共查询到18条相似文献,搜索用时 171 毫秒
1.
以MoS 2为载体,通过水热法合成Fe 3O 4/MoS 2催化剂,采用X射线衍射、透射电子显微镜和X射线光电子能谱分析对材料进行表征,研究了Fe 3O 4/MoS 2/PMS体系中2,4-二氯苯氧基乙酸(2,4-D)的降解效率并探究了其反应机理.结果表明,以Fe 3O 4、MoS 2和Fe 3O 4/MoS 2为催化剂,30 min内2,4-D的去除率分别为31%、 20%和89%.表征结果发现,在MoS 2的存在下,Fe 3O 4表面的Fe(Ⅲ)还原为Fe(Ⅱ),Mo(Ⅳ)被氧化为Mo(Ⅵ),Fe 3O 4和MoS 2间的协同作用加强了PMS分解,提高了2,4-D去除效率.自由基淬灭实验表明,·OH、 SO<... 相似文献
2.
载金催化剂可在温和条件下还原性降解环境中某些有毒有害污染物,并转化为低毒性、高附加值的物质,从而促进水体污染物化学资源转化和综合利用.本文设计制备Fe@CeO 2/CN双空腔核壳磁性载金椭球催化剂,用于还原降解水体中对硝基苯酚和染料污染物.该催化剂先制备Fe 2O 3@CeO 2梭型微粒内核,采用乙二胺介导的Stober扩展法在其表面合成SiO 2@RF复合物,经过碳化-水热蚀刻得到具有介孔碳氮壳层的Fe 2O 3@CeO 2/CN椭球;采用[Au(en) 2] 3+为金前驱体的沉积沉淀-还原气氛热处理法在上述椭球中构筑较好分散度超细纳米Au颗粒,同时Fe 2O 3转化为小体积Fe颗粒并形成内空腔,得到Fe@CeO 2-Au/CN双空腔核壳磁性椭球催化剂.该催化剂独特的结构特征和复合组分协同增强性效应使其在还原降解对硝基苯酚和染料... 相似文献
3.
本文以双壁碳纳米管(double-walled carbon nanotubes,DWCNTs)为基础材料,通过化学沉淀法制备了磁性双壁碳纳米管(magnetic double-walled carbon nanotubes,m-DWCNTs),研究了pH和吸附剂投加量对全氟辛烷磺酸(perfluorooctane sulfonate,PFOS)的吸附影响.采用扫描电镜(SEM)、傅里叶红外光谱(FTIR)、X射线衍射(XRD)和VSM对吸附前后的m-DWCNTs进行了观察,并进行了吸附动力学模型和等温线模型拟合.结果表明,磁化后的双壁碳纳米管包覆了铁的氧化物,出现了Fe 3O 4的特征衍射峰,具有超顺磁性,饱和磁化强度为66.07 emu·g -1. m-DWCNTs对PFOS的吸附更符合准二级动力学方程(R 2>0.95)和Langmuir等温吸附模型(R 2>0.95).随着m-DWCNTs投加量的增加,吸附量逐渐降低,去除率逐渐升高.吸附量随着pH值的增加而逐渐降低,... 相似文献
4.
铬是污染性金属元素,铬含量是水质污染控制的一项重要指标,其中Cr(Ⅵ)的毒性最大,且易被人体吸收.本研究以水中的Cr(Ⅵ)吸附传质分离为目标,利用以铝为金属源水热法合成的铝基MOFs为前驱体,600℃煅烧后制备了多孔掺碳Al 2O 3吸附材料,利用现代分析技术对其进行微观结构表征,探究了其吸附作用能力与机制.研究结果表明,XRD、SEM、BET等表征手段证明了NH 2-MIL-53(Al)与多孔掺碳Al 2O 3结构的成功合成.前驱体NH 2-MIL-53(Al)和煅烧后的衍生物多孔掺碳Al 2O 3,在形貌上相似,且多孔掺碳Al 2O 3材料(180.24 m 2·g -1)的比表面积要大于NH 2-MIL-53(Al)(116.73 m 2·g -1).多孔掺碳Al 2 相似文献
5.
采用溶剂热-水热法合成了碳覆盖的Fe3O4纳米粒子Fe3O4/C,利用扫描电镜(SEM)与红外光谱(FT-IR)对其进行了表征,并研究了其对水中罗丹明B的吸附性能.系统考察了吸附动力学、吸附等温线、吸附剂用量对吸附性能的影响.Fe3O4/C对罗丹明B的吸附在3 h内即可达到平衡,最大吸附量可达13.23 mg.g-1.分别用Langmuir和Freundlich吸附模型解释了Fe3O4/C对罗丹明B的作用机理,吸附反应过程符合准二级动力学方程.结果表明,该吸附剂具有良好的磁效应和吸附性能,可快速去除罗丹明B,去除率高达90%以上;吸附剂可重复利用,成本低,具有环境友好的优势. 相似文献
6.
以锐钛矿TiO 2(P25)为载体采用原位生长法负载锰氧化物制备了Mn/TiO 2催化剂,再以等体积浸渍-煅烧法对该催化剂掺杂氧化铈制备Ce(x)Mn/TiO 2-y催化剂用以烟气低温SCR脱硝.在固定锰负载量(质量分数为8%)的基础上,考察了铈掺杂量(铈锰摩尔比)、煅烧温度对催化剂SCR脱硝性能的影响.采用TEM、BET、XRD和XPS等手段表征了催化剂的理化结构特性.结果发现,当Ce/Mn的摩尔比例为1.0,煅烧温度为300℃时,Ce(1.0)Mn/TiO 2-300催化剂在150—300℃温度范围内、10500—27000 h -1的空速范围内,能够保持90%以上的NO转化率.理化性能分析结果表明,煅烧温度对催化剂的微观形貌影响显著,随着煅烧温度的升高,Ce(1.0)Mn/TiO 2-500催化剂活性物种颗粒集聚明显、比表面积降低,且锰氧化物价态分布偏向于低价态;铈的掺杂有助于Ce(1.0)Mn/TiO 2-300催化剂活性物种在载体表面的均匀分散,可以促进产生更多的Mn4+物种和更多的吸附氧,有利于催化剂低温SCR脱硝性能的提升. 相似文献
7.
本研究以钙基蒙脱石(Ca-MMT)为原料,通过K +作用制得改性蒙脱石粉(K-MMT),经海藻酸钠交联作用,将改性蒙脱石与永磁体(BaFe 12O 19)结合,制成钾改性蒙脱石磁性微球(KMBC).对比了Ca-MMT、K-MMT、KMBC对Cs+的吸附差异,并通过SEM-EDS、FTIR、XRD、XPS分析了K-MMT的微观结构及理化性质.试验结果表明,K +对蒙脱石的改性以离子交换为主,改性后晶体层间距变小,吸附量K-MMT>KMBC>Ca-MMT,分别为57.08、45.13、45.05 mg·g -1;K-MMT对Cs +的吸附属于吸热反应,反应在2 h内可达到平衡,35℃时KMBC的最大吸附量为136.08 mg·g -1;随着pH的增加,KMBC对Cs+的吸附量呈先增大后减小的趋势;吸附机理主要包括离子交换和内层扩散. 相似文献
8.
采用过硫酸钠(PDS)直接氧化和催化活化氧化脱色罗丹明B(RhB),分别考察了PDS剂量、pH、催化剂、Cl-浓度对RhB脱色的影响.结果表明,PDS在无外加催化剂下能够有效脱色RhB,pH越低,脱色率越高;当pH 2.4,PDS用量为3.5 g·L -1,在120 min内RhB的脱色率可达92%;自由基淬灭实验表明,酸性条件下主要为PDS直接氧化脱色RhB,并存在小部分硫酸根自由基(SO 44·-)作用.在pH 5.6、pH 8.0条件下,外加活性炭纤维(ACF)、四氧化三铁(Fe 3O 44)、Fe 3O 44负载型催化剂(ACF/Fe3O 44)可促进PDS对RhB脱色;在pH 2.4条件下,外加ACF对RhB脱色的促进作用较小,Fe 3O 44、ACF/Fe 3O 44对RhB脱色有一定抑制作用.不同pH和催化剂处理下,低浓度Cl-(0.01、0.04 mO 4l·L -1)对RhB脱色速率都呈现抑制作用,高浓度Cl-(0.08 mO 4l·L -1)相对于低浓度Cl-处理都呈促进作用.不同浓度Cl-处理在反应前60 min RhB脱色速率差异较大,而反应120 min后脱色率差异较小.提出Cl-通过调控SO 44·-脱色RhB途径来影响RhB脱色速率的机理,Cl-竞争消耗SO 44·-降低RhB脱色速率,但经一系列反应生成的Cl2·-能与RhB快速反应而提高RhB脱色速率;Cl-对RhB的脱色反应速率的影响存在抑制-促进双重机制,且与Cl-浓度相关.研究结果为基于PDS直接氧化和催化氧化处理含盐染料废水的研究和应用提供了一定的理论依据. 相似文献
9.
本研究以硝酸铈、硝酸锆为原料使用溶剂热合成法,制备了CeO 2-ZrO 2纳米棒催化剂(Ce 0.7Zr 0.3O 2(NR)),并用于柴油车尾气碳颗粒催化净化.催化活性检测证实:Ce 0.7Zr 0.3O 2(NR)纳米棒催化剂可有效净化柴油车尾气碳烟颗粒.在Ce 0.7Zr 0.3O 2(NR)存在下,碳颗粒净化率为10%、50%和90%时,所需温度分别仅为375℃、414℃和455℃,比商用Ce 0.7Zr 0.3O 2和Ce0.3Zr0.7O2催化剂性能更优.采用氮吸附-脱附、X射线光电子能谱(XPS)、H2程序升温还原(H 2-TPR)、X射线衍射(XRD)、拉曼光谱(Raman)、扫描电子显微镜(SEM)和透射电子显微镜(TEM)等技术对催化剂进行表征.XRD和Raman结果证实,Ce 0.7Zr 0.3O 2(NR)主要由立方相CeO 2构成,并掺杂了少量四方相氧化锆.SEM和TEM结果则显示,Ce 0.7Zr 0.3O 2(NR)催化剂颗粒明显由纳米棒堆积而成,特定的纳米形貌会影响其对碳颗粒的催化氧化活性.XPS结果证明Ce 0.7Zr 0.3O 2(NR)催化剂主要具有晶格氧、化学氧和表面吸附氧等氧物种;晶格氧是碳颗粒氧化的活性氧物种,其溢流到催化剂表面可与碳颗粒接触从而提高反应活性;化学氧和表面吸附氧均为表面氧物种,极易与表面固体碳颗粒直接接触,从而可在较低温度下促进碳颗粒的净化.H 2-TPR结果进一步证实了XPS结果,Ce 0.7Zr 0.3O 2(NR)催化剂的低温还原温度比商用Ce 0.7Zr 0.3O 2催化剂更低,且含有更多的易还原氧物种,这些低温易还原氧物种可以在较低温度下参与催化反应,促进柴油车尾气颗粒物的低温催化净化. 相似文献
10.
以焦炭为原料、KOH为活化剂制备改性焦炭,采用原位氧化沉淀法制备纳米Fe_3O_4负载于改性焦炭表面上,制备出磁性复合材料,利用N2等温吸附(BET)、扫描电子显微镜(SEM)、傅里叶交换红外光谱(FTIR)、X射线衍射(XRD)、振动样品磁强计(VSM)等对其进行了表征,并研究了其对罗丹明B的吸附性能,系统考察了吸附动力学、吸附等温线、pH、吸附剂投加量对吸附性能的影响.结果表明,改性焦炭微孔结构发达,利于Fe_3O_4分散负载其表面上.Fe_3O_4/改性焦炭具有良好的磁性能和吸附性能,在2 h内对罗丹明B达到吸附平衡,吸附动力学符合准二级吸附动力学方程,等温吸附数据符合Langmuir模型,吸附是自发行为且为吸热反应.吸附剂在较宽的pH范围内有较高的吸附量,罗丹明B去除率可达98.32%. 相似文献
11.
• BiVO4/Fe3O4/rGO has excellent photocatalytic activity under solar light radiation. • It can be easily separated and collected from water in an external magnetic field. • BiVO4/Fe3O4/0.5% rGO exhibited the highest RhB removal efficiency of over 99%. • Hole (h+) and superoxide radical (O2•−) dominate RhB photo-decomposition process. • The reusability of this composite was confirmed by five successive recycling runs. Fabrication of easily recyclable photocatalyst with excellent photocatalytic activity for degradation of organic pollutants in wastewater is highly desirable for practical application. In this study, a novel ternary magnetic photocatalyst BiVO 4/Fe 3O 4/reduced graphene oxide (BiVO 4/Fe 3O 4/rGO) was synthesized via a facile hydrothermal strategy. The BiVO 4/Fe 3O 4 with 0.5 wt% of rGO (BiVO 4/Fe 3O 4/0.5% rGO) exhibited superior activity, degrading greater than 99% Rhodamine B (RhB) after 120 min solar light radiation. The surface morphology and chemical composition of BiVO 4/Fe 3O 4/rGO were studied by scanning electron microscopy, X-ray diffraction, X-ray photoelectron spectroscopy, UV–visible diffuse reflectance spectroscopy, Fourier transform infrared spectroscopy, and Raman spectroscopy. The free radicals scavenging experiments demonstrated that hole (h +) and superoxide radical (O 2•−) were the dominant species for RhB degradation over BiVO 4/Fe 3O 4/rGO under solar light. The reusability of this composite catalyst was also investigated after five successive runs under an external magnetic field. The BiVO 4/Fe 3O 4/rGO composite was easily separated, and the recycled catalyst retained high photocatalytic activity. This study demonstrates that catalyst BiVO 4/Fe 3O 4/rGO possessed high dye removal efficiency in water treatment with excellent recyclability from water after use. The current study provides a possibility for more practical and sustainable photocatalytic process. 相似文献
12.
● PDA-Fe3O4-Ag was made by hydrothermal and oxidation self-polymerization method. ● PDA-Fe3O4-Ag had great magnetic separation performance. ● PDA-Fe3O4-Ag had good adsorption and degradation performance for ionic dyes. ● PDA-Fe3O4-Ag showed NR and MO degradation potential of 91.2% and 87.5%, respectively. High-performance adsorbents have been well-studied for the removal of organic dye pollutants to promote environment remediation. In this study, an Ag nanoparticle-functionalized Fe 3O 4-PDA nanocomposite adsorbent (PDA-Fe 3O 4-Ag) was synthesized, and the adsorption/separation performance of commonly used cationic and anionic organic dyes by the PDA-Fe 3O 4-Ag adsorbent were assessed. Overall, PDA-Fe 3O 4-Ag exhibited a significantly higher adsorption capacity for cationic dyes compared to anionic dyes, the highest of which was more than 110.0 mg/g (methylene blue (MB)), which was much higher than not only the adsorption capacities of the anionic dyes in this study but also other dye adsorption capacities reported in the literature. The dye adsorption kinetics data fitted well to both the pseudo second-order kinetics model and the Langmuir isotherm model, suggesting a monolayer-chemisorption-dominated adsorption mode. Thermodynamics analysis indicated that the adsorption process was both endothermic and spontaneous. Furthermore, the PDA-Fe 3O 4-Ag adsorbent achieved high photodegradation removal rates of the dyes, especially neutral red (NR) and methyl orange (MO), which were 91.2% and 87.5%, respectively. With the addition of PDA-Fe 3O 4-Ag, the degradation rate constants of NR and MO increased from 0.08 × 10 −2 and 0 min −1 to 2.11 × 10 −2 and 1.73 × 10 −2 min −1, respectively. The high adsorption and photocatalytic degradation performance of the PDA-Fe 3O 4-Ag adsorbent make it an excellent candidate for removing cationic and anionic dyes from the industrial effluents. 相似文献
13.
• Strong metal-support interaction exists on Pt/Fe3O4 catalysts. • Pt metal particles facilitate the formation of oxygen vacancies on Fe3O4. • Fe3O4 supports enhance the strength of CO adsorption on Pt metal particles. ![]() The self-inhibition behavior due to CO poisoning on Pt metal particles strongly impairs the performance of CO oxidation. It is an effective method to use reducible metal oxides for supporting Pt metal particles to avoid self-inhibition and to improve catalytic performance. In this work, we used in situ reductions of chloroplatinic acid on commercial Fe 3O 4 powder to prepare heterogeneous-structured Pt/Fe 3O 4 catalysts in the solution of ethylene glycol. The heterogeneous Pt/Fe 3O 4 catalysts achieved a better catalytic performance of CO oxidation compared with the Fe 3O 4 powder. The temperatures of 50% and 90% CO conversion were achieved above 260°C and 290°C at Pt/Fe 3O 4, respectively. However, they are accomplished on Fe 3O 4 at temperatures higher than 310°C. XRD, XPS, and H 2-TPR results confirmed that the metallic Pt atoms have a strong synergistic interaction with the Fe 3O 4 supports. TGA results and transient DRIFTS results proved that the Pt metal particles facilitate the release of lattice oxygen and the formation of oxygen vacancies on Fe 3O 4. The combined results of O 2-TPD and DRIFTS indicated that the activation step of oxygen molecules at surface oxygen vacancies could potentially be the rate-determining step of the catalytic CO oxidation at Pt/Fe 3O 4 catalysts. The reaction pathway involves a Pt-assisted Mars-van Krevelen (MvK) mechanism. 相似文献
14.
A simple solvothermal method was used to prepare monodisperse magnetite (Fe 3O 4) nanoparticles attached onto graphene oxide (GO) sheets as adsorbents to remove tetrabromobisphenol A (TBBPA) from an aqueous solution. These Fe 3O 4/GO (MGO) nanocomposites were characterized by transmission electron microscopy. The adsorption capacity at different initial pH, contact duration, and temperature were evaluated. The kinetics of adsorption was found to fit the pseudo-second-order model perfectly. The adsorption isotherm well fitted the Langmuir model, and the theoretical maximum of adsorption capacity calculated by the Langmuir model was 27.26 mg?g -1. The adsorption thermodynamics of TBBPA on the MGO nanocomposites was determined at 303 K, 313 K, and 323 K, respectively. The results indicated that the adsorption was spontaneous and endothermic. The MGO nanocomposites were conveniently separated from the media by an external magnetic field within several seconds, and then regenerated in 0.2 M NaOH solution. Thus, the MGO nanocomposites are a promising candidate for TBBPA removal from wastewater. 相似文献
15.
• 4-chlorophenol biodegradation could be enhanced in Fe2O3 coupled anaerobic system. • Metabolic activity and electron transport could be improved by Fe2O3 nanoparticles. • Functional microbial communities could be enriched in coupled anaerobic system. • Possible synergistic mechanism involved in enhanced dechlorination was proposed. Fe 2O 3 nanoparticles have been reported to enhance the dechlorination performance of anaerobic systems, but the underlying mechanism has not been clarified. This study evaluated the technical feasibility, system stability, microbial biodiversity and the underlying mechanism involved in a Fe 2O 3 nanoparticle-coupled anaerobic system treating 4-chlorophenol (4-CP) wastewater. The results demonstrated that the 4-CP and total organic carbon (TOC) removal efficiencies in the Fe 2O 3-coupled up-flow anaerobic sludge blanket (UASB) were always higher than 97% and 90% during long-term operation, verifying the long-term stability of the Fe 2O 3-coupled UASB. The 4-CP and TOC removal efficiencies in the coupled UASB increased by 42.9±0.4% and 27.5±0.7% compared to the control UASB system. Adding Fe 2O 3 nanoparticles promoted the enrichment of species involved in dechlorination, fermentation, electron transfer and acetoclastic methanogenesis, and significantly enhanced the extracellular electron transfer ability, electron transport activity and conductivity of anaerobic sludge, leading to enhanced 4-CP biodegradation performance. A possible synergistic mechanism involved in enhanced anaerobic 4-CP biodegradation by Fe 2O 3 nanoparticles was proposed. 相似文献
16.
Fe2O3-CeO2-Bi2O3/γ-Al2O3, an environmental friendly material, was investigated. The catalyst exhibited good catalytic performance in the CWAO of cationic red GTL. The apparent activation energy for the reaction was 79 kJ·mol−1. HO2· and O2·− appeared as the main reactive species in the reaction. ![]() The Fe 2O 3-CeO 2-Bi 2O 3/γ-Al 2O 3 catalyst, a novel environmental-friendly material, was used to investigate the catalytic wet air oxidation (CWAO) of cationic red GTL under mild operating conditions in a batch reactor. The catalyst was prepared by wet impregnation, and characterized by special surface area (BET measurement), X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS). The Fe 2O 3-CeO 2-Bi 2O 3/γ-Al 2O 3 catalyst exhibited good catalytic activity and stability in the CWAO under atmosphere pressure. The effect of the reaction conditions (catalyst loading, degradation temperature, solution concentration and initial solution pH value) was studied. The result showed that the decolorization efficiency of cationic red GTL was improved with increasing the initial solution pH value and the degradation temperature. The apparent activation energy for the reaction was 79 kJ·mol −1. Hydroperoxy radicals (HO 2·) and superoxide radicals (O 2−·) appeared as the main reactive species upon the CWAO of cationic red GTL. 相似文献
17.
• Size and shape-dependent MnFe2O4 NPs were prepared via a facile method. • Ligand-exchange chemistry was used to prepare the hydrophilic MnFe2O4 NPs. • The catalytic properties of MnFe2O4 NPs toward dye degradation were fully studied. • The catalytic activities of MnFe2O4 NPs followed Michaelis–Menten behavior. • All the MnFe2O4 NPs exhibit selective degradation to different dyes. The magnetic nanoparticles that are easy to recycle have tremendous potential as a suitable catalyst for environmental toxic dye pollutant degradation. Rationally engineering shapes and tailoring the size of nanocatalysts are regarded as an effective manner for enhancing performances. Herein, we successfully synthesized three kinds of MnFe 2O 4 NPs with distinctive sizes and shapes as catalysts for reductive degradation of methylene blue, rhodamine 6G, rhodamine B, and methylene orange. It was found that the catalytic activities were dependent on the size and shape of the MnFe 2O 4 NPs and highly related to the surface-to-volume ratio and atom arrangements. Besides, all these nanocatalysts exhibit selectivity to different organic dyes, which is beneficial for their practical application in dye pollutant treatment. Furthermore, the MnFe 2O 4 NPs could be readily recovered by a magnet and reused more than ten times without appreciable loss of activity. The size and shape effects of MnFe 2O 4 nanoparticles demonstrated in this work not only accelerate further understanding the nature of nanocatalysts but also contribute to the precise design of nanoparticles catalyst for pollutant degradation. 相似文献
18.
● Fe3O4 NPs increased the biomass and chlorophyll content of hemp clones. ● Fe3O4 NPs penetrated and were internalized by root cells. ● Fe3O4 NPs induced the alteration of metabolite profiles in hemp leaves. ● The psychoactive compound THC in hemp leaves was significantly down-regulated. We investigated the effect of iron oxide nanoparticles (Fe 3O 4 NPs, ~17 nm in size) on the phenotype and metabolite changes in hemp ( Cannabis sativa L.), an annual crop distributed worldwide. Hemp clones were grown in hydroponic cultures with Fe 3O 4 NPs (50, 100, 200, or 500 mg/L) for four weeks. TEM and ICP-MS were used to determine Fe 3O 4 NPs uptake and translocation. LC-MS-based metabolomics was employed to explore the deep insight into the effect of Fe 3O 4 NPs on hemp plants. The results revealed that plant growth enhanced gradually with increasing concentrations of given NPs up to 200 mg/L, which improved the fresh weight and dry weight by 36.13% and 74.68%, respectively, compared to the control. Even at a high dose (500 mg/L), Fe 3O 4 NPs promoted plant growth, including increased biomass and tissue length. NPs significantly increased the iron and chlorophyll content in plant tissues Increased catalase activity and reduced hydrogen peroxide content in hemp leaves suggested that the Fe 3O 4 NPs activated the defense system. TEM showed that NPs were abundantly attached to the cell wall and dispersed throughout the root cells. Metabolomics revealed that Fe 3O 4 NPs induced metabolic reprogramming in hemp leaves, including the up-regulation of carbohydrates and organic acids, and down-regulation of antioxidants, especially tetrahydrocannabinol (THC). The significantly up-regulated metabolites, including peonidin and 2-hydroxycinnamic acid, could be involved in photosynthesis in hemp plants. These results demonstrate the potential of Fe 3O 4 NPs for promoting hemp growth and decreasing the THC content at low doses. 相似文献
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