Boosting High-Voltage and Ultralong-Cycling Performance of Single-Crystal LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2) Cathode Materials via Three-in-One Modification

LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2) is extensively researched as one of the most widely used commercially materials for Li-ion batteries at present.However,the poor high-voltage performance(≥4.3 V)with low reversible capacity limits its replacement for LiCoO_(2) in high-end digital field.Herein,three-in-one modification,Na-doping and Al_(2)O_(3)@Li_(3)BO_(3) dual-coating simultaneously,is explored for single-crystalline LiNi_(0.5)Co_(0.2)Mn_(0.3)O_(2)(N-NCM@AB),which exhibits excellent high-voltage performance.N-NCM@AB displays a discharge-specific capacity of 201.8 mAh g^(−1) at 0.2 C with a high upper voltage of 4.6 V and maintains 158.9 mAh g^(−1) discharge capacity at 1 C over 200 cycles with the corresponding capacity retention of 87.8%.Remarkably,the N-NCM@AB||graphite pouch-type full cell retains 81.2% of its initial capacity with high working voltage of 4.4 V over 1600 cycles.More importantly,the fundamental understandings of three-in-one modification on surface morphology,crystal structure,and phase transformation of N-NCM@AB are clearly revealed.The Na+doped into the Li–O slab can enhance the bond energy,stabilize the crystal structure,and facilitate Li+transport.Additionally,the interior surface layer of Li^(+)-ions conductor Li_(3)BO_(3) relieves the charge transfer resistance with surface coating,whereas the outer surface Al_(2)O_(3) coating layer is beneficial for reducing the active materials loss and alleviating the electrode/electrolyte parasite reaction.This three-in-one strategy provides a reference for the further research on the performance attenuation mechanism of NCM,paving a new avenue to boost the high-voltage performance of NCM cathode in Li-ion batteries.

Al_(2)O_(3)改性等离子喷涂-物理气相沉积热障涂层的异物损伤行为及失效机理

由外来异物损伤引起的颗粒冲蚀是制约热障涂层使用寿命的重要因素。为了提高等离子喷涂-物理气相沉积(PS-PVD)热障涂层的耐冲蚀性能,采用磁控溅射和真空热处理在PS-PVD喷涂的7YSZ热障涂层表面制备一层致密的α-Al_(2)O_(3)。系统研究热障涂层的异物损伤行为,并采用第一性原理计算对α-Al_(2)O_(3)/c-ZrO_(2)界面进行研究。结果表明,PS-PVD、大气等离子喷涂(APS)和电子束-物理气相沉积(EB-PVD)热障涂层的冲蚀质量损失率分别为324、248和139μg/g,而Al_(2)O_(3)改性的PS-PVD热障涂层的冲蚀质量损失率降至199μg/g。此外,在Al_(2)O_(3)/ZrO_(2)-O的顶部构型模型中观察到的界面结合能最高(3.88 J/m^(2)),远高于ZrO_(2)/Ni(2.011 J/m^(2)),使界面结合性能得以提高。

表面疏油Al_(2)O_(3)陶瓷膜的制备及表征

以氨水和无水氯化铝为原料,采用溶胶-凝胶法在SiC基体上制备了Al_(2)O_(3)陶瓷膜,以氟碳表面活性剂Capstone FS-50为改性剂,通过真空浸渍法对所制备的Al_(2)O_(3)膜进行疏油改性。结果表明,制备的膜孔径分布均匀,表面无裂纹和针孔缺陷,Capstone FS-50改性前后膜通量和孔结构几乎不变。Capstone FS-50能均匀附载在Al_(2)O_(3)膜表面,使其展现出良好的疏油性能(表面接触角最大为130°),在温度低于200℃时,改性陶瓷膜仍具有较好的疏油性和良好的耐磨性能。

Triple the steady-state reaction rate by decorating the In_(2)O_(3)surface with SiO_(x)for CO_(2)hydrogenation

Indium oxide(In_(2)O_(3)),as a promising candidate for CO_(2)hydrogenation to C_(1) products,often suffers from sintering and activity decline,closely related to the undesirable structural evolution under reaction conditions.Based on the comprehension of the dynamic evolution,this study presents an efficient strategy to alleviate the agglomeration of In_(2)O_(3)nanoparticles by the surface decoration with highly dispersed silica species(SiO_(x)).Various structural characterizations combined with density functional theory calculations demonstrated that the sintering resulted from the over-reduction,while the enhanced stability originated from the anchoring effect of highly stable In-OSi bonds,which hinders the substantial formation of metallic In(In^(0))and the subsequent agglomeration.0.6Si/In_(2)O_(3)exhibited CO_(2)conversion rate of10.0 mmol g^(-1)h^(-1)at steady state vs.3.5 mmol g^(-1)h^(-1)on In_(2)O_(3)in CO_(2)hydrogenation.Enhanced steady-state activity was also achieved on Pd-modified catalysts.Compared to the traditional Pd/In_(2)O_(3)catalyst,the methanol production rate of Pd catalyst supported on 0.6Si/In_(2)O_(3)was enhanced by 23%,showing the potential of In_(2)O_(3)modified by SiO_(x)in serving as a platform material.This work provides a promising method to design new In_(2)O_(3)-based catalysts with improved activity and stability in CO_(2)hydrogenation.

构筑功能性Bi_(2)O_(3)光催化材料的研究进展

随着世界经济的快速发展,出现了严重的能源短缺和环境危机,光催化技术是缓解该问题的有效方案。Bi_(2)O_(3)具有独特的层状结构和较窄的禁带宽度、潜在的可见光驱动光催化性能,逐渐成为环境能源科学领域的研究热点之一。该文概述了Bi_(2)O_(3)光催化材料的制备方法,重点介绍了气相反应法、液相反应法、固相反应法和其他方法的研究现状;总结了Bi_(2)O_(3)光催化材料构筑策略、去除成效及主要机理;阐述了Bi_(2)O_(3)光催化材料在光催化水环境处理、水分解制氢、固氮脱硫、杀菌消毒、二氧化碳还原、电极与超级电容器领域的应用;最后,提出了Bi_(2)O_(3)光催化材料存在的问题,并对其未来发展方向进行了展望。

镁改性对Ni-Mo/Al_(2)O_(3)体系催化剂烯烃选择性能的影响

为探究助剂改性对催化加氢催化剂烯烃芳烃选择性能的影响,采用超声辅助沉淀法制备出不同镁含量的系列Mg-Al_(2)O_(3)载体,后采用等体积浸渍法制备出Ni-Mo/Mg-Al_(2)O_(3)催化剂,并对催化剂进行了XRD、BET、XPS、NH_(3)-TPD和H_(2)-TPR等表征分析。结果显示,引入的镁助剂与氧化铝载体有效结合改善了催化剂的孔道织构特性,降低了催化剂的酸性,改善了活性组分的分布形态,促进了更多活性更高的NiMoS-Ⅱ型相的生成。在固定床加氢反应器中,使用催化裂解汽油(DCC汽油)作为评价原料,探究催化剂的加氢脱硫(HDS)、加氢脱氮(HDN)性能及催化剂对芳烃和烯烃选择性的影响。结果表明,经过镁助剂改性的催化剂,产物加氢脱硫脱氮率能达到99.9%,并且当镁助剂引入量为3%(质量分数)时,烯烃饱和率大于99%,芳烃损失率仅为7.2%。镁助剂的引入有效提高了催化剂的加氢脱硫脱氮能力,通过对Mg助剂含量的控制可以调变催化剂的烯烃芳烃选择性能,对目前催化加氢催化剂选择性能的提升具有较大的研究意义。

Al_(2)O_(3)修饰液改性多孔陶瓷的制备及材料性能研究

这是一篇陶瓷及复合材料领域的论文。为了提高粉煤灰基多孔陶瓷材料的性能,利用Al_(2)O_(3)修饰液对样品进行表面处理,并对其开展物理、力学性能、吸附效果和微观实验。结果表明:烧结温度越高,多孔陶瓷的气孔率与吸水率越小,强度和表观密度越大,在1100℃的温度条件下,多孔结构烧结成型的效果较佳;当修饰液的浓度从0增至50 mol/L,多孔陶瓷的饱和吸附率增加了4.5倍左右,同时密实度和强度也显著提高;氧化铝修饰液的表面改性效应对钙长石晶体的形成起到促进作用,使得孔陶瓷的强度与吸附性能显著提升。

Ag/SiC和Ag/Al_(2)O_(3)-SiC催化剂的乙烯环氧化催化性能

制备了高分散的Ag/SiC和Al_(2)O_(3)修饰的Ag/SiC催化剂,并用于乙烯环氧化反应。结果显示,Al_(2)O_(3)修饰的Ag/SiC催化剂对乙烯的转化率显著提高,但环氧乙烷的选择性急剧降低。进一步研究发现,在反应过程中乙烯吸附在SiC表面;O_(2)在Ag表面解离后,活性O物种溢流到SiC表面参与环氧化反应。Al_(2)O_(3)修饰后改变了Ag的电子性质,抑制了活性O物种在SiC表面的迁移,导致反应性能的改变。该工作为乙烯环氧化催化剂的设计提供了一定的参考。

Nano-Al_(2)O_(3)改性石蜡相变微胶囊的热性能及作用机理

以石蜡为芯材,Nano-Al_(2)O_(3)改性三聚氰胺脲醛树脂为壁材,利用原位聚合法制备导热增强型石蜡相变微胶囊。采用ESEM、HotDisk、DSC、TG、FT-IR、EDS测试表征其微观形貌、导热系数、储热性能、热稳定性及化学结构。结果表明:石蜡相变微胶囊呈球状颗粒且分散均匀,相变温度30℃~31℃,热稳定性能良好。掺10%的Nano-Al_(2)O_(3)时,导热系数提高了56.8%。Nano-Al_(2)O_(3)均匀分布在壁材中,形成网状结构,使微胶囊内部与表面形成传热通道,从而赋予石蜡相变微胶囊的高导热性能和高热传输效率。

Al_(2)O_(3)界面修饰单向纤维C/C复合材料组织结构及其力学性能

为了缓解C/C复合材料脆性,利用勃姆石溶胶对单向碳纤维预制体进行处理,在纤维表面制备了Al_(2)O_(3)涂层.使用自制的热梯度化学气相沉积(TG-CVI)设备对预制体进行致密化,得到致密的C/C复合材料.通过高温热处理进一步调节界面的结合强度和基体碳的石墨化程度.利用排水法测试复合材料的密度,万能材料试验机测试其拉伸性能,采用可视化石墨烯片层技术(VGT)对试样进行处理,使用偏光显微镜(PLM)、扫描电子显微镜(SEM)、X-射线衍射(XRD)分别研究复合材料的微观组织、界面和断面形貌、以及物相组成.结果表明:涂覆Al_(2)O_(3)涂层的C/C复合材料在沉积后期转变为粗糙层(RL)织构.经过高温热处理后,碳基体的石墨化程度提高,改变了C/C复合材料的断裂机制.由复合材料最初的脆性断裂向拟延性转变,延伸率提高.C_(f)(Al_(2)O_(3))/C-3样品的峰值应力达到了77.3 MPa,延伸率达到了15%.

钐掺杂改性γ-Al_(2)O_(3)粉体的热稳定性研究

以硝酸铝(Al(NO_(3))_(3)·9H_(2)O)为氧化剂,甘氨酸(C_(2)H_(5)NO_(2))为还原剂,硝酸钐(Sm(NO_(3))_(3)·6H_(2)O)为改性剂,通过溶液燃烧法合成了γ-Al_(2)O_(3)粉体。采用XRD、SEM、BET、TG-DTG等手段对产物进行表征,并分析探讨了焙烧温度、改性剂添加量对产物物相的影响。实验结果表明:在硝酸铝(Al(NO_(3))_(3)·9H_(2)O)与甘氨酸(C_(2)H_(5)NO_(2))的物质的量之比为3∶5,改性剂Sm(NO_(3))_(3)·6H_(2)O添加量为1%,焙烧温度为1025℃,焙烧时间为4 h的条件下可以制备具有较高热稳定性的γ-Al_(2)O_(3)粉体,且该粉体具有比表面积较大、结构稳定等特点,可以作为催化剂的载体。

高活性耐硫MoO_(3)改性NiO-Al_(2)O_(3)催化剂用于焦炉煤气甲烷化

采用双水解共沉淀法结合浸渍法合成了系列的MoO_(3)改性的xMoO_(3)/Ni O-Al_(2)O_(3)催化剂(x%为MoO_(3)的质量分数),利用固定床装置对催化剂的甲烷化反应活性和耐硫性能进行评价,并对失活前后催化剂进行详细表征。结果表明,随着MoO_(3)含量的升高MoO_(3)改性后的催化剂甲烷化活性有所下降,但MoO_(3)的掺杂显著提升了催化剂的耐硫性能。催化剂低温甲烷化活性降低的原因在于MoO_(3)负载量的增加降低了催化剂的活性比表面积,但MoO_(3)的引入也为硫化物提供了一个竞争吸附位点,进而延缓了活性位点的硫中毒过程。当MoO_(3)负载量(质量分数)为12.5%时,12.5MoO_(3)/Ni O-Al_(2)O_(3)催化剂在143 mg·m^(-3)H_(2)S/H_(2)气氛下运行时间长达7 h,远高于其他催化剂。12.5MoO_(3)/Ni O-Al_(2)O_(3)催化剂吸收硫的量(质量分数)达到0.71%,是Ni O-Al_(2)O_(3)催化剂硫吸附量的1.48倍。XPS表征进一步发现12.5MoO_(3)/Ni O-Al_(2)O_(3)催化剂表面生成的Mo S2最多,这说明在此负载量下Mo优先吸附了更多的硫而保护了活性位点。此外,MoO_(3)负载量为12.5%时,MoO_(3)在催化剂表面接近单层分散阀值,当竞争吸附发生时,为硫化物提供更多的吸附位点。

Bi_(2)O_(2)CO_(3)光催化剂的改性及性能研究

采用一次水热法通过改变溶剂来调控Bi_(2)O_(2)CO_(3)纳米片的厚度,构建具有不同比表面积、官能团接枝、氧空位的绣球花状Bi_(2)O_(2)CO_(3)以提高其光激发载流子的分离效率。采用X射线粉末衍射、扫描电子显微镜、透射电子显微镜和X射线光电子能谱等手段对其进行结构和形貌表征。并通过对盐酸四环素溶液、甲基橙溶液和双酚A溶液进行吸附降解实验,研究了催化剂的光催化降解性能。结果表明,经乙二醇溶剂调控改性后具有超薄结构的Bi_(2)O_(2)CO_(3)材料(BiC-G)在10 min内,对盐酸四环素溶液、甲基橙溶液和双酚A溶液有机污染物的吸附效率分别达到81.1%、60.5%和25.4%,是经去离子水调控合成样品(BiC-W)的2.32倍、5.5倍和3.18倍;且经光照后,降解率分别达到86.3%、82.6%和49.9%,是BiC-W的2.12倍、4.86倍和1.96倍。改性后的催化剂因比表面积提高、官能团接枝和氧空位的产生从而提供更多的吸附位点,是光催化性能提升的主要原因。

Al_(2)O_(3)/LiAlO_(2)表面包覆改性LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)三元正极材料研究

三元正极材料因比容量高、成本低和较为环保而备受研究者的关注和青睐,但其循环稳定性与倍率性能较差。通过固相包覆法制备了纳米Al_(2)O_(3)以及LiAlO_(2)包覆的LiNi_(1/3)Co_(1/3)Mn_(1/3)O_(2)材料,对所制备材料的结构及形貌进行系统表征,结果表明,两种包覆均在保持正极材料结构的基础上成功形成了表面包覆层。电化学性能测试表明,用质量分数为1%的Al_(2)O_(3)包覆时,其初始放电容量从原始材料的159 mA·h·g^(-1)提升至162.57 mA·h·g^(-1),循环35次的容量保持率由74.38%提升至94.89%;用质量分数为3%的LiAlO_(2)包覆时,初始放电比容量提升至164.85 mA·h·g^(-1),前35次的容量保持率较未包覆材料均有所提高。此外,经包覆后正极材料循环性能和倍率性能均有所提高,电压衰减和电化学阻抗降低,说明Al_(2)O_(3)或LiAlO_(2)包覆均能提高正极材料的离子电导率和结构稳定性。

Preparation of B_(2)O_(3)/SBA-15 and Application as Matrix Component in Nickel-Tolerant Fluid Catalytic Cracking Catalyst

Fluid catalytic cracking(FCC)is still a key process in the modern refining industry,in which nickel contamination of the FCC catalyst can significantly increase the dry gas and coke yields and thus seriously affect the stability of the FCC unit.Therefore,in this work,B_(2)O_(3)-modified SBA-15 molecular sieves(B_(2)O_(3)/SBA-15)with different B_(2)O_(3) contents were prepared,characterized,and further used as matrix component in the preparation of Ni-tolerant FCC catalyst.The characterization results indicated that the B_(2)O_(3)/SBA-15 samples possessed excellent Ni passivation ability and kept the characteristic structure of the parent SBA-15 such as highly ordered mesopores,large surface area,and high pore volume,which enabled the B_(2)O_(3)/SBA-15 sample to greatly improve the Ni tolerance of the prepared FCC catalyst.The heavy oil catalytic cracking tests indicated that,under the same Ni contamination conditions,the dry gas,coke,and heavy oil yields of the FCC catalyst containing B_(2)O_(3)/SBA-15 decreased by 0.92%,1.65%,and 1.26%,respectively,compared with those of conventional FCC catalyst,while the total liquid yield increased by 3.83%.

α-Fe_(2)O_(3)光阳极光电化学性能改进策略的研究进展

阐述了赤铁矿光阳极材料在光电化学分解水方面的最新研究进展,总结了改善赤铁矿光阳极光电化学性能的一般策略和新兴策略。一般改性策略包括:形貌控制、杂质掺杂、异质结构构建、表面修饰等;新兴策略包括:超薄膜共振光捕获、表面等离子体共振等。重点讨论了负载钝化层和析氧助催化剂两种表面修饰方法对提高赤铁矿光阳极光电化学水氧化性能的作用。展望了赤铁矿光电极材料开发当前面临的挑战及其在光电化学分解水方面的发展前景。

硬脂酸表面修饰纳米Sb_(2)O_(3)增强PBT基复合材料

通过机械球磨法,利用硬脂酸对纳米Sb_(2)O_(3)进行表面改性,并采用熔融共混法制备了纳米Sb_(2)O_(3)与聚对苯二甲酸丁二醇酯(PBT)的复合材料,通过X射线衍射仪(XRD)、傅里叶红外光谱仪(FT-IR)、热重分析仪(TG)对硬脂酸表面修饰前后纳米Sb_(2)O_(3)颗粒的晶型结构、表面官能团、表面包覆量特性进行表征.并通过扫描电子显微镜(SEM)和力学性能测试等手段表征了复合材料的力学性能,对比分析了改性与未改性纳米Sb_(2)O_(3)与PBT基复合材料力学性能的影响机制.结果表明,硬脂酸以化学键的作用方式成功包覆在纳米Sb2O3颗粒表面,其改性的纳米Sb2O3颗粒的晶型结构没有发生变化;随着纳米Sb_(2)O_(3)质量分数的增加,复合材料的拉伸屈服强度呈现先增大后减小的趋势,当纳米Sb2O3质量分数为3%时,复合材料表现出优异的综合性能.

Recent advances in structural modification on graphitic carbon nitride(g-C_(3)N_(4))-based photocatalysts for high-efficiency photocatalytic H_(2)O_(2)production

To date,extensively high demand for hydrogen peroxide(H_(2)O_(2))has been predominantly supplied by the anthraquinone process for several worldwide applications,encompassing wastewater treatment,environmental remediation,and chemical synthesis.However,the compacted manufacturing,massive energy input and the release of tremendous wastes have restricted commercialization feasibility.Regards to mitigate such issues,the photocatalytic H_(2)O_(2)production by utilizing g-C_(3)N_(4)catalysts has endowed a greener,sustainable and promising alternative,considering that it involves water and oxygen as reactants in the present of sunlight as energy input.Herein,we have manifested a comprehensive overview of the research progress for g-C_(3)N_(4)-based semiconductors for photocatalytic H_(2)O_(2)generation.This review has systematically elucidated state-of-the-art development of different modifications on g-C_(3)N_(4)to unravel the fundamental mechanism of H_(2)O_(2)evolution via oxygen reduction reaction(ORR)and water oxidation reaction(WOR).In addition,the contribution made by vacancy introduction,doping,heterogenization,and co-catalyst passivation with respect to photoefficiency enhancement have been clarified.Furthermore,the current challenges and perspective of future development directions on photocatalytic H_(2)O_(2)production have also been highlighted.As such,g-C_(3)N_(4)stands as the next step toward advancement in the configuration and modulation of high-efficiency photocatalysts.

Li_(2)ZrO_(3)包覆富锂Li_(1.20)Mn_(0.44)Ni_(0.32)Co_(0.04)O_(2)改性正极材料的制备及电化学性能研究

富锂层状氧化物以其高放电比容量和低成本优势而成为重要的锂离子电池正极材料。将拥有供锂离子迁移的三维通道的Li_(2)ZrO_(3)导体包覆在富锂层状正极材料Li_(1.20)Mn_(0.48)Ni_(0.24)Co_(0.08)O_(2)表面,期望改善其综合电化学性能。系统地研究了Li_(2)ZrO_(3)包覆及不同包覆量对Li_(1.20)Mn_(0.48)Ni_(0.24)Co_(0.08)O_(2)的晶体结构,颗粒形貌和电化学性能影响。电化学测试结果证实Li_(2)ZrO_(3)包覆改性能够显著提高Li_(1.20)Mn_(0.48)Ni_(0.24)Co_(0.08)O_(2)的首次库伦效率,高倍率和低温放电能力,以及循环稳定性。

Al_(2)O_(3)基底上Zn/HZSM-5分子筛膜的制备与甲醇芳构化性能

通过在Al_(2)O_(3)微球上原位生长HZSM-5分子筛膜并负载Zn后获得了宏观颗粒尺寸2~3mm的Zn/HZSM-5/Al_(2)O_(3)分子筛,研究了其甲醇芳构化性能。结果表明:HZSM-5均匀包覆在Al_(2)O_(3)表层,并呈现出B酸为主的表面酸性质,该催化剂实现了98%以上的甲醇转化率以及35.25%的芳烃选择性。引入Zn后,在保持98%以上甲醇转化率的同时,芳烃选择性达到42.60%。Zn/HZSM-5/Al_(2)O_(3)中ZnOH~+物种提供的L酸性中心,与分子筛的B酸中心协同作用,使催化剂的芳构化性能得到了显著提高。