoploid. It is thus evident that MDCK cell of WB or H strain can be approved as substrate for the preparation of attenuated viral vaccines, but MDCK cell of YB or KA strain can not be approved as substrate for the preparation of attenuated viral vaccines.

造血干细胞移植患者重返工作的研究进展

造血干细胞移植患者重返工作岗位意味着继续保持原来的生活和日常活动,是其康复之路的里程碑,被视为回归正常生活的重要标志。文章阐述了造血干细胞移植患者重返工作的现状、影响因素及干预措施,旨在为制定我国患者重返工作策略提供参考。

氨燃料固体氧化物燃料电池性能研究进展

氨(NH_(3))是一种零碳燃料,也是富氢载体,具有较大储运优势。固体氧化物燃料电池(SOFC)是一种清洁高效发电装置,在分布式发电、热电联供、储能调峰等领域有广阔应用前景,NH_(3)可直接用作SOFC阳极燃料以实现高效、清洁、低成本发电。该文简介了质子传导型和氧离子传导型氨SOFC的工作原理,电解质、电极材料的选择以及NH_(3)在阳极的分解过程,总结了氨SOFC的实验研究现状,以单电池最大功率密度为评价指标,综述了不同电解质/电极材料、电解质厚度、工作温度、电池结构类型等因素下2种传导类型的氨SOFC的性能表现,并分析了造成电池性能差异的原因,介绍了氨SOFC目前面临的挑战。最后,对氨SOFC未来研究方向、热电联供系统的应用进行了展望。

基于工况识别的燃料电池电动汽车能量管理策略

为降低燃料电池电动汽车的氢气消耗、降低燃料电池输出功率波动率及维持电池系统的荷电状态,基于工况识别能量管理策略框架提出了一种新型转移过程工况识别方法,该方法相较于传统的工况识别方法具有识别率高、识别速度快等优点。与常见的学习向量量化神经网络工况识别方法进行对比,通过仿真分别验证了所提工况识别算法的优势,同时所提基于工况识别方法的能量管理策略在混合工况下具有更优的性能表现。

有机电子传输材料在反式钙钛矿太阳能电池中的研究现状

近年来,反式结构的钙钛矿太阳能电池凭借制备工艺简单、可低温成膜、迟滞效应低、适合与传统太阳能电池结合制备叠层器件等优点,受到了人们广泛的关注,经过几年的发展,反式钙钛矿太阳能电池的光电转化效率已从3.9%提升到25.37%。其中电子传输层作为钙钛矿太阳能电池的重要组成部分,在提取和运输载流子、阻挡空穴、调节界面能级结构和抑制电荷复合等方面起着关键性的作用。一些有机材料(富勒烯及其衍生物、苝二酰亚胺、萘二酰亚胺等)凭借容易合成和纯化、能级可调、电子迁移率高、溶解性好、化学/热稳定性良好等优势,已经广泛应用于反式钙钛矿太阳能电池。本文主要介绍了不同有机电子传输材料在反式钙钛矿太阳能电池中的研究现状,还介绍了电子传输层掺杂和界面修饰两种提升器件性能的改性手段,旨在为开发全新的有机电子传输材料提供基础性的理论指导。

Cs_(2)AgBi_(0.75)Sb_(0.25)Br_(6)钙钛矿太阳能电池的优化设计

双钙钛矿太阳能电池以其低成本、高性能、环境友好、稳定性强而备受关注.本研究使用Silvaco TCAD分析了Cs_(2)AgBi_(0.75)Sb_(0.25)Br_(6)太阳能电池的钙钛矿层厚度、能带偏移、金属电极功函数、传输层厚度及掺杂浓度与器件效率的关系,以提升器件性能.基于空穴传输层为Spiro-OMeTAD,电子传输层为ZnO的器件进行初始研究,其显示出12.66%的光电转换效率.结果表明,当钙钛矿层厚度大于500 nm时,效率趋于饱和.最佳导带偏移量为0—+0.5 eV,最佳价带偏移量为-0.1—+0.2 eV.在改变器件的电子传输层为ZnOS,空穴传输层分别为MoO_(3),Cu_(2)O和CuSCN的情况下,优化其厚度和掺杂浓度,最终空穴传输层为Cu_(2)O的双钙钛矿太阳能电池理论光电转换效率达22.85%,比目前报道的理论效率值相对提升了25.6%.此外,当金属电极功函数小于-4.9 eV时易实现最佳效率.本工作为开发高性能无铅钙钛矿太阳能电池提供了理论指导.

Effects of ORC Working Fluids on Combined Cycle Integrated with SOFC and ORC for Stationary Power Generation

The purpose of this study is to explore the effects of working fluid on conventional combined cycle integrated with pressurized solid oxide fuel cell (SOFC) and waste heat recovery organic Rankine cycle (ORC) for stationary utility power generation. The mathematical model of a natural gas fueled design configuration is developed in Matlab and Simulink and simulated with 14 working fluids. The effluent gases of SOFC undergo combustion in the combustion chamber and it is utilized in the gas turbine, steam turbine cycle and ORC. The model is compared with those found in literature and the parametric studies of temperature, flow rate, fuel utilization factor and exhaust gas on the system efficiency are examined. Results revealed that working fluids show a closely related behavior in efficiency at low pressure ratio and high flow fraction, fuel utilization, and temperature. R-123 was found to perform the best among 14 working fluids studied, yielding a system energy efficiency of 70% in the combined cycle integrated with SOFC and ORC.

Development of nickel based cermet anode materials in solid oxide fuel cells–Now and future

High temperature solid oxide fuel cell(SOFC)is the most efficient and clean energy conversion technology to electrochemically convert the chemical energy of fuels such as hydrogen,natural gas and hydrocarbons to electricity,and also the most viable alternative to the traditional thermal power plants.However,the power output of a SOFC critically depends on the characteristics and performance of its key components:anode,electrolyte and cathode.Due to the highly reducing environment and strict requirements in electrical conductivity and catalytic activity,there are limited choices in the anode materials of SOFCs,particularly for operation in the intermediate temperature range of 500–800C.Among them,Ni-based cermets are the most common and popular anode materials of SOFCs.The objective of this paper is to review the development of Ni-based anode materials in SOFC from the viewpoints of materials microstructure,performance and industrial scalability associated with the fabrication and optimization processes.The latest advancement in nano-structure architecture,contaminant tolerance and interface optimization of Ni-based cermet anodes is presented.And at the end of this paper,we propose and appeal for the collaborative work of scientists from different disciplines that enable the inter-fusion research of fabrication,microanalysis and modelling,aiming at the challenges in the development of Ni-based cermet anodes for commercially viable intermediate temperature SOFC or IT-SOFC technologies.

A Volt-Ampere Method to Estimate the Energy Efficiency Evolutions of Proton Exchange Membrane Fuel Cells along with Load and Time

The energy efficiency of proton exchange membrane (PEM) fuel cells always keeps changing with load and time. Considering cell diversity and operation variety, it’s of necessity to find a simple method to estimate the changes. The work is done with the recently developed ideal cell model on behalf of various real cells, and results in a complete set of efficiency formulae including one for the instantaneous and three for the average. The formulae stand for a volt-ampere method which permits the average efficiency to be estimated in the form of state function of cell output like the instantaneous efficiency. With cell constants for cell specialty representation in this method, the formulae can extend to cover various real cells and make it realized to broadly overview the instantaneous and average efficiency movements with both load and time throughout cell operating ranges. The energy efficiency formulization and overviews may help make clear the correlative parameters with the efficiency, help deepen acquaintance with efficiency change and assist in cell operation optimization.

Discrimination and Estimation of the Maximum Cost Performance of Proton Exchange Membrane Fuel Cell Power Generation with Seven Constants

This paper is dedicated to analytical expression of the maximum electricity-cost ratio (M-ECR) point of the proton exchange membrane (PEM) fuel cell power generation as the function of cell constants and cost constants. That is to formulize the maximum cost performance (MCP) magnitude and the optimal final operating (OFO) location in the working zone based on the five-constant ideal cell model and the two-constant cost model. The issues are well resolved by introducing the concepts of economic voltage and cost factor and describing the movement of the M-ECR point with cost factor. According to mathematical derivations, the movement can be described in the form of MCP and OFO curves. The derivations lead to a complete set of discriminants and criteria of the M-ECR point of PEM fuel cells that theoretically cover all of cell specialties and all of cost specialties. The discriminants and criteria may act as a general tool for the operation optimization of a diversity of PEM fuel cells and the economic viability estimation of the power generation.

Method of Construction of Material That Work on All the Range of Wavelengths or Frequency or Energy of Photon

The main objective of this research work is to decrease work function of any given element or compound or material. To decrease the work function of the given material we have to decrease the bandwidth between conduct band and valance band. Because according to definition of work function, the amount of energy that required the remove the electron from valance band of an atom and it is also called ionization energy. These all energies depend upon the band width that is greater than the band width greater energy required to remove the electron from the surface, and less than the band width and lesser amount of energy required to remove the electron from of materials. In this work we are trying to give an theoretical model or relation, how to decrease the work function of a material by applying external pressure on atoms and doping of the material that has screening or shielding effects. With the help of this model we can increase the efficiency of material used in solar cell that is cell work for all range of frequencies and by construction material bases on this we can increase the efficiency of solar cell or any type of material working solar cell principle.

A highly-efficient concentrated perovskite solar cell-thermoelectric generator tandem system

Concentrated photovoltaic(CPV)has been identified as an effective method to further enhance the efficiency of photovoltaic cells.Previous studies on CPV mainly focused on III-V multi-junction cells.Nevertheless,Ⅲ-ⅤCPV technology is mainly used in niche applications due to its high cost.Here,we use metal-halide perovskite solar cell(PSC)to demonstrate a concentrated photovoltaic-thermoelectric tandem device.The thermoelectric generator(TEG)is utilized to reduce the effect of heat generation under concentrated solar irradiance.Our tandem system achieved a peak power conversion efficiency(PCE)of 25.0%at a solar concentration of 3 suns.This efficiency exceeded that of the single PSC by~4.7%.Our work proves that by controlling the heat flow in concentrated PSC-TEG tandem system,the redundant heat produced by upper PSC can be effectively reused.This tandem structure provides a promising approach to improve the efficiency and stability of PSC under low-concentrated solar irradiation.

噪声性听力损失与血白细胞计数的相关性研究

目的分析噪声性听力损失与血白细胞计数的关联性,以期为职业性噪声性健康损害提供新的人群研究证据。方法2009年委托广州市职业病防治院开展职业健康检查的工厂157家,噪声作业工人14396名,结合职业健康检查,选择其中同时检查血常规、空腹血糖、血脂和纯音听力的噪声作业人员3508人为研究对象,其中男2969人,女539人。同时调查收集其一般信息、职业接触史、听觉系统疾病史等资料。噪声性听力损失与白细胞计数的相关性分别采用t检验和协方差分析,与白细胞偏高的相关性采用logistic回归分析。结果两独立样本t检验和调整性别、年龄、接噪工龄、空腹血糖、总胆固醇和三酰甘油后的协方差分析结果均提示,噪声性听力损失组白细胞计数均高于听力正常组[(7.15±0.06)×10^(9)/L比(6.91±0.03)×10^(9)/L、(6.94±0.07)×10^(9)/L比(6.79±0.04)×10^(9)/L],差异均有统计学意义(t=-3.912、P<0.001,F=5.618、P=0.018);调整性别、年龄、接噪工龄、空腹血糖、总胆固醇和三酰甘油后,logistic回归分析结果显示,相对于听力正常组,噪声性听力损失组白细胞偏高风险增加32%,比值比为1.32(95%可信区间:1.03~1.70,P<0.05)。结论噪声性听力损失与白细胞计数升高独立相关,提示噪声暴露可能诱发机体出现慢性炎性反应。

IEC/TC108标准解释组发布的信息文件

介绍IEC/TC108近期发布的6个与标准解释相关的INF文件内容,澄清了标准中特定要求的适用性,确认了标准中的测试方法,解释了合格判据。帮助相关人员正确地理解标准中安全评估的要求,以及部分安全评估测试的细节。

基于多智能体强化学习的异构网络CRE偏置动态优化算法

为应对无线网络用户激增导致的高吞吐量需求,针对宏微异构网络干扰场景,提出一种基于多智能体强化学习的小区范围扩展(CRE)偏置动态优化算法。基于协作多智能体强化学习的值分解网络框架,通过合理利用并在微微基站间交互系统内用户分布及其所受干扰水平,实现所有微微基站的个性化CRE偏置值在线本地化决策。仿真结果表明,与CRE=5 dB、分布式Q-Learning算法相比,所提算法在提高系统吞吐量、均衡各基站吞吐量及改善边缘用户吞吐量方面具有明显优势。

双钙钛矿Cs_(4)CuSb_(2)Cl_(12)纳米晶无铅太阳电池的数值研究

提出一种结构为FTO/TiO_(2)/Cs_(4)CuSb_(2)Cl_(12)/Au的无铅、无空穴传输层钙钛矿太阳电池。该电池以Cs_(4)CuSb_(2)Cl_(12)双钙钛矿纳米晶为光活性层,FTO和Au为接触电极,TiO_(2)为电子传输层。数值仿真结果表明,当Cs_(4)CuSb_(2)Cl_(12)厚度和缺陷态密度分别为1050 nm和1012 cm^(-3),TiO_(2)掺杂浓度和电子亲和势分别为1019 cm^(-3)和3.9 eV,界面缺陷态密度为1013 cm^(-3),背电极功函数为5.1 eV,工作温度为300 K时,电池性能得到提升,优化后电池的Voc、Jsc、FF以及η_(PCE)分别提升了6.9%,39.5%,12.0%以及67.7%。这为新型无铅无空穴传输层钙钛矿太阳电池的研究提供了一定的借鉴思路。

造血干细胞移植幸存者重返工作体验的质性研究

目的了解经历造血干细胞移植的血液系统恶性肿瘤幸存者重返工作的体验与感受,旨在为造血干细胞移植幸存者再就业提供参考依据。方法采用描述性质性研究方法,于2021年6月至2022年4月,基于病历记录,目的抽样曾在浙江省1家三级甲等医院接受造血干细胞移植后的13例幸存者进行半结构式访谈,通过传统内容分析法进行资料分析、归纳及提炼主题。结果造血干细胞移植幸存者重返工作体验可归纳为4个主题,分别为:重返职场的时机、回归职场考虑的就业类别、再次踏入职场工作付出改变、返回职场的益处。结论造血干细胞移植幸存者重返职场需求与体验复杂,应从多方面对幸存者重返职场体验予以关注和支持,以提高幸存者重返职场的应对能力,改善其工作体验。

电活性紫罗烯有机光伏界面材料的研究进展

有机太阳能电池因具有质轻、柔性及可印刷制备等优点而受到广泛关注.调控和优化金属电极与有机半导体活性层之间的软/硬材料界面是有机太阳能电池界面工程的前沿课题,其核心是新型界面材料的设计合成与器件集成.紫罗烯聚合物是一类新兴的非共轭聚合物电解质界面材料,其离子部分位于聚合物主链.相对于传统共轭聚合物电解质,紫罗烯聚合物合成方法简单,条件温和而且绿色,具有更高的离子浓度和更强的界面诱导极化能力,适用于有机太阳能电池的界面修饰.电活性紫罗烯的最新研究进展激发了科研人员探索这种新型聚合物在有机电子器件中应用的兴趣.本综合评述介绍了电活性紫罗烯聚合物的分子设计与合成,讨论了紫罗烯聚合物修饰金属电极的机理和作用,以及其电荷传输性能和界面能级调控能力.

用于晶硅异质结太阳电池的透明导电薄膜研究进展

提升晶硅异质结(HJT)太阳电池的电流有望进一步提高电池效率,透明导电氧化物薄膜(TCO)是影响HJT太阳电池电流的重要功能层。该文首先介绍了TCO薄膜的自身特性,包括掺杂元素和掺杂比例、制备技术对薄膜特性的影响。同时总结了薄膜特性对HJT太阳电池性能的影响。最后阐述了TCO薄膜应用的最新进展及发展趋势,增加盖帽层或多层TCO薄膜有望改善薄膜整体特性及电池性能。以期指导TCO薄膜特性的优化,从而进一步提高HJT太阳电池效率,加快HJT太阳电池产业化进程。