水滑石及其衍生物处理水中污染物的研究进展

水滑石(LDH)由于具有记忆效应、内部结构可调性、层间阴离子可交换性等优良性质,而在水处理领域具有广阔应用前景。本文综述了水滑石及其衍生物处理水中污染物的最新研究进展。介绍了LDH处理重金属废水和有机废水,利用催化氧化性能或通过与不同材料复合处理废水。此外,还简述了LDH的规模化生产现状及存在问题,对LDH材料在水处理领域的未来发展方向进行了展望。     

高荧光性含锌类水滑石研究

本研究将适量锌离子(II)取代镁铝水滑石中的镁离子(II), 以及将一定量的8-羟基喹啉(8-hydroxyquinoline)分散于镁铝水滑石层间的亲油性阴离子中, 使与其板层表面上的锌离子配位, 经共沉淀法, 合成、组装得到一类迄今未见报道的具高荧光性的类水滑石(Zn-HTLC)荧光材料. 采用荧光光谱、红外光谱、紫外光谱、X射线衍射和热分析等对其进行了表征. 研究表明, 这种类水滑石在紫外光下可发出强烈的蓝绿色荧光(501 nm), 荧光强度高达4.5×10⁵ a.u., 说明锌离子(II)分散于类水滑石的氢氧化镁板层中, 可有效防止发光结构单元的荧光猝灭, 而且溶于层间阴离子中的配体与板层上的锌离子(II)配位所形成的特殊组装结构, 增强了发光中心的不对称性, 也是其具有高荧光性的可能原因. 热分析结果显示, 这种类水滑石耐热性强, 有望应用于各种功能性荧光材料.     

含钯类水滑石衍生复合氧化物Pd/M3AlO(M=Mg,Co, Ni,Cu, Zn)催化剂上氯苯的催化氧化

采用共沉淀法制备了系列含Pd类水滑石材料, 类水滑石基体为M3Al-HT (M=Mg, Co, Ni, Cu, Zn), 经焙烧制备出含Pd类水滑石衍生复合氧化物催化剂. 通过X射线衍射(XRD), 热重-差热分析(TG-DTG), H2程序升温还原(H2-TPR), O2程序升温脱附(O2-TPD)和N2吸脱附等表征技术手段研究了不同二价金属元素对含Pd类水滑石衍生复合氧化物催化剂物理化学性质及其对挥发性有机污染物氯苯催化氧化性能的影响. XRD和TG-DTG结果表明, 不同二价金属元素, 除Cu外, 都能形成类水滑石层状结构, Pd在不同类水滑石前驱物中均能良好分散. 不同的二价金属元素对催化剂性能的影响不同, 其中Pd/Co3AlO催化剂表现出最高的氯苯催化氧化活性, 其起燃温度和全转化温度分别为182和283 ℃. H2-TPR和O2-TPD测试表明, Pd和类水滑石衍生复合氧化物存在着协同作用, Pd的引入促进了复合氧化物的还原, 从而影响氧化物的氧化还原性能. Pd/M3AlO系列催化剂的活性主要受催化剂的氧化还原性能及其表面活性氧物种的影响.     

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 ,…     

CuMgAlFeNO3型纳米层状复合氢氧化物的制备与表征

采用稳态共沉淀法合成了系列CuMgAlFeNO3类水滑石(CMAFNO3-HTLC), 可得到结晶良好的类水滑石材料, 并通过XRD, TG-DSC, FTIR, TEM对产物进行了表征.     

水滑石作为芬顿反应催化剂的研究进展

芬顿反应(Fenton reaction)利用H_2O_2与Fe~(2+)的催化反应可快速生成高活性的·OH自由基用于有机物的降解等过程,因其无副产物的二次污染被广泛应用于环境保护和污水处理领域.但传统的均相芬顿反应中,低价金属再生效率较低,导致整体的反应效率受到限制.同时,传统均相芬顿反应因为酸性的反应条件以及铁离子的引入,从环保角度来看也不是一个理想的反应体系.近年来,水滑石(layered double hydroxides, LDHs)作为一种特殊的层状结构材料,在芬顿反应中表现出优异的催化性能,引起了人们的广泛关注. LDHs的催化活性位点通常为固定于固体表面的金属离子,可避免反应中金属离子的浸出,降低反应体系对pH的要求.同时由于水滑石层板中多元金属的可调控性,可设计制备具有多种过渡金属的协同氧化还原循环的水滑石材料,促进低价金属再生的循环反应,提高芬顿反应效率.本文主要介绍了近年来水滑石类材料作为芬顿反应催化剂的研究成果和进展,并对该领域目前面临的挑战和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。     

发红色荧光的类水滑石材料的制备及在LED中的应用

通过共沉淀法合成了发红色荧光的类水滑石材料,采用硅烷偶联剂对其进行了表面改性,并利用荧光光谱、红外光谱、X射线衍射(XRD)和扫描电子显微镜(SEM)等对其结构和性能进行了表征,探讨了表面改性对荧光类水滑石的影响.将改性荧光类水滑石与发射波长为384 nm的In Ga N芯片组合制成发光二极管,器件发出明亮的红光.研究结果表明,改性的发红色荧光的类水滑石是制作白光二极管可供选用的红色发光材料.     

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。     

水滑石无机阴离子交换剂的合成与表征

采用水热法制成了镁铝碳酸盐型、镁铝硝酸盐型、镁铝盐酸盐型、镁铝羟基型等插层镁铝类水滑石,比较了层间含不同阴离子类水滑石的结构差异和高温热处理后的结构稳定性.通过离子交换方式以镁铝羟基型为基材插层组装无机阴离子基团MoO42-、WO42-、CO32-和NO3-制得不同的阴离子插层类水滑石.通过XRD、TEM、XPS和热分析方法对镁铝类水滑石和阴离子插层类水滑石进行了表征.     

Treatment of heavy metal ions in wastewater using layered double hydroxides: A review

Heavy metal ions are toxic, and their toxicities change with different valence states, charges, and radii. Among the methods used for heavy metal ion removal, adsorption is widely employed due to its low cost and simple operation. As natural anionic clays, layered double hydroxides (LDHs) have drawn considerable attention for their use in the removal of anionic pollutants (such as heavy metal anions) due to their high removal efficiency and environmental friendliness. This article reviews the effects of the charge, type, and radius of the cations in the laminates of LDHs and the anions in the LDH interlayers, as well as the charge and radius of the heavy metals and the conditions (such as pH, coexisting ions, and temperature) on removing heavy metal ions with LDHs. The removal mechanisms have also been discussed. LDHs are hugely promising as an application for removing heavy metal ions that exist in different ionic forms by controlling the type and condition of LDHs.     

Recent progress in functionalized layered double hydroxides and their application in efficient electrocatalytic water oxidation

Layered double hydroxides(LDHs), a class of anionic clays consisting of brucite-like host layers and interlayer anions, have been widely investigated in the last decade due to their promising applications in many areas such as catalysis, ion separation and adsorption. Owing to the highly tunable composition and uniform distribution of metal cations in the brucite-like layers, as well as the facile exchangeability of intercalated anions, LDHs can be modified and functionalized to form various nanostructures/composites through versatile processes such as anion intercalation and exfoliation, decoration of nanoparticles, selfassembly with other two-dimensional(2D) materials, and controlled growth on conductive supports(e.g.,nanowire arrays, nanotubes, 3D foams). In this article, we briefly review the recent advances on both the LDH nanostructures and functionalized composites toward the applications in energy conversion, especially for water oxidation.     

阴离子层状材料的可控制备

LDHs (layered double hydroxides)是一类具有相同结构、不同物理化学性质的阴离子层状无机功能材料,作为催化剂、催化剂载体和催化剂前驱体在催化领域得到了广泛的关注. 本文综述了LDHs制备技术的最新发展,并从粒径控制、结晶度控制、形貌控制、含贵金属LDHs以及原位固载化等方面详细讨论了LDHs的可控制备技术.     

基于层状双金属氢氧化物的电化学生物传感器研究进展

层状双金属氢氧化物（LDHs）具有开放的二维平面结构和良好的生物相容性,是非常适合于将生物酶固定在电极表面用于生物传感器的主体材料。本文介绍了酶在LDHs材料上的固定方法,综述了近年来基于这类二维层状材料的各种电化学生物传感器的研究进展,讨论了不同类型生物传感器的设计原理和电子传递机理,并对LDHs在电化学生物传感领域...     

Mg–Al layered double hydroxide intercalated with sodium lauryl sulfate as a sorbent for <Superscript>152+154</Superscript>Eu from aqueous solutions

In the present study, Mg–Al layered double hydroxide intercalated with nitrate anions (LDH-NO₃) was synthesized, modified with the anionic surfactant, sodium lauryl sulfate, and applied for the removal of ^152+154Eu from aqueous solutions. Modification of the as-synthesized Mg–Al layered double hydroxide was carried out at surfactant concentration of 0.01 M (the organo-LDH produced denoted LDH-NaLS). The as-synthesized and surfactant-intercalated LDHs were characterized by FT-IR and energy-dispersive X-ray spectroscopy techniques. The effect of some variables such as solution pH, contact time and sorbate concentration on removal of ^152+154Eu was investigated. The kinetic data obtained were well fitted by the pseudo-second-order kinetic model rather than the pseudo-first-order model. Intraparticle diffusion model showed that sorption of ^152+154Eu proceed by intraparticle diffusion together with boundary layer diffusion. Experimental isotherm data were well described by Langmuir model. Organo-LDH was found to have higher capacity (156.45 mg g⁻¹) for europium than the as-synthesized LDH-NO₃ (119.56 mg g⁻¹). Comparing LDHs capacities obtained for Eu(III) in the present work with other sorbents reported in literature indicated that LDHs have the highest capacities. Application of the developed process for removal of ^152+154Eu(III) from radioactive process wastewaters was also studied and the obtained results revealed that these LDHs are promising materials for treatment of radioactive wastewaters.     

Recent advances of layered double hydroxides–based bifunctional electrocatalysts for ORR and OER

The oxygen reduction reaction (ORR) and the oxygen evolution reaction (OER) have attracted increasing attention for the sake of clean, renewable, and efficient energy technologies in recent years. The design of ORR/OER bifunctional electrocatalysts is a challenging task in the promotion of highly efficient rechargeable metal-air batteries as well as regenerative fuel cells. Owing to the wide adaptability of different types and ratios of metals in the interlayer space as well as the adjustable interlayer distance, composite materials with layered double hydroxides (LDHs) and their derivatives have recently been registered as electrode materials and catalysts supports for various electrochemical reactions. This study examines the recent development of bifunctional electrocatalysts based on LDHs for ORR/OER to expand the application of LDHs in the field of energy storage and conversion. Various bifunctional electrocatalysts associated with LDHs are discussed in detail to improve their performance. Finally, existing problems and future prospects for improving the performance of LDHs bifunctional electrocatalysts are proposed.     

A Prospect for Environmental Remediation of Perchlorate via Cost-Effective Pinus Leaves and Dandelion Flower Powder-based Layer Double Hydride (LDH) Sorbents

In this study, pine leaves powder (PiP) and dandelion flower powder (DFP) were repurposed to synthesize layered double hydroxides (LDHs) to form a base for sorbents used in perchlorate remediation from wastewater. The effects of the adsorbent dose, pH, thermodynamics, and coexisting ions were evaluated in batch experiments. The results revealed that 0.1 g adsorbent (PiP-LDH and DFP-LDH) removed 97% and 93% of perchlorate contaminants, respectively. In this study, the correlation coefficient of pseudo-second-order was higher than pseudo-first-order for all the LDHs. The kinetic and isotherm studies showed the best uptake of perchlorate in the short time was by PiP-LDH, followed by DFP-LDH (20 min and 40 min, respectively). The calculated and experimental values of adsorption at the equilibrium state also concurred with the pseudo-second-order model. The prepared LDHs were mesoporous. The surface area of PiP-LDH provided more adsorption sites, rendering it more suitable for perchlorate adsorption compared with the other two LDHs. The model suggests Physico-chemical interactions behind the sorption of perchlorate by LDHs. The adsorption was more influenced by anions i.e, PO₄³⁻ > SO₄²⁻ > NO₃ than monovalent anions due to the increase in the charge radius values. The prepared LDHs could be of great benefit to the environmental remediation of wastewater bodies.     

二氟尼柳/水滑石插层组装结构、氢键及水合特性的分子动力学模拟

采用分子动力学方法模拟二氟尼柳插层水滑石(DIF/LDHs)的超分子结构, 研究复合材料主客体间形成的氢键以及水合膨胀特性.结果表明, 当水分子总数与DIF分子总数之比Nw≤3时, 层间距dc保持基本恒定, 约1.80 nm; 当Nw≥4时, 层间距逐渐增大, 且符合dc=1.2611Nw+13.63线性方程. 随着水分子个数增加, 水合能驻UH逐渐增大. 当Nw≤16时, 由于⊿UH<-41.84 kJ·mol-1, LDHs-DIF可以持续吸收水, 从而使材料层间距不断膨胀. 但当Nw≥24时, ⊿UH>-41.84 kJ·mol-1, 此时LDHs-DIF层间不能再进一步水合, 因此LDHs-DIF在水环境中膨胀具有一定的限度. 水滑石层间存在复杂的氢键网络. DIF/LDHs水合过程中, 水分子首先同步与层板和阴离子构成氢键; 当阴离子趋于饱和后, 水分子继续与层板形成氢键, 并逐步发生L-W型氢键取代L-A型氢键, 驱使阴离子向层间中央移动, 与层板发生隔离; 最后水分子在水滑石羟基表面形成有序结构化水层.     

二元类水滑石层板组成、结构与性能的理论研究

采用晶体学理论建立二元类水滑石(LDHs)微观结构模型与静电势能模型，将层板金属离子间距、层板电荷密度、层间阴离子间距等微观结构参数定量化，并将层间阴离子的静电势能表示成层板金属离子半径和物质的量之比、插层阴离子尺寸和电荷的函数。研究结果表明：LDHs层板金属离子间距应用离子紧密堆积来估算和孔径按阴离子平面六方点阵分布来计算是可行的；调变层板金属离子种类与物质的量之比影响层间阴离子的稳定性，势能计算值与文献报道的LDHs热稳定性次序一致。所以该模型可用于预测LDHs的微观结构参数以及热稳定性，为新型层状双羟基材料的定向合成提供思路。     

层状双金属氢氧化物微观结构与性质的理论研究进展

总结了近年来理论计算方法在研究层状双金属氢氧化物(LDHs)结构与功能方面的应用现状. 结合LDHs材料的结构特点, 归纳了量子力学、分子力学、几何建模及物理静电模型相结合对LDHs材料进行结构模拟的思路, 比较了各种方法在LDHs结构模拟上的优势及存在的不足. 量子力学方法能够精确获得水滑石材料的层板构成及作用机制、简单阴离子插层水滑石主客体间的超分子作用实质以及电子性质、反应机理等方面的信息. 与量子力学相比较, 分子力学方法可以快速得到插层水滑石材料的层间阴离子排布及取向、水合膨胀特性及宏观力学性质等. 几何模型和物理静电模型能构建直观、形象的数学模型, 大大简化了计算量,因此能计算接近实际LDHs尺寸的体系, 为推测LDHs结构信息提供了可能性. 随着理论方法和计算机硬件水平的发展, 使得计算机模拟技术逐渐成为获得LDHs材料微观结构参数、电子性质和动力学性质的一种有效手段.