钴铁水滑石基材料在电催化析氧中的应用

析氧反应(OER)是电催化裂解水、二次金属-空气电池和可再生燃料电池等绿色可持续能源储存和转化技术中的关键步骤,但其较高的势垒和迟滞的动力学过程限制了反应的效率。因此,设计开发高效、稳定的非贵金属催化剂是新能源领域面临的挑战之一。钴铁水滑石(CoFe LDH)材料具有独特的二维层状结构、丰富多变的化学组成、高分散的金属阳离子、优异的稳定性和成本低廉等优点,在OER反应中有广泛的应用前景。但不良的导电性和有限的活性位点阻碍了CoFe LDH的工业化应用。本文首先介绍了CoFe LDH的结构并阐述了其OER反应机理,接着总结了CoFe LDH的制备工艺,并详细综述了近年来提升其 OER性能的改性策略:插层剥离、空位制造、材料复合、离子取代和衍生物等。最后讨论了水滑石材料现阶段存在的问题和未来在能源转化和利用领域的发展方向。     

类水滑石材料在核废水处理领域的应用

核能已成为我国能源结构的重要组成部分, 但含放射性物质的废水所带来的危害不容忽视. 如何高效解决核废水污染问题迫在眉睫. 类水滑石材料是一类阴离子型粘土化合物, 因其层板组成及层间阴离子种类的可调控性、 较大的比表面积及粒径和形貌的可调控性等特点已在含放射性核素废水的处理中崭露头角. 本文主要阐述了类水滑石材料对废水中放射性核素的吸附行为及其作用机制, 探讨了存在的问题及可能的解决方法, 并对其发展前景进行了展望.     

水滑石阻燃剂的离子改性研究进展

由于水滑石具有层板阳离子可调控、层间阴离子可交换、酸碱性等独特的性能,在医药、离子交换、催化、材料阻燃等领域备受研究者关注。特别是水滑石用作阻燃材料时,具有无卤、无毒、不产生有毒和腐蚀性气体、阻燃和抑烟性能优良等突出优点,已成为当前材料阻燃领域研究的热点。然而,水滑石也存在热稳定性较差、容易聚集、分散性较差等缺点,故国内外学者开展了一些水滑石阻燃剂改性的系列研究。本文阐述了近年来国内外学者利用Ca2+、Mg2+、Al3+等阳离子对水滑石阻燃剂进行改性,以及应用BO33-、SiO32-等阴离子对水滑石阻燃剂进行改性等方面的研究进展,并对水滑石在生物质材料阻燃、低成本水滑石阻燃剂的合成、水滑石协效阻燃剂的研究、水滑石阻燃剂工业化生产新工艺与设备、洁净化制备技术等方面的研究与应用前景进行了展望。     

水滑石阻燃剂的离子改性研究进展

由于水滑石具有层板阳离子可调控、层间阴离子可交换、酸碱性等独特的性能,在医药、离子交换、催化、材料阻燃等领域备受研究者关注。特别是水滑石用作阻燃材料时,具有无卤、无毒、不产生有毒和腐蚀性气体、阻燃和抑烟性能优良等突出优点,已成为当前材料阻燃领域研究的热点。然而,水滑石也存在热稳定性较差、容易聚集、分散性较差等缺点,故国内外学者开展了水滑石阻燃剂改性的系列研究。本文阐述了近年来利用Ca~(2+)、Mg~(2+)、Al~(3+)等阳离子以及BO_3~(3-)、SiO_3~(2-)等阴离子对水滑石阻燃剂进行改性等方面的研究进展,并对水滑石在生物质材料阻燃、低成本水滑石阻燃剂的合成、水滑石协效阻燃剂的研究、水滑石阻燃剂工业化生产新工艺与设备、洁净化制备技术等方面的研究与应用前景进行了展望。     

类水滑石催化合成聚(碳酸1,4-丁二醇)酯二醇

采用共沉淀法制备了镁铝类水滑石(Mg-Al-CO3LDH)、镁锌铝类水滑石(Mg-Zn-Al-CO3LDH)和锌铝类水滑石(Zn-Al-CO3LDH),并研究了它们在碳酸二苯酯(DPC)与1,4-丁二醇(1,4-BD)酯交换合成聚碳酸酯二醇(PCDL)反应中的催化活性。在常压反应阶段,以苯酚的产率表征催化剂的活性;在减压缩聚阶段,以产品的数均分子量Mn和羟基值来表征催化剂的活性。结果发现,Zn-Al LDH具有良好的催化活性。在优化反应条件下,获得了Mn和羟基值分别为1600和70.8mg KOH/g的PCDL。     

LDHs生物医学复合材料的制备及其在药物输送和诊疗方面的应用

生命科学是关乎人类健康的重要研究领域.基于无机纳米材料为载体的生物无机材料推动了生命科学的发展.水滑石(LDHs)作为一种二维无机纳米材料,具有层板金属离子种类和比例可调控以及层间可插层的特性,近年来在生物医学领域受到广泛关注.本文重点介绍了水滑石纳米复合材料的物理化学结构、作为基因/药物载体的应用,以及在新型诊疗一体化复合材料领域的应用和优势.此外,通过细胞和活体实验,进一步探讨了水滑石纳米复合材料的细胞输运机制、诊断成像以及肿瘤治疗效果,并展望了水滑石纳米复合材料在生物医学领域的发展前景.     

癸二酸根插层水滑石的组装及其结构表征

有机物柱撑水滑石类化合物的基础和应用研究是水滑石层柱材料研究领域中较为活跃的一个分支。近年来,化学家和材料学家较为系统、深入地研究了有机物在水滑石层板间的插层组装方法、插层驱动力、主鄄客体间的超分子作用、插层产物的结构表征、性能和应用[1],制备出了许多具有特     

水滑石纳米阵列电极在能量储存和转化中的应用

纳米技术在能源领域的应用为解决化石燃料的消耗和环境污染问题提供了新的契机.水滑石(LDHs)作为一类典型的阴离子黏土材料,其独特的组成、结构及形貌可调性,使其成为一类优秀的能源储存和转化材料.其中,将水滑石材料进行纳米阵列结构化设计,结合水滑石优异的物理化学性能和纳米阵列的结构特性,已经成为构建高性能电化学电极的重要方法.本文综述了水滑石基纳米阵列电极的合成及其在电化学能量储存和转化上的应用,并进一步讨论了水滑石纳米阵列材料在该领域面临的挑战和发展趋势.     

水滑石层间阴离子为还原剂原位负载贵金属纳米颗粒

研究了以水滑石为载体原位负载贵金属纳米颗粒(Pd、Ag、Ru、Au)的方法,通过共沉淀合成甲酸根水滑石,以层间甲酸根为还原剂原位还原贵金属前驱体制得高分散水滑石(LDH)负载纳米颗粒。本方法无需载体预处理,操作方便、适用性强,阴离子前驱体(Au)和阳离子前驱体(Pd、Ag、Ru)均可顺利得到纳米颗粒。所得水滑石负载纳米颗粒系一种潜在的纳米催化剂,作为示例,Pd/LDH在Suzuki偶联反应中显示出较高催化活性。     

镁铝型水滑石水热合成

水滑石是一类具有特殊结构的层状无机材料 .具有可调变的组成及独特的结构和性能 ,在离子交换、吸附分离、催化、医药等领域得到广泛应用 [1～ 4 ] .特别是水滑石类材料所具有的选择性、红外吸收性和离子交换性等一些特殊性能 ,使其作为新型无机功能材料已应用于 PE农膜 (保温剂 )和 PVC(无毒热稳定剂 )等高分子材料中 ,显示了独特的性能[5] .作为无机功能材料 ,水滑石在复合材料中的应用必然涉及其粒子尺寸和分布 ,因此对水滑石晶化规律的研究非常重要 .水滑石成熟的合成方法是共沉淀法[6] ,如单滴法、双滴法 .由于沉淀粒子是渐次产生 ,…     

高铁酸钾的制备及其在废水治理中的应用进展

高铁酸钾是一种集氧化、絮凝、吸附、杀菌、消毒、除臭功能于一体的新型绿色高效水处理药剂,在废水处理领域具有重要的理论研究和实际应用价值。本文对近年来高铁酸钾的制备方法及其在废水治理中的应用进行综述,重点分析了各制备方法的优缺点,并结合当前最新研究成果对高铁酸钾的工业制备及在废水治理中的应用前景进行了展望。     

聚四氟乙烯膜分离技术在含油废水处理中的应用进展

世界生态环境逐渐恶化,为保护生态环境,含油废水的无害化处理排放成为保护生态环境的必要做法。膜处理技术作为20世纪最具发展前景的污水处理技术之一,具备低能耗,分离效率高等特点。聚四氟乙烯薄膜（PTFE）膜由于其具有的极高化学稳定性、良好的力学性能、过滤速度高、使用寿命长等特点,被广泛应用于水处理领域。为此本文概述膜分离原理,结合膜本身特点和改性方法,重点对PTFE膜及其改性膜在含油废水中的应用进行综述,并探讨了PTFE膜在应用过程中亟待解决的问题,为PTFE膜及其改性膜在水处理中的应用提供技术和理论支持。     

Ag/AgBr/Co–Ni–NO3 Layered Double Hydroxide Nanocomposites with Highly Adsorptive and Photocatalytic Properties

A facile anion‐exchange precipitation method was used to synthesize bifunctional Ag/AgBr/Co–Ni–NO₃ layered double hydroxide (LDH) nanocomposites by adding AgNO₃ solution to a suspension of Co–Ni–Br LDH. The Ag/AgBr nanoparticles were highly dispersed on the sheets of Co–Ni–NO₃ LDH. The prepared nanocomposites were used to adsorb and photocatalytically degrade organic pollutants from water. Without light illumination, the nanocomposites quickly adsorbed methyl orange, and the adsorptive capacity, which can reach 230 mg g^?1, is much higher than those of Co–Ni–Br LDH, Ag/AgBr, and activated carbon. The photocatalytic activities of the nanocomposites for the removal of dyes and phenol are higher than those of Co–Ni–Br LDH and Ag/AgBr. The proposed method can be applied to prepare other LDH/silver salt composites. The high absorptive capacity and good photocatalytic activity of such nanostructures could have wide applications in wastewater treatment.     

Enhancement of azo dyes removal efficiency by using LDH/Tris/Pd catalyst: Kinetic studies

LDH/Tris/Pd (CaAl‐layered double hydroxide/tris (hydroxymethyl)aminomethane/palladium) was synthesized and appraised for its catalytic activity towards the degradation of two selected azo dyes. The decolorization of azo dyes, acid red 18 (AR 18) and reactive yellow 15 (RY 15), requires considerably small amounts of synthesized catalyst. Kinetic studies show that the catalytic decolorization of these azo dyes follows the first order kinetic model. The reported method is simple and applicable; in addition, the stable catalyst can efficiently decolorize model azo dyes with good recyclability. Therefore, LDH/Tris/Pd can be accepted as the possible component for the utilization in wastewater treatment.     

粉煤灰在废水处理中的应用研究进展

粉煤灰的高附加值综合利用已成为循环经济和环境保护领域中亟待解决的重要课题之一,粉煤灰用于水处理是变废为宝、变害为利的一种尝试。粉煤灰因其形貌特征、比表面积、孔隙率和化学成分等方面的优势而在膜过滤、Fenton处理、光催化、吸附等方面均有显著应用价值。本文重点介绍粉煤灰在这几方面的应用,并对其在废水处理中的应用前景进行了展望。     

A mini-review of the electro-peroxone technology for wastewaters:Characteristics,mechanism and prospect

The electro-peroxone technology, a novel type of advanced oxidation technology, is widely used in wastewater treatment. Herein, this paper reviews the advantages and problems of the electro-peroxone technology compared with electrochemical oxidation technology, ozonation technology, and traditional peroxone technology. Due to the high kinetics of pollutant degradation, the electro-peroxone process can reduce the reaction time and energy consumption of pollutant treatment in wastewater. The elect...     

Bismuth-containing layered double hydroxide as a novel efficient photocatalyst for degradation of methylene blue under visible light

Layered double hydroxide (LDH)-based photocatalysts have emerged as a very promising candidate to replace TiO₂, owing to their unique layered structure, tunable band gaps, low cost, ease of scale-up, and good photocatalytic activity. Bismuth-doped ZnCr-LDH was studied as photocatalyst in the photodegradation of methylene blue (MB). The structure and morphology of ZnCr-LDH and ZnCrBi-LDH were characterized using a different mode of delegated tools, e.g., FTIR, XRD, UV–Vis, FESEM–EDX, and TEM measurements. FESEM and TEM image of the synthesized LDHs showed that the synthesized LDH is smooth overlapping crystals, and they are approximately in hexagonal form. The material was found to be a good photocatalyst for degradation of methylene blue in visible light, and the results showed that the photocatalytic activity of ZnCrBi-LDH sample is higher than of ZnCr-LDH sample. According to the kinetic data, the reaction rate constant of ZnCrBi-LDH is approximately four times higher than the apparent reaction rate constant of ZnCr-LDH. The catalytic activity was retained even after four methylene blue degradation cycles, indicating that the LDH could be an important addition to the field of wastewater treatment.     

Application of liquid chromatography quadrupole time-of-flight mass spectrometry to the identification of acetamiprid transformation products generated under oxidative processes in different water matrices

This work allowed the identification of major transformation products (TPs) of acetamiprid (ACTM) during Fenton process. Acetamiprid is a chloronicotinoid insecticide widely used around the world for its characteristics (high insecticidal activity, good systemic properties, suitable field stability, etc.). The degradation of the parent molecule and the identification of the main TPs were evaluated in different water matrices (demineralized water and real agro-food industrial wastewater). TPs of acetamiprid generated by Fenton experiments were monitored and identified by liquid chromatography quadrupole time-of-flight tandem mass spectrometry (LC–QTOF–MS/MS). Up to 14 TPs were characterized based on the accurate mass of the molecular ion and fragment ions obtained in both full-scan and MS/MS modes. Most of them were eliminated after 75 min of treatment time in demineralized water. However, in real agro-food industrial wastewater, most of them were eliminated at 90 min of treatment time, demonstrating the influence of the matrix composition on the studied compound degradation.     

树脂吸附法处理有毒有机化工废水及其资源化研究

介绍了大孔树脂的发展及在有机化工废水处理及资源化领域的应用,包括大孔树脂的合成、吸附作用的基本原理以及在具体化工废水处理项目（如2,3-酸、对硝基酚等）的应用。     

磁场对含Ni废水混凝的影响

对不溶性强磁性水污染物、高梯度磁处理技术已显示了其速度快、效率高、成本低等优点,并受到人们的注目,但对于弱磁性悬浮物及可溶性磁性物质来说,目前所采用的加磁种的方法,因其工艺复杂、成本高而无法推广,如何选择合理的处理方法,是废水磁分离技术的一个重要研究课题,磁场作为混凝的强化手段,国外已有一些研究,但国内尚未见报道,本文研究了非均匀磁场对含Ni废水混凝处理的影响及相关的各种因素。