A Hierarchically Porous ZIF@LDH Core-Shell Structure for High-Performance Supercapacitors

Designing nanocomposites with good electrochemical properties is one of the challenges in constructing supercapacitors. Adjustable metal-organic frameworks (MOFs) have potential research value in improving charge storage and transfer due to their multi-porosity. Moreover, MOFs can serve as a precursor to various derivatives. Herein, a series of core-shell structures with macro-microporous ZIF-67 (M-ZIF-67) as the core and layered double hydroxide (LDH) as the shell were synthesized based on polystyrene spheres (PSs) template via a simple ion etching method. As a result, the sample of M-ZIF-67@LDH4 shows a specific capacitance of 597.6 F g⁻¹ at 0.5 A g⁻¹ and a high rate retention of 92% at 3 A g⁻¹.     

Synchronous Electrocatalytic Design of Architectural and Electronic Structure Based on Bifunctional LDH-Co3O4/NF toward Water Splitting

The rational design of highly efficient bifunctional electrocatalysts for water splitting is extremely urgent for application in sustainable energy conversion processes to alleviate the energy crisis and environmental pollution. In this work, through simple deposition of layered double hydroxides (LDH) on Co₃O₄/NF (NF=nickel foam) nanosheets arrays, hierarchical Co³⁺-rich materials based on LDH-Co₃O₄/NF are prepared as highly active and stable electrocatalysts for water splitting. The NiFe-LDH-Co₃O₄/NF demonstrates excellent electrochemical activity with an overpotential of 214 mV for the OER and an overpotential of 162 mV for the HER at 10 mA cm⁻². Such a performance is attributed to the optimized electronic states with a high concentration of Co³⁺, which improves the intrinsic activity, and the sheet-on-sheet hierarchical structure, which increases the number of active sites. The unique synchronous design of both the architectural and electronic structure of nanomaterials can simultaneously accelerate the reaction kinetics and provide a more convenient charge transfer path. Therefore, the strategy reported herein may open a new pathway for the design of excellent electrocatalysts for water splitting.     

In Quest of Environmentally Stable Perovskite Solar Cells: A Perspective

Inorganic-organic halide perovskites pose a once-in-a-generation opportunity to revolutionize photovoltaic technology as they are excellent semiconductor candidates with a combination of many desirable attributes. Specifically, halide perovskite solar cells with extremely high device efficiency are easily fabricated and present great promise for commercialization in the near future. However, their non-ideal environmental stability under real operating conditions can limit their further development. Both the academic and industrial research communities have been devoting considerable effort to overcome this critical deficiency through material and device engineering. Significant progress has been reported in this direction, and in this perspective, we review the recent strategies that promise to improve solar cell stability focusing on two interwoven topics. The first one is the development of environmentally stable semiconductor materials, while the second one is dedicated to the reported progress in improving solar cell device stability. Although, the currently adopted methods have not resolved the above problems, yet they build a foundation of principles for future advances to overcome them. In this regard, we believe commercial perovskite-related photovoltaics might indeed be on the horizon, not only replacing the currently commercially available ones, but also improving them.     

二维层状离子型纳米材料在化妆品领域的应用进展

二维层状离子型纳米材料具有独特的结构和界面性能,使其在透皮吸收、防晒、活性物的靶向传递、构建稳定的纳米微胶囊等功效中显示出极大的优势,在化妆品行业中具有良好的市场前景。 该类化合物根据层板电荷不同可分为阳离子型粘土材料和阴离子型水滑石类材料。 基于近年来国内外对二者的研究报道和实验研究成果,本文综述了二维离子型纳米材料的特点、性能及其在化妆品领域的应用历史和发展现状,并进一步展望了该类材料在化妆品领域中的应用前景。     

ZnO/RGO复合材料的结构及其光催化性能研究

本实验以ZnSO₄和氧化石墨(Graphite Oxide,GO)原料,在低温环境下(60 ℃)制备了层状ZnO/RGO(ZnO/Reduced Graphite Oxide)复合材料。通过对ZnO/RGO复合材料进行XRD、FTIR、XPS和FE-SEM等测试,表征了产物的晶相结构、界面状况及微观形貌特征。氧化石墨在与ZnO的复合反应过程中其活性基团消失或减弱,氧化石墨自身被还原为一种类石墨物质(Reduced GO,RGO);GO的预处理过程对产物的形貌有较大影响,采用稀碱溶液对石墨的剥离处理有利于产物的层状结构形成。本文还以甲基橙为目标降解物,考察了不同条件下所得催化剂的紫外光催化性能。研究表明,ZnO/RGO纳米复合材料大大提高了ZnO紫外光催化活性。光致发光谱(PL)显示,ZnO/RGO复合材料的荧光发射峰强度比纯ZnO有较大降低,说明ZnO的光激发电子在氧化石墨的还原产物RGO和ZnO纳米颗粒之间存在界面电子转移效应,因而抑制了ZnO中光生电子-空穴对的复合,从而提高了ZnO的光催化性能。     

大学物理实验分层次教学与创新能力的培养

建立现代物理实验教学新体系是大学物理实验教学改革的必然趋势,阐述了分层教学法在大学物理实验教学中应用的必要性,分析了分层教学法的优势,探索了更好地发挥分层教学法的方法和原则,从而使大学物理实验在培养学生的动手能力和创新能力方面起到了重要的作用。     

11-钨铜三元杂多阴离子层状材料的制备及其光催化性能

采用离子交换法将杂多酸盐K₈［Co(H₂O)W₁₁CuO₃₉］镶嵌到Zn₂Al粘土当中,制得层状材料LDH［Co(H₂O)W₁₁CuO₃₉］^8-(2),其结构经IR, XRD, SEM, EDS和N₂吸附-脱附与孔径分析表征。并以2为光催化剂,研究其对孔雀石绿溶液光降解的催化活性,最佳实验条件为：孔雀石绿溶液的初始浓度为20 mg·L^-1,初始pH为2, 2用量为0.08 g,脱色率98.32%。     

含三聚氰胺多孔材料分层复合介质吸声特性*

三聚氰胺泡沫材料是一种具有高开孔率的多孔材料,具备优良的吸音、防火隔热及环保性能,可以作为吸声材料与弹性板、空腔介质形成复合结构,在建筑、航空、交通工具等工程领域有广泛的应用。该文基于Biot理论和分层介质在交界面处的不同边界条件,建立非均匀复合介质背衬刚性壁面结构的理论声学模型,详细分析了多孔材料布局对复合结构吸声特性的影响。该文理论模型计算的结果与阻抗实验得到的垂直入射吸声系数基本一致,验证了理论模型的正确性。结果表明:在多孔材料前面增加空气层可以改善高频吸声特性;在多孔材料后面增加空气层可以改善复合结构低频吸声特性。通过合理配置多孔材料,可以在应用需求频段上达到满意的吸声效果。     

大黄素/Mg-Al-LDHs纳米杂化物的制备及缓释性能研究

以Mg-Al型层状双金属氢氧化物(Mg-Al-LDHs)为载体,将大黄素分子通过二次组装法成功插入其层间,得到大黄素/Mg-Al-LDHs纳米杂化物。XRD结果显示,Mg-Al-LDHs粒子层间距由0.48 nm增大到3.35 nm。差热曲线(DTA曲线)分析结果表明,该纳米杂化物分子中大黄素的分解温度比纯大黄素的分解温度高50℃。分别在pH 4.8和pH 7.5的缓冲溶液中测定了大黄素/LDHs的缓释性能,结果表明大黄素/LDHs的药品释放速率明显低于二者的物理混合物,并探讨了释放机理。     

MgFe-Cl-LDHs的合成、结构及其插层组装性能研究

合成出了层间含Cl-的MgFe型层状双羟基氢氧化物（MgFe-Cl-LDHs），通过X射线衍射(XRD)、红外光谱(FT-IR)、热重及差热分析(TG-DTA)和元素分析等手段对其组成和结构特征进行了分析。研究表明：在共沉淀条件下，可制得晶体结构规整的MgFe-Cl-LDHs，且其结构规整性随组成中Mg²⁺/Fe³⁺物质的量比的增大而增强；LDHs层板六配位的金属离子与层板羟基层、层板羟基层与层间结构水的相互作用不随Mg²⁺/Fe³⁺物质的量比的改变而改变，而层板主体与层间客体阴离子之间的静电引力随Mg²⁺/Fe³⁺物质的量比的增大而降低。另外，其超分子结构特征使层间Cl^-能与有机阴离子CH₂CHC₆H₄SO₃^-和CH₃(CH₂)₁₁SO₃^-发生离子交换，形成以双分子层垂直于层板的交错有序的排布结构模式。