以乙酸为模型反应物的Ti-Ce复合氧化物湿式氧化催化剂的研制

催化湿式氧化(catalytic wet air oxidation, CWAO)为高浓度难降解有机废水提供了一种有效可行的处理技术[1～8],它可使难降解有机物分子在相对较低的反应温与压力下降解矿化或生成易生物处理的小分子有机物.     

难降解有机废水的催化氧化法处理

催化氧化法可通过多种途径来加强传统的化学法处理效果，目前已成为难降解有机废水处理的一项重要新技术。本文介绍了光催化氧化法、均相氧化法、多相氧化法(包括电催化氧化法)以及超临界水氧化技术的国内外研究现状及特点，并对其在有机废水中的应用情况和发展前景作了扼要评述。     

电化学催化氧化降解含酚废水的研究进展

酚类化合物具有高毒性,难降解性,国内外研究者越来越重视含酚废水的治理.电化学催化氧化技术在降解酚类化合物方面的研究较多.作者深入探讨了电化学催化氧化技术降解酚类化合物的机理和历程,概述了一些常用阳极材料的优缺点,最后指出了该技术存在的一些问题与发展前景.     

Fe2+/UV催化臭氧-曝气生物滤池降解腈纶废水研究

腈纶废水是一种难降解的有毒有机废水。本文采用Fe2+/UV催化臭氧-曝气生物滤池降解腈纶废水,探讨了臭氧浓度和紫外光辐射强度等影响因素对腈纶废水的COD去除效果的影响,并考察了紫外催化臭氧氧化单元和曝气生物滤池单元对COD去除的协同作用。结果表明,臭氧浓度对COD的去除率影响较大,臭氧浓度下降25%时,臭氧催化氧化和曝气生物滤池单元处理的COD去除率分别下降了12.53%和15.98%。紫外光强度对臭氧催化氧化单元的COD去除率影响较小,但对曝气生物滤池单元影响较大。臭氧催化氧化单元和曝气生物滤池单元COD去除率之比为1∶2,其协同作用使总出水COD值稳定在较低水平。     

碳酸氢盐活化的过氧化氢:一种有机废水处理的新技术（英文）

水污染问题已成为影响我国可持续发展的关键问题之一,为有效提高现有污水处理的效率及其回收利用,各种催化氧化技术受到了广泛的关注.目前发展的各类高级氧化技术在实际的应用过程中明显受到了氧化剂的利用率、催化剂的浸出、寿命及成本等问题的严重限制.因此基于新的理念、发展新的催化氧化技术仍然受到广泛的关注.最近几年,利用碳酸氢盐活化过氧化氢,应用于有机废水的降解逐渐受到环境催化领域的关注.碳酸氢盐本身是一种低毒性、广泛存在于环境及生物体系的化学物质,通过它活化过氧化氢产生过碳酸氢盐氧化剂,该氧化剂能够直接氧化有机物.同时,在各种过渡金属催化剂的存在下,通过该过碳酸氢盐可以形成氧化能力更强的各种自由基(如羟基自由基等)及高价态的过渡金属离子参与有机废水的降解.虽然传统认为碳酸盐及碳酸氢盐对高级氧化法降解有机废水不利,原因是认为它们能捕捉羟基自由基,形成氧化能力更低的碳酸根自由基.现有的研究已充分表明,较低浓度的碳酸氢盐能够加快有机废水的氧化降解,而且通常比单独使用过氧化氢效率更高,这些新的发现已明显突破了传统意义上对碳酸氢盐作用的理解.更为重要的是,在微量碳酸氢盐的存在下,其产生的微碱性环境极大地消除了负载型氧化物催化剂在废水降解过程中的金属离子流失、从而极大地延长了催化剂的寿命.该缺点是各种基于过渡金属氧化物催化剂的高级氧化技术难以广泛推广的关键性挑战,原因是随着氧化降解的进行,废水体系由于有机酸的生成而逐渐酸化,进而引发氧化物催化剂的酸溶而流失.在这点上,碳酸氢盐活化过氧化氢系统由于其天然的微碱性环境体现出了其明显的优势.本文即是在本课题组工作基础上,对该领域内国内外研究进展加以总结,以期获得国内外同行的进一步关注.综述的主要内容包括:(1)碳酸氢氧活化过氧化氢的相关知识介绍,(2)均相碳酸氢氧活化过氧化氢降解有机废水的研究进展,(3)基于金属氧化物催化剂的碳酸氢氧活化过氧化氢降解有机废水的研究进展,和(4)碳酸氢盐在其他高级氧化技术中的应用.虽然基于碳酸氢氧活化过氧化氢降解有机废水的研究还处于早期探索阶段,还有很多基础科学问题如降解机理等值得进一步探索,期望通过该综述的介绍能够让同行对碳酸氢氧活化过氧化氢降解有机废水有一个比较全面的了解,进而推动该研究方向的发展,为有机废水的催化处理提供新的机会.     

漆酶催化氧化水中有机污染物*

漆酶是一种含铜的多酚氧化酶, 属于铜蓝氧化酶蛋白, 能催化氧化多种难降解的有机污染物。漆酶催化氧化水中有机污染物具有底物广泛、能耗低、易操作、环境友好等优点,是一项前景广阔的生物处理技术。本文综述了漆酶对水中有机污染物的催化降解,主要从漆酶的化学组成、结构、催化降解机理、漆酶的固定化、影响因素（溶液pH值、温度、金属离子、营养因子、有机溶剂、漆酶的浓度、底物的初始浓度等）、降解的动力学以及漆酶在处理水中有机污染物的应用等五个方面介绍了相关的研究进展。漆酶催化氧化有机物的机理主要表现在底物自由基中间体的产生和氧气还原成水两个方面。本文提出了目前漆酶催化氧化水中有机污染物存在的主要问题,并展望了漆酶降解水体中有机污染物的发展方向。     

碳酸氢盐活化的过氧化氢：一种有机废水处理的新技术

水污染问题已成为影响我国可持续发展的关键问题之一,为有效提高现有污水处理的效率及其回收利用,各种催化氧化技术受到了广泛的关注。目前发展的各类高级氧化技术在实际的应用过程中明显受到了氧化剂的利用率、催化剂的浸出、寿命及成本等问题的严重限制。因此基于新的理念、发展新的催化氧化技术仍然受到广泛的关注。
　　最近几年,利用碳酸氢盐活化过氧化氢,应用于有机废水的降解逐渐受到环境催化领域的关注。碳酸氢盐本身是一种低毒性、广泛存在于环境及生物体系的化学物质,通过它活化过氧化氢产生过碳酸氢盐氧化剂,该氧化剂能够直接氧化有机物。同时,在各种过渡金属催化剂的存在下,通过该过碳酸氢盐可以形成氧化能力更强的各种自由基(如羟基自由基等) 及高价态的过渡金属离子参与有机废水的降解。虽然传统认为碳酸盐及碳酸氢盐对高级氧化法降解有机废水不利,原因是认为它们能捕捉羟基自由基,形成氧化能力更低的碳酸根自由基。现有的研究已充分表明,较低浓度的碳酸氢盐能够加快有机废水的氧化降解,而且通常比单独使用过氧化氢效率更高,这些新的发现已明显突破了传统意义上对碳酸氢盐作用的理解。更为重要的是,在微量碳酸氢盐的存在下,其产生的微碱性环境极大地消除了负载型氧化物催化剂在废水降解过程中的金属离子流失、从而极大地延长了催化剂的寿命。该缺点是各种基于过渡金属氧化物催化剂的高级氧化技术难以广泛推广的关键性挑战,原因是随着氧化降解的进行,废水体系由于有机酸的生成而逐渐酸化,进而引发氧化物催化剂的酸溶而流失。在这点上,碳酸氢盐活化过氧化氢系统由于其天然的微碱性环境体现出了其明显的优势。
　　本文即是在本课题组工作基础上,对该领域内国内外研究进展加以总结,以期获得国内外同行的进一步关注。综述的主要内容包括：(1)碳酸氢氧活化过氧化氢的相关知识介绍,(2)均相碳酸氢氧活化过氧化氢降解有机废水的研究进展,(3)基于金属氧化物催化剂的碳酸氢氧活化过氧化氢降解有机废水的研究进展,和(4)碳酸氢盐在其他高级氧化技术中的应用。虽然基于碳酸氢氧活化过氧化氢降解有机废水的研究还处于早期探索阶段,还有很多基础科学问题如降解机理等值得进一步探索,期望通过该综述的介绍能够让同行对碳酸氢氧活化过氧化氢降解有机废水有一个比较全面的了解,进而推动该研究方向的发展,为有机废水的催化处理提供新的机会。     

臭氧氧化技术处理含抗生素废水*

本文详细介绍了臭氧氧化技术的基本原理,分析了臭氧投加量、反应温度、溶液pH值、UV、H₂O₂及催化剂等因素对臭氧氧化处理抗生素废水效果的影响。根据抗生素的不同分类,综述了近年来关于臭氧氧化技术处理β-内酰胺、大环内酯、磺胺、喹诺酮、四环素、氯霉素六类常见抗生素废水的研究进展,并展望了臭氧氧化处理抗生素等难降解有机废水的发展趋势以及所面临的主要问题。     

常温常压湿式催化氧化染料废水的Mo-Cu-Fe-O新型复合催化材料

染料广泛应用于纺织厂、皮革厂以及染发等各个领域.染料废水具有成分复杂、浓度高、色度大和生物难降解等特性,因此传统的处理方法难以将其完全降解.高级氧化技术已成为国内外广泛应用的染料废水处理技术之一,特别是湿式催化氧化(CWAO)技术.然而,CWAO工艺中反应往往需要高温(通常为200-280℃)和高压(通常为2-9 MPa),制约了其广泛应用.因此,人们致力于研发具有高催化活性的催化剂,通过改变反应历程和降低反应的活化能,使反应在常温常压条件下进行.本课题组曾采用钼酸盐浸渍于Zn/Al LDHs溶液中成功制备了Mo/Zn-Al LDHs催化剂,该催化剂能在常温常压下湿式催化氧化降解阳离子红GTL有机废水.Mo/Zn-Al LDHs催化剂中Mo作为主催化成分,Zn-Al LDHs作为载体.Cu-Fe LDHs本身作为一种催化剂,与Mo相结合能有效提高催化剂的活性及稳定性,因此本文采用浸渍法制备了Mo-Cu-Fe-O新型复合催化材料,采用X射线衍射、氢气程序升温还原、循环伏安法和氧气程序升温脱附等表征手段研究了Mo-Cu-Fe-O材料的结构及氧化还原特性.以阳离子红GTL、结晶紫和酸性红为染料废水代表,研究了常温常压下Mo-Cu-Fe-O催化降解染料废水的催化活性.结果表明,在中性条件下Mo-Cu-Fe-O对阳离子型染料废水具有良好的催化活性.循环使用七次后该样品对阳离子红GTL和酸性红的脱色率分别达到91.5%和92.8%,然而对酸性红阴离子型染料废水基本无催化活性.在常温常压CWAO过程中产生的羟基自由基能有效降解阳离子GTL废水,其废水毒性随着反应的进行逐渐减小.     

常温常压湿式催化氧化染料废水的Mo-Cu-Fe-O新型复合催化材料（英文）

染料广泛应用于纺织厂、皮革厂以及染发等各个领域.染料废水具有成分复杂、浓度高、色度大和生物难降解等特性,因此传统的处理方法难以将其完全降解.高级氧化技术已成为国内外广泛应用的染料废水处理技术之一,特别是湿式催化氧化(CWAO)技术.然而,CWAO工艺中反应往往需要高温(通常为200-280°C)和高压(通常为2-9 MPa),制约了其广泛应用.因此,人们致力于研发具有高催化活性的催化剂,通过改变反应历程和降低反应的活化能,使反应在常温常压条件下进行.本课题组曾采用钼酸盐浸渍于Zn/Al LDHs溶液中成功制备了Mo/Zn-Al LDHs催化剂,该催化剂能在常温常压下湿式催化氧化降解阳离子红GTL有机废水.Mo/Zn-Al LDHs催化剂中Mo作为主催化成分,Zn-Al LDHs作为载体.Cu-Fe LDHs本身作为一种催化剂,与Mo相结合能有效提高催化剂的活性及稳定性,因此本文采用浸渍法制备了Mo-Cu-Fe-O新型复合催化材料,采用X射线衍射、氢气程序升温还原、循环伏安法和氧气程序升温脱附等表征手段研究了Mo-Cu-Fe-O材料的结构及氧化还原特性.以阳离子红GTL、结晶紫和酸性红为染料废水代表,研究了常温常压下Mo-Cu-Fe-O催化降解染料废水的催化活性.结果表明,在中性条件下Mo-Cu-Fe-O对阳离子型染料废水具有良好的催化活性.循环使用七次后该样品对阳离子红GTL和酸性红的脱色率分别达到91.5%和92.8%,然而对酸性红阴离子型染料废水基本无催化活性.在常温常压CWAO过程中产生的羟基自由基能有效降解阳离子GTL废水,其废水毒性随着反应的进行逐渐减小.     

Fe-Mn-Cu-Ce/Al2O3 as an efficient catalyst for catalytic ozonation of bio-treated coking wastewater: Characteristics,efficiency, and mechanism

It is important to develop a catalyst that has high catalytic activity and can improve the degradation efficiency of refractory organic pollutants in the catalytic ozonation process. In this study, Fe-Mn-Cu-Ce/Al₂O₃ was synthesised via impregnation calcination for catalytic ozonation of bio-treated coking wastewater. The physical and chemical characteristics of the catalysts were analysed using X-ray diffraction (XRD), X-ray fluorescence spectrometry (XRF), X-ray photoelectron spectroscopy (XPS), scanning electron microscopy (SEM), and Brunauer–Emmett–Teller nitrogen adsorption–desorption methods. The effects of catalyst dosage, pH, and reflux ratio on the degradation efficiency of wastewater were examined in laboratory-scale experiments. The chemical oxygen demand (COD) removal rate of bio-treated coking wastewater was estimated to be 52.76 % under optimal conditions. The experiments on the catalytic mechanism demonstrated that the surface hydroxyl formed by the Lewis acid sites on the surface of the catalyst can react with ozone as the active site forming the active oxygen (·OH, ·O₂^–, and ¹O₂), thereby efficiently degrading the organic pollutants in coking wastewater. Furthermore, a pilot-scale experiment on the catalytic ozonation of bio-treated coking wastewater was carried out using an Fe-Mn-Cu-Ce/Al₂O₃ catalyst, while the effects of the initial pollutant concentration, ozone concentration, and gas flow on the COD removal rate were studied on a pilot scale. It was found that the COD removal rate of the wastewater was ～ 60 % under optimal parameters. After the treatment, the wastewater steadily reached the coking wastewater discharge standard (COD < 80 mg/L), while the operating cost of catalytic ozonation reached ～ 0.032$/m³, thereby paving the way toward economic engineering applications. The COD degradation kinetics in the bio-treated coking wastewater followed pseudo-second-order kinetics. Three-dimensional fluorescence and gas chromatography–mass spectrometry revealed that macromolecular organic pollutants in the bio-treated coking wastewater were greatly degraded. In summary, Fe-Mn-Cu-Ce/Al₂O₃ exhibited good reusability, high catalytic activity, and low cost and has a wide application prospect in the treatment of coking wastewater.     

Analysis of sulphonated polyphenols, synthetic tanning agents in heavily polluted tannery wastewaters

A method is presented for the analysis of sulphonated polyphenols, acting as synthetic tanning agents, in heavily polluted tannery wastewater. It consists of ion-pair solid-phase extraction (RP-18) with tetrabutylammonium bromide followed by reversed-phase ion-pair liquid chromatography on a C₁₈ stationary phase with UV detection. The detection limit is 15 μg/1. The influence of the wastewater matrix on extraction and the effects of pH and temperature on the HPLC separation are discussed. The procedure is not affected by the high contents of dissolved organic carbon and inorganic salts of tannery wastewater. The tannery effluents investigated contained around 40 mg/1 of sulphonated polyphenols. These compounds appear to be refractory against both anaerobic and aerobic biological wastewater treatment. They might, thus, contribute to the dissolved organic sulphur content of surface waters.     

Recent advances in persulfate-based advanced oxidation processes for organic wastewater treatment

In recent years, with the emergence of new pollutants, the effective treatment of wastewater has become very important. Persulfate-based advanced oxidation processes have been successfully applied to the treatment of wastewater, such as wastewater containing antibiotics, pharmaceuticals and personal care products, dyes, endocrine-disrupting chemicals, chlorinated organic pollutants, and phenolics, for the degradation of refractory organic contaminants. This paper summarizes the production of sulfate radicals, which can be generated by the activation of persulfate via conventional and emerging approaches. The existing problems of persulfate-based advanced oxidation processes were analyzed in detail, including residual sulfates, coexisting factors (coexisting inorganic anions and natural organic matter), and energy consumption. This paper proposes corresponding possible solutions to the problems mentioned above, and this paper could provide a reference for the application of persulfate-based advanced oxidation processes in actual wastewater treatment.     

Minireview: Silver-Doped Titanium Dioxide and Silver-Doped Zinc Oxide Photocatalysts

The catalytic oxidation of organic dyes using various systems has been widely reported during the past decade. Photocatalytic methods, heterogeneous processes for the degradation of dyes, are one of the best and efficient oxidation processes to treat industrial wastewater with minimal residual waste. This review describes the improvement in catalytic activity of silver-doped titanium dioxide and silver-doped zinc oxide. The degradation of dyes provides information about the catalytic performance of silver-doped metal oxide. The effects of pH, catalyst concentration, dye concentration, hydrogen peroxide, dissolved oxygen, temperature, irradiation time, and light source have been reviewed along with the degradation mechanism and reaction methodology of organic dyes.     

湿式氧化用于染料废水脱色:过去20年回顾（英文）简

Wet air oxidation (WAO), a liquid phase reaction between organic materials in water and oxygen, is one of the most economical and technologically viable advanced oxidation processes for wastewater treatment, particularly toxic and high organic content wastewater. WAO is the liquid phase oxidation of organics or oxidizable inorganic components at elevated temperatures (125-320℃) and pressures (0.5-20 MPa) using gaseous oxygen (or air) as oxidant. In the past two decades, the WAO process was widely studied and applied in the treatment of dye wastewater. Compared to conventional WAO, catalytic WAO processes have higher efficiency and use moderate reaction conditions. The catalysts included homogenous and heterogeneous types. The key points that need to be solved are recycling of homogenous catalysts and better stability of heterogeneous catalysts. In the present review, the technological processes are first introduced, then some research history and hotspots of WAO research are presented, and finally, its application in the treatment of dye wastewater in the past two decades is summarized to reveal the impressive changes in modes, trends, and conditions used. The application includes model pollutant studies and wastewater tests.     

Advances in Template Prepared Nano‐Oxides and their Applications: Polluted Water Treatment,Energy, Sensing and Biomedical Drug Delivery

The nano‐oxide materials with special structures prepared by template methods have a good dispersion, regular structures and high specific surface areas. Therefore, in some areas, improved properties are observed than conventional bulk oxide materials. For example, in the treatment of dye wastewater, the treatment efficiency of adsorbents and catalytic materials prepared by template method was about 30 % or even higher than that of conventional samples. This review mainly focuses on the progress of inorganic, organic and biological templates in the preparation of micro‐ and nano‐ oxide materials with special morphologies, and the roles of the prepared materials as adsorbents and photocatalysts in dye wastewater treatment. The characteristics and advantages of inorganic, organic and biological template are also summarized. In addition, the applications of template method prepared oxides in the field of sensors, drug carrier, energy materials and other fields are briefly discussed with detailed examples.     

Degradation of p-aminophenol wastewater using Ti-Si-Sn-Sb/GAC particle electrodes in a three-dimensional electrochemical oxidation reactor

In this study, Ti-Si-Sn-Sb/GAC particle electrodes were prepared by sol–gel method. The particle electrodes were characterized by SEM, XRD, EDX, and BET then used to carry out three-dimensional (3D) electrocatalytic oxidation degradation on simulated refractory p-aminophenol (PAP) wastewater. The effects of initial pH, cell voltage, aeration flow rate and initial PAP concentration on degradation experiments were investigated. Under the optimal conditions, the PAP and COD removal rates were 89.45% and 75.17% respectively. In addition, the possible degradation mechanism of PAP was further investigated by UV–Vis and HPLC. Finally, it was found that the Ti-Si-Sn-Sb/GAC particle electrodes with high catalytic activity and excellent stability could significantly improve the PAP wastewater removal efficiency.     

Adsorption studies of tannic acid by commercial ester resin XAD-7

<正>Tannic acid and its related compounds are known as refractory organic pollutants,and it can create serious problems for the environment.The adsorption and desorption studies of tannic acid on commercial resins XAD-7 and D-201 are performed,and all data indicates resin XAD-7 can be used as an effective adsorbent for removing tannic acid during water/wastewater treatment.Furthermore,adsorption thermodynamics studies indicate different adsorption mechanisms for TA on XAD-7 and D-201.FT-IR and solid state ~(13)C-NMR spectroscopy are used to explain the adsorption force between XAD-7 and TA.It suggests that hydrogen bonding is the main adsorption force for TA.Finally,XAD-7's adsorption capacity in the presence of different metal ions is investigated,which indicates that heavy metal ions in solutions can decrease the adsorption capacity for TA on ester resin XAD-7.     

A TiO2-nanotube-array-based photocatalytic fuel cell using refractory organic compounds as substrates for electricity generation

A TiO(2)-nanotube-array-based photocatalytic fuel cell system was established for generation of electricity from various refractory organic compounds and simultaneous wastewater treatment. The present system can respond to visible light and produce obviously enhanced cell performance when a narrow band-gap semiconductor (i.e. Cu(2)O and CdS) was combined with TiO(2) nanotubes.