环境超声化学

环境超声化学利用超声空化效应分解液相污染物,属于高级氧化过程。介绍了环境超声化学的基本原理,包括超声空化理论、超声降解环境污染物机理及生成自由基反应。综述了近年来环境超声化学在污染物净化中的应用,对存在问题和发展趋势提出了见解。     

超声-光催化降解水中有机污染物

超声-光催化是一项近年发展起来的废水处理的新型高级氧化技术。该技术利用超声的空化效应、自由基效应以及机械效应强化光催化的催化效能,实现超声和光催化对水中有机污染物的协同降解。本文从水中有机污染物的超声-光催化降解机理、降解动力学、影响因素（光催化剂类型和投加量、超声频率和强度、溶液pH值、温度、反应物初始浓度、溶解性气体和离子强度）和反应器类型（悬浮型、固定床型）4个方面介绍了相关研究进展,提出了目前存在的主要问题,并展望了超声-光催化降解水中有机污染物的发展方向。     

聚合物材料空化效应研究进展

综述了聚合物基材料中的各种空化现象,对橡胶增韧聚合物体系中的空化现象进行了详细讨论.同时讨论了聚合物基材料的形态、结构等因素对空化效应的影响,介绍了各种空化现象的原因及其对材料性能的影响和作用机理.     

超声技术处理水中有机污染物

超声技术在处理水中有机污染物的应用近年来受到越来越多的关注.与常规处理方法相比,超声处理高效省时.超声技术对众多难处理有机污染物的降解是有效的.本文介绍了超声降解有机污染物原理、影响因素和各种方法,主要包括单独使用超声处理和超声与生物催化剂、化学氧化、吸附等其它技术的联用,综述了近年来利用超声技术处理水中有机污染物的研究进展,对存在问题和发展趋势提出了见解.     

超声-光催化降解有机污染物的研究进展

超声-光催化联合技术是近年来废水处理的新型高级氧化技术。该技术主要利用超声波和光催化降解联合产生的协同效应来提高有机污染物的降解效率。本文主要就目前国内外超声-光催化降解有机物的降解机理、影响因素(光催化剂的性能及投加量、超声频率、超声强度及声功率、pH、温度、离子强度、污染物的浓度、溶解气体和其它添加物)以及在废水处理方面的应用等方面进行了综述,并介绍了超声-光催化技术存在的主要问题,最后展望了该技术的发展前景。     

超声化学在生物医学中应用的研究进展

超声是一类频率超过人类听力上限的机械波,具有高能和高穿透性的特点,能穿透生物体软组织的阻碍,在其内部诱导发生化学反应.近年来,超声化学手段越来越多地被应用于生物医学的研究当中,并为生物医学的发展提供了新的着力点.本文从三个方面,即超声的机械化学作用、声敏剂辅助的超声化学和超声的空化效应,总结并综述了超声化学在生物医学领域应用的研究进展.     

五氯苯酚降解的超声诱导

人为或自然因素会导致挥发性或不挥发有毒有机物存在于饮用水中,这一现象 已成为国际上共同关心的问题。从长期对健康状况来说,即使不能辨别饮用水中的 味道和气味,但只要有十亿分之几毫克的有毒有机物存在,就足以使水不能饮用。 所以,废水处理刻不容缓。同废水处理相关的实验方法中,超声作为一种处理方法 ,早有报道,因为超声化学效应主要是空化,空化是自由基,特别是羟基自由基产 生的根源,而痉基自由基是强烈而非特殊的氧化物,它能迅速同水中化合物发生反 应。作者以五氯苯酚为模拟水样,分别用低频（16 kHz）和高频[（800 ± 1） kHz]以及其组合进行超声降解研究。研究表明复频降解效果最好,最差为低频。在 Fenton类试剂存在下,与Fenton类单独降解效果相比,复频则是它的20.93倍,高 频是它的4.9倍,低频与它几乎无变化。实验表明,频率组合对有机污染物的降解 是一条有效途径,但需要更进一步的研究。     

废水中有机污染物降解机理的研究方法

我国废水排放总量较大,且废水中含有的多种有机污染物一直是人类生命健康的潜在威胁,因此对废水处理的研究必不可少,而理解废水中有机污染物的降解机理是处理各种废水的基础.本综述概述了国内外针对各种有机污染物降解机理的研究方法,主要包括实验手段和计算模拟两大类.实验手段中主要采用光谱分析技术检测有机污染物降解过程中生成的中间产物,进而推测有机污染物的降解路径.但是由于实验条件和实验方法的不同,对于同种物质的降解机理研究,不同的实验结果存在着争议.基于量子化学计算、定量构效关系模型（QSAR）、定量结构-生物降解性能关系模型（QSBR）、统计分子碎化模型（SMF）等计算模拟方法为有机污染物降解机理的研究提供了新的方法.将实验手段和计算模拟有机结合起来,可为有机污染物的降解机理研究提供参考和指导.     

高分子填料在生物法处理废水中的应用进展

对生物法处理废水用的高分子填料进行了综述。首先,从无机高分子填料、有机高分子填料两方面介绍了其应用特点及对废水中有机物的作用机理和去除效果;其次,介绍了新型生物填料,主要从生物亲和亲水磁性填料和酶促生物填料两方面介绍其在废水处理中的应用。     

有毒有机污染物光化学降解及机理研究

水环境污染已成为全球性普遍关注的重要课题.Fenton氧化法和Fenton光化学氧化法由于它在处理废水中的有毒有机污染物方面呈现了其它处理方式不能取代的特点而具有广阔的应用前景.虽然Fenton氧化法是一种非常有效的废水处理方法,但是由于体系中大量的铁离子的存在,使得处理后的体系带有颜色,且沉降铁泥的处理大大增加了运行成本.此外,Fenton反应一般需要在pH小于3的酸性介质中进行及在反应过程中过氧化氢的利用率不高等不足都限制了该方法的广泛应用.在本文中,我们用铁络合物代替Fenton反应中的铁离子并首次把可见光引入到反应体系中氧化降解有机污染物,着重研究了铁络合物在可见光照射下在均相和异相反应体系中对有毒有机污染物的光催化降解动力学、光化学反应机理、微环境的影响、活性自由基的形成以及光降解产物等方面内容,并得出以下几个重要结论:     

Characteristic analysis of cavitation bubbles in carbon dioxide fluid

After analysing the characteristics of bubble cavitation in high-pressure carbon dioxide (CO₂) fluid, cavitation conditions and some correlative physical characteristics are investigated. The results show that the ultrasonic intensity of liquid carbon dioxide to make cavitation occur is affected by the initial radius of the bubbles, hydrostatic pressure, temperature and vapour pressure within the bubbles in liquid CO₂. At the low frequency of ultrasound, the phase-speed of the liquid CO₂ gradually approaches the sound speed of the pure liquid when void fraction increases. At high frequency, the phase-speed is nearly equal to the sound speed in the liquid under different void fractions. The attenuation of ultrasound in liquid carbon dioxide reaches a maximum near the resonance frequency and then decreases when frequency either increases or decreases. At the resonance frequency, the phase-speed and the attenuation increase when the void fraction increases.     

Decomposition of Transformer Oil Under Ultrasonic Irradiation During Degassing Process

In the degassing process of transformer oil with ultrasonic waves ,decompostition of the oil was observed.Light hydrocarbons,including methane,ethane,ethylene ,aceylene,propane etc,were found to be released continuously from the oil into headspace within a closed vial placed in an ultrasonic field ,The gases came from decomposition of hydrocarbon molecules under cavitation effect.     

Ultrasonic Decomposition of Ammonia‐Nitrogen and Organic Compounds in Coke Plant Wastewater

The investigations of the ultrasonic decomposition of NH₃‐N and organic compounds (i.e., COD_Cr) in coke plant wastewater are presented in this work. The process parameters were controlled with respect to the presence (or absence) of air atmosphere, initial pH value, initial concentration, and ultrasonic power density in the process of ultrasonic decomposition. It is noted that the ultrasonic removal efficiencies for both the NH₃‐N and the COD_Cr were increased in the presence of the air atmosphere and significantly affected by the initial pH value. The removal efficiencies increased with increasing the ultrasonic power density while they decreased with increasing the initial concentration. The effects of n‐butyl alcohol as an effective OH radical scavenger on the removal efficiencies indicates that the ultrasonic decomposition of the NH₃‐N was carried out mainly via the mechanism of thermal decomposition in cavitation bubbles or in the interfacial region, whereas the ultrasonic decomposition of the COD_Cr mainly resulted from the reactions with OH radicals in the bulk solution. The GC/MS analysis indicates that most of the organic compounds in the wastewater were effectively destroyed by ultrasound.     

Effects of vapour pressure on the motion of cavitation bubble

Two models of bubble dynamics with constant vapour pressure and vapour content were newly developed. The mass flux of water vapour at bubble wall was simplified to facilitate the analysis. Based on these two models and the approximation of the mass flux, more simplified equations corresponding to the models were deduced from dynamic equation of bubble corrected by Sochard et al. MATLAB and the Runge–Kutta algorithm were applied to calculate and analyse the dynamical behaviour of cavitation bubbles under an ultrasonic field. Numerical results reveal that bubbles under the constant vapour pressure model exhibit larger amplitudes and move more violently to generate acoustic cavitation effect than the constant vapour content model. Nevertheless, the kinetic characteristics of bubbles under the constant vapour content model are similar to those of bubbles without water vapour. Moreover, vapour content exerts certain influence on the maximum radius, minimum radius and collapse intensity of bubbles.     

油田含油废水处理絮凝剂的研究与应用

对国内外石油和石化行业含油废水处理常用絮凝剂进行了综合评述，较详细地介绍了它们的种类，使用性能和近期研究及应用进展情况，与无机、有机絮凝剂相比，复合絮凝剂具有效率高、实用范围广等优点。未来含油废水处理絮凝剂应向无毒，易生物降解的天然高分子改性絮凝剂、微生物絮凝剂和兼具多种功能的水处理剂方向发展。     

壳聚糖及其衍生物处理工业废水的研究进展

综述了近年来壳聚糖及其衍生物在处理工业废水中的应用.壳聚糖及其衍生物可处理工业废水中的重金属离子,如Cr（Ⅵ）、Cu（Ⅱ）和Zn（Ⅱ）等;可处理含染料的工业废水,如处理直接紫B、直接绿BE以及甲基橙等染料;还可用于处理印染、造纸和含油废水.壳聚糖及其衍生物具有易分离、可生物降解,无污染等特点,是绿色的水处理剂,且我国壳聚糖资源极为丰富,探索其在工业废水处理中的应用有着重要的价值.     

Ultrasonic Mastering of Filter Flow and Antifouling of Renewable Resources

Inadequate access to pure water and sanitation requires new cost‐effective, ergonomic methods with less consumption of energy and chemicals, leaving the environment cleaner and sustainable. Among such methods, ultrasound is a unique means to control the physics and chemistry of complex fluids (wastewater) with excellent performance regarding mass transfer, cleaning, and disinfection. In membrane filtration processes, it overcomes diffusion limits and can accelerate the fluid flow towards the filter preventing antifouling. Here, we outline the current state of knowledge and technological design, with a focus on physicochemical strategies of ultrasound for water cleaning. We highlight important parameters of ultrasound for the delivery of a fluid flow from a technical perspective employing principles of physics and chemistry. By introducing various ultrasonic methods, involving bubbles or cavitation in combination with external fields, we show advancements in flow acceleration and mass transportation to the filter. In most cases we emphasize the main role of streaming and the impact of cavitation with a perspective to prevent and remove fouling deposits during the flow. We also elaborate on the deficiencies of present technologies and on problems to be solved to achieve a wide‐spread application.     

Physico-chemical approach to ultrasonic cavitation dynamics on ultrasonic cavitation from the viewpoint of sonochemical reactions

Summary The present theory treats ultrasonic cavitation as a train of expansion and contraction of a bubble, while most theories (e. g.Rayleigh's andGüth's) treated only contraction step.As a measure for the cavitation effect on sonochemical reaction, we used the reaction rateB mole l^–1 sec^–1. Especially in the case of ultrasonic depolymerisation of linear polymers we can use the final valueg of the degree of polymerisation besides initial rateB of depolymerisation.The theory can explain many experimental results of sonochemistry, e. g., effects of ultrasonic intensity and frequency, static pressure, size of bubble, gas in bubble, the kind of solvent, concentration of solution and temperature. The fact that the mono-disperse solution is easily obtained by ultrasonic depolymerisation can be explained, too.The use of two characteritic constantsB andg contributes also to the research on mechanism of cavitation, e. g., the existence of a prephenomenon, the significance of imperfect cavitation and the diagraming of conditions for cavitation.With 13 figures and 3 tables