微波密封消解法快速测定CODcr

标准法──重铬酸钾法测定ＣＯＤＣｒ的缺点是测定时间长，氯离子干扰大。微波密封消解法对此进行了改进。实验结果表明，该法具有消解时间短，减轻了二次污染，准确度高，精密度好等优点，可同标准回流法等效使用。     

利用毛细管气相色谱法测定水和废水中的丙烯酰胺

本文采用毛细管色谱法建立了水和废水中丙烯酰胺的测定程序。以活性炭柱吸附、浓缩样品中的丙烯酰胺，用甲醇洗脱，洗脱液用FID测定。方法回收率为83．1～99．0％，相对标准偏差为5．34％，检出限为0．016mg／L。     

射流曝气周期活性污泥法脱氮除磷研究

针对零星居民点的污水处理,开发了射流曝气周期活性污泥法工艺.它是一种连续进水、周期性间歇曝气的改良型SBR工艺,也是一种时间程序和空间程序相结合的污水处理工艺,具有良好的脱氮除磷效果.试验表明,在水力负荷4 m3/d,曝气周期为每2 h曝气15 min、静置105 min的条件下,出水COD为48.8～53.5 mg/L,去除率达79.4%～80.5%;出水TN为2.81～3.98 mg/L,去除率达82.4%～89.4%;出水NH3-N为0.36～0.78 mg/L,去除率高达96.4%～98.4%;出水TP为0.63～1.18 mg/L,去除率为67.2%～78.9%,均可达到《城镇污水处理厂污染物排放标准》(GB 18918-2002)中的一级B排放标准.     

水中可吸附有机氯(AOCl)的测定——离子色谱法

采用自制的燃烧装置,使吸附在活性炭上的有机氯定量地转化为无机氯,经硼砂双氧水溶液吸收,用离子色谱法分离测定。当富集水样的体积为５０～２００ｍｌ时,可测定可吸附有机氯（ＡＯＣｌ）的范围为２８～１０００μｇ／Ｌ。当样品中ＡＯＣｌ含量在１６～６４μｇ时,平均加标回收率大于９０％,相对标准偏差小于１０％。用该方法还可同时测定水中可吸附有机硫。     

固相微萃取-气相色谱法测定饮用水及其水源水中的氯酚

利用固相微萃取(SPME)-气相色谱法(GC)联用技术测定饮用水及其水源水中的氯酚．优化萃取温度、萃取平衡时间、酸度、离子强度等实验条件．所建方法简便、精确,自来水和太湖水中均检测到氯酚。     

固相萃取-气相色谱/质谱法测定水中多环芳烃

建立了固相萃取-气相色谱／质谱联用测定水中多环芳烃(PAHs)的分析方法．优化了固相萃取条件。结果表明,固相萃取效率高、萃取时间短,采用MS的选择离子检测方式对实际水样中PAHs进行定性定量分析,平均回收率在80．4％～115％之间,相对标准偏差为7．03％～18．5％,方法的检出限在0．010～0．020μg／L之间。通过实际样品中PAHs的分析表明,该法快速,溶剂用量少,能满足痕量分析的要求。     

GC-MS法测定饮用水源水中半挥发性有机物

用固相萃取的方法对样品进行预处理,再进行GC-MS分析测定,对饮用水源水中的痕量半挥发性有机化合物进行了测定,并对结果进行了讨论。     

湿法消解-原子荧光光谱法同时测定地表水中的砷和汞

为提高检测效率、降低检测成本、提高检测的准确性,采用硝酸消解水样,断续流动进样,在KBH_4-酸体系中、最佳的仪器试验条件下,用原子荧光光谱法同时测定地表水中的砷和汞。实验结果表明:砷、汞检出限分别为0.109、0.0026μg/L,线性范围分别为0～40μg/L和0～2μg/L,精密度都是1.4%,加标回收率分别为93.5%～107%和96.0%～104%。表明该检测方法检出限低、干扰性小、精密度高、测定结果稳定,能够满足地表水中砷和汞同时测定要求。     

Combination of ion exchange system and biological reactors for simultaneous removal of ammonia and organics

A novel process for a simultaneous removal of ammonia and organics was developed on the basis of ion exchange and biological reactions. From batch experiments, it was found out that NH₄⁺ could be removed effectively by combining cation exchange and biological nitrification showing 0.98 mg N/m²?s of a maximum flux. On the other hand, the removal of NO₃⁻ was 3.5 times faster than NH₄⁺ and the maximum flux was calculated to be 3.4 mg N/m²?s. The systems for NH₄⁺ and NO₃⁻ removal were combined for establishing the IEBR process. When the process was operated in a continuous mode, approximately 95.8% of NH₄⁺ was removed showing an average flux of 0.22 mg N/m²·s. The removal efficiency of total nitrogen was calculated as 94.5% whereas that of organics was 99.5%. It was concluded that the IEBR process would be effectively used for a simultaneous removal of NH₄⁺ and organics.     

Hydroxyl, hydroperoxyl free radicals determination methods in atmosphere and troposphere

The hydroxyl radical (?OH) has a crucial function in the oxidation and removal of many atmospheric compounds that are harmful to health. Nevertheless, high reactivity, low atmospheric abundance, determination of hydroxyl, and hydroperoxyl radical's quantity is very difficult. In the atmosphere and troposphere, hydroperoxyl radicals (HO₂) are closely demanded in the chemical oxidation of the troposphere. But advances in technology have allowed researchers to improve the determination methods on the research of free radicals through some spectroscopic techniques. So far, several methods such as laser-induced fluorescence (LIF), high-performance liquid chromatography (HPLC), and chemical ionization mass spectroscopy have been identified and mostly used in determining the quantity of hydroxyl and hydroperoxyl radicals. In this systematic review, we have advised the use of scavenger as an advance for further researchers to circumvent some of these problems caused by free radicals. The primary goal of this review is to deepen our understanding of the functions of the most critical free radical (?OH, HO₂) and also understand the currently used methods to quantify them in the atmosphere and troposphere.