铁钛双金属共柱撑膨润土光催化-Fenton降解苯酚

 通过简单的离子交换方法成功合成了铁钛双金属共柱撑膨润土催化剂, 并利用 N2 吸附、X 射线衍射和等离子体发射光谱对所合成的样品进行了表征. 以苯酚为目标污染物, 考察了 pH 值、催化剂的投加量以及双氧水的加入量等对苯酚降解性能的影响. 结果表明, 在中性条件和紫外光照射下, 铁钛双金属柱撑膨润土上苯酚降解率和矿化率都高达 95%, 且铁离子的溶出率始终低于 2 mg/L, 均优于单一铁柱撑膨润土催化剂. 经过五次循环测试, 催化剂均表现出较高的活性. 即使在碱性 (pH = 9.0) 条件下, 反应 180 min 苯酚降解率也高达 70.3%, 表现出较好的酸碱适应性. 并讨论了双金属柱撑土所具有较大的比表面积和较强的表面酸性与活性之间的关系.     

炼化反渗透浓水中有机物处理技术

双膜工艺作为一种有效的废水处理方法,已被炼化企业广泛采用。然而,该工艺在使用过程中会产生一定量的含有机物高盐反渗透浓水(ROCs)。在国家排放标准对废水外排指标日趋严格的情况下,反渗透浓水直接外排已被禁止。因此,含有机物高盐反渗透浓水处理技术成为研究的热点。本文对炼化反渗透浓水处理技术研究进展进行综述和讨论。首先本文对不同炼化企业反渗透浓水的组成进行了汇总和分析; 其次,对反渗透浓水中有机物的去除技术,如物理化学方法、高级氧化法和生化方法等,进行了详细讨论,并深入分析了新兴高级氧化工艺的机理和优缺点; 最后对炼化反渗透浓水中盐回收技术进行了讨论。     

碘量法连续测定选矿废水中的铜铁

针对选矿废水中的铜离子和铁离子,在滴定铜离子含量的基础上,向滴定液中继续加入三氯化铝溶液作为解蔽剂将铁离子解蔽,此时溶液呈深棕色,以硫代硫酸钠标准溶液继续滴定铁,溶液深棕色消失转为奶白色即为滴定终点,避免了单独滴定铜铁含量的麻烦,且在滴定铁离子含量时无需除铜。经实验验证,对选矿废水中铁含量进行滴定与重铬酸钾滴定铁含量的结果一致,相对误差小于2.03%,加标回收率在95.8%~101.9%,相对标准偏差(RSD,n=10)在0.48%~1.5%。方法精密度高,重现性好,简便快捷,可以满足选矿废水中铜、铁含量的测定要求。     

新型仿生光催化剂HMS-FePcS催化降解孔雀绿的反应因素及动力学

在可见光照射下,应用合成的新型仿生光催化剂HMS-FePcS,催化降解孔雀绿模拟废水.考察了温度、光源强度、催化剂用量、过氧化氢用量以及金属活性中心(Fe,Cu和Co)等一系列因素对降解反应的影响,得到了优化的反应条件.在此基础上推导出孔雀绿光催化降解的反应级数及反应速率常数.该降解反应分两个阶段,初始反应的速率与反应物的浓度无关,呈现出零级反应的特征;而后一阶段的反应呈现一级反应的特征.两段反应均可用经典的Langmuir-Hinshelwood多相催化动力学模型进行合理的解释.     

Synthesis and Characterization of Cu Decorated Zeolite A@Void@Et-PMO Nanocomposites for Removal of Methylene Blue by a Heterogeneous Fenton Reaction

Hydrothermal synthesized nano zeolite A has been encapsulated with ethyl bridged periodic mesoporous organosilica(Et-PMO) shell tlirougli a simple modified Stober method and an organosilane-directed growth-induced etching strategy, the obtained yolk-shell structured A@Et-PMO nanocomposite(YS-A@Et-PMO) was further functionalized by the impregnation of copper ions, realizing the composite material with hierarchical porous and catalytic properties. The morphology and metal content of the Cu/A and Cu/YS-A@Et-PMO were fully characterized. As compared to tlie parent material, the composite Cu/YS-A@Et-PMO has an efficient adsorption and catalytic degradation performance on methylene blue(MB), the removal efficiency reached as high as 95% of 60 mg/L MB within 10 min. These novel structured porous composites may have great potential application for the removal of organic dye including waste effluents.     

过渡金属同晶替换的铁氧化物及其在非均相Fenton反应中的应用

过渡金属同晶替换的铁氧化物因其具有稳定、高效和可重复利用等特点而被广泛应用于催化处理难降解有机物领域。本文综述了这种新型催化剂的制备过程、过渡金属的同晶替换对催化剂物理化学性质(如比表面积、表面羟基数量、铁离子溶出量及热稳定性)的影响以及促进非均相Fenton反应的催化机制(氧化还原电对结构及氧空位理论)。本文还探讨了这种新型铁氧化物在难降解有机物处理中的应用进展,为后续研究提供了新的思路。     

非均相芬顿体系协同去除复合双污染物:化学转化,pH影响和机理分析

系统研究了ZVI(零价铁粉)-Fenton体系协同去除铜离子和亚甲基蓝(MB)污染物过程中, ZVI微表面发生的化学转化以及目标污染物降解机理. 分别利用扫描电子显微镜(SEM), X射线能谱(EDS), X射线衍射(XRD), X射线光电子能谱(XPS)和傅里叶变换红外光谱(FTIR)等技术, 对比分析了反应前后以及不同体系之间ZVI表面结构, Fe和Cu化学转移的变化. 结果表明, 在ZVI/H₂O₂体系中反应后ZVI表面腐蚀产物较多, 主要为Fe₃O₄和Fe₂O₃. 在ZVI/H₂O₂-Cu体系中, 虽ZVI腐蚀作用更加剧烈, 但ZVI表面残留的腐蚀产物较少, 且腐蚀产物中Fe₃O₄含量的占比增加. Cu ²⁺主要还原产物为Cu ⁰, 同时还伴随着CuO的生成. pH影响实验表明, ZVI/H₂O₂-Cu体系不仅强化了MB的降解, 有效地去除了总溶解铜离子(TCu), 同时还扩大ZVI-Fenton体系的有效pH范围(pH=2.5~5.5). 叔丁醇捕获自由基实验表明, 羟基自由基是氧化降解MB的主要活性物质. 最后针对ZVI-Fenton体系协同去除复合双目标污染物的机理进行研究分析.     

球磨微米硫化零价铁活化双氧水降解有机污染物的研究

报道了机械球磨方法制备的微米硫化零价铁（S-ZVI）可以快速活化H₂O₂降解各类有机污染物.S-ZVI/H₂O₂降解苯酚的单位比表面积反应速率常数是ZVI/H₂O₂的5倍以上,且苯酚的降解不存在初始抑制阶段.探针化合物乙醇的淬灭反应结合电子顺磁共振（EPR）实验证明S-ZVI/H₂O₂体系产生的氧化活性物质为·OH.反应前后S-ZVI颗粒的扫描电子显微镜（SEM）和X射线衍射（XRD）表征结合电化学测试和苯酚降解结果表明S-ZVI中FeS取代ZVI表面的钝化膜（铁氧化物）,加速了电子从Fe⁰传递到H₂O₂,更快地释放Fe²⁺,引发Fenton反应.在这过程中FeS主要作为电子的导体而非Fe²⁺的释放源.     

Removal of Phenol from Wastewater Using Date Seed Carbon

The adsorption of phenol on Date Seed Carbon (DSC) was investigated to assess its possible use as an adsorbent for the processing of phenolic wastewater. The influence of various factors such as initial concentration, agitation speed, amount of adsorbent and temperature on the adsorption capacity has been studied. The percentage removal of phenol was observed to increase with increase an initial concentration of phenol. The adsorption of phenol decrease with an increase in temperature indicated the exothermic nature of the reaction. The Langmuir and Freundlich equations interpret adsorption isothermal data. Kinetic data was obtained by using a pseudo‐second‐order equation to understand the reaction mechanism. Thermodynamic parameters such as ΔG, ΔH and ΔS for the adsorption process were calculated.     

层状CuyFe6-yAl2Ox催化剂的制备及其在罗丹明B降解反应中的应用

以铜铁铝水滑石为前驱体,经焙烧后得到了一系列不同组成的层状铜铁铝混合氧化物催化剂。将其应用于中性条件下高浓度罗丹明B(450 mg·L^-1)的类芬顿降解反应中,考察了催化剂中铜铁比例及焙烧温度对其降解性能的影响。实验结果表明,当铜铁物质的量之比为5∶1、焙烧温度为500℃时所得到的Cu5FeAl2Ox-500催化剂对罗丹明B的降解效率最高,能够在150 min内将罗丹明B完全降解。表征结果发现,Cu5FeAl2Ox-500催化剂中生成了新的CuFe2O4物相,而且具有较大的比表面积和介孔体积,因而有利于罗丹明B的降解。同时还发现该催化剂对多种污染物的降解均有很好的效果。     

Synthesis of Iron Nanometallic Glasses and Their Application in Cancer Therapy by a Localized Fenton Reaction

Metallic glasses and cancer theranostics are emerging fields that do not seem to be related to each other. Herein, we report the facile synthesis of amorphous iron nanoparticles (AFeNPs) and their superior physicochemical properties compared to their crystalline counterpart, iron nanocrystals (FeNCs). The AFeNPs can be used for cancer theranostics by inducing a Fenton reaction in the tumor by taking advantage of the mild acidity and the overproduced H₂O₂ in a tumor microenvironment: Ionization of the AFeNPs enables on‐demand ferrous ion release in the tumor, and subsequent H₂O₂ disproportionation leads to efficient ^.OH generation. The endogenous stimuli‐responsive ^.OH generation in the presence AFeNPs enables a highly specific cancer therapy without the need for external energy input.     

Simultaneous Removal of Antibiotics and Heavy Metals with Poly(Aspartic Acid)-Based Fenton Micromotors

The discharge of diverse pollutants has led to a complex water environment and posed a huge health threat to humans and animals. Self-propelled micromotors have recently attracted considerable attention for efficient water remediation due to their strong localized mass transfer effect. However, a single functionalized component is difficult to tackle with multiple contaminants and requires to combine different decontamination effects together. Here, we introduced a multifunctional micromotor to implement the adsorption and degradation roles simultaneously by integrating the poly(aspartic acid) (PASP) adsorbent with a MnO₂-based catalyst. The as-prepared micromotors are well propelled in contaminated waters by MnO₂ catalyzing hydrogen peroxide. In addition, the catalytic ramsdellite MnO₂(R-MnO₂) inner layer is decorated with Fe₂O₃ nanoparticles to improve their catalytic performance, contributing to an excellent degradation ability with 90% tetracycline (TC) removal in 50 minutes by enhanced Fenton-like reactions. Combining the attractive adsorption capability of poly (aspartic acid) (PASP), the composite micromotors offer an efficient removal of heavy metal ions in short time. Moreover, the designed micromotors are able to simultaneously remove antibiotic and heavy metals in mixed contaminants circumstance just in single treatment. This multifunctional micromotor with distinctive decontamination ability exhibits a promising prospective in treating multiple pollutants in the future.     

Inorganic Ion Exchangers for Cesium Removal from Radioactive Wastewater

Ion exchange is a proven process for radioactive wastewater decontamination, where inorganic sorbents are ideal due to their thermal, chemical and radiation stability. This review focuses on the removal of Cs⁺ by inorganic exchangers, viz. zeolites, titanosilicates, hexacyanoferrates metal oxides and hydrous metal oxides, bentonite/clays and the key family of ammonium phosphomolybdates (AMPs). The design of new selective composites is also addressed focusing on those based on AMPs, hexacyanoferrates and titanosilicates/zeolites. Future inorganic Cs⁺ exchangers will encompass promising solids, like lanthanide silicates, sodium titanates and metal sulfides. The sensing ability derived from the photoluminescence properties of lanthanide silicates and the efficiency of layered gallium-antimony-sulfide materials in acidic and basic solutions disclose considerable potential for real applications. The ion exchange systems are discussed in terms of sorbent capacity and selectivity (with competitors), pH, temperature and solution salinity. The microscopic features of the exchangers and the associated mechanisms (e.g., pore size, counterions radii, dehydration energy of the ions, coordination environments in the solid exchanger, and site accessibility) are always used for interpreting the ion exchange behavior. On the whole, more than 250 publications were reviewed and a large compilation of data is provided in Supplemental Material.     

High-Selectivity Pervaporation Membranes for 1-Butanol Removal from Wastewater

Russian Journal of Applied Chemistry - Possibility of using polydecylmethylsiloxane in the pervaporation removal of organic compounds from aqueous media was examined. It was shown for the example...     

高浓度含酚废水中酚类的转化回收及脱除

以含量30 g/L的苯酚水溶液为模型,提出氯化联合氧化工艺,实现对高浓度含酚废水中苯酚的转化回收及残余酚类的氧化脱除。 首先以pH值作为指示,向溶液中引入足够量的氯离子和氢离子,通过加入氯酸钠与之反应定量产生氯气;在所控制的实验条件下,氯气与溶液中的苯酚选择性反应转化为低溶解度的三氯苯酚沉淀,经气相色谱-质谱（GC-MS）面积归一法测得其含量可达97.76%;过滤所得滤液化学需氧量（COD）降低至1125 mg/L,苯酚回收率约98.7%。 采用Fenton氧化技术对该滤液进行氧化降解,结果表明,在优化的实验条件pH=3、Fe2+浓度为1 mmol/L下,H2O2用量为15 mL/L时,残余的氯酚类即可以被有效降解,降解后的水样经调碱性将铁或亚铁离子沉淀后为无色透明的溶液;联合处理后,水样COD减小到52 mg/L,该值满足国家工业污水排放标准。     

高浓度甲醛废水预处理工艺研究

采用“尿素缩合-粉煤灰吸附-Fenton氧化”复合工艺来处理高浓度甲醛废水,对影响甲醛去除率的因素进行了试验探讨,并确定了工艺优化条件．用该工艺处理高浓度甲醛废水,甲醛的总去除率可达到99％以上,能满足最终生化处理的要求．     

A Novel,Efficient and Facile Method for the Template Removal from Mesoporous Materials

A new catalytic-oxidation method was adopted to remove the templates from SBA-1 5 and MCM-4 1 me- soporous materials via Fenton-like techniques under microwave irradiation. The mesoporous silica materials were treated with different Fenton agents based on the template＇s property and textural property. The samples were cha- racterized by powder X-ray diffraction（XRD） measurement, N2 adsorption-desorption isotherms, infrared spectro- scopy, 29Si MAS NMR and thermo gravimetric analysis（TGA）. The results reveal that this is an efficient and facile approach to the thorough template-removal from mesoporous silica materials, as well as to offering products with more stable structures, higher BET surface areas, larger pore volumes and larger quantity of silanol groups.     

Removal of the Harmful Nitrate Anions from Potable Water Using Different Methods and Materials,including Zero-Valent Iron

Drinking water containing nitrate ions at a higher concentration level of more than 10 mg/L, according to the World Health Organization (WHO), poses a considerable peril to humans. This danger lies in its reduction of nitrite ions. These ions cause methemoglobinemia during the oxidation of hemoglobin into methemoglobin. Many protocols can be applied to the remediation of nitrate ions from hydra solutions such as Zn metal and amino sulfonic acid. Furthermore, the electrochemical process is a potent protocol that is useful for this purpose. Designing varying parameters, such as the type of cathodic electrode (Sn, Al, Fe, Cu), the type of electrolyte, and its concentration, temperature, pH, and current density, can give the best conditions to eliminate the nitrate as a pollutant. Moreover, the use of accessible, functional, and inexpensive adsorbents such as granular ferric hydroxide, modified zeolite, rice chaff, chitosan, perlite, red mud, and activated carbon are considered a possible approach for nitrate removal. Additionally, biological denitrification is considered one of the most promising methodologies attributable to its outstanding performance. Among these powerful methods and materials exist zero-valent iron (ZVI), which is used effectively in the deletion process of nitrate ions. Non-precious synthesis pathways are utilized to reduce the Fe²⁺ or Fe³⁺ ions by borohydride to obtain ZVI. The structural and morphological characteristics of ZVI are elucidated using UV–Vis spectroscopy, zeta potential, XRD, FE-SEM, and TEM. The adsorptive properties are estimated through batch experiments, which are achieved to control the feasibility of ZVI as an adsorbent under the effects of Fe⁰ dose, concentration of NO₃⁻ ions, and pH. The obtained literature findings recommend that ZVI is an appropriate applicant adsorbent for the remediation of nitrate ions.