镀金石英砂吸附-AMA 254测汞仪测定大气中痕量汞的研究

采用镀金石英砂来富集大气中的气态总汞,AMA 254测汞仪测定。结果表明,不同采样时间下的单级吸附管的吸附效率均在90%以上,采样40min时的相对标准偏差为5%左右。与巯基棉吸附和吸收液吸收方法的对比显示,该方法具有吸收效果好、多次采样的精密度高、操作简便并且可以再生重复使用等优点。运用该法,对徐家汇等几个地点的大气总汞进行了测定。     

金汞齐富集—冷原子吸收法测定大气中的微量汞

本文介绍了大气中微量汞的一种监测方法,利用汞富集解析器富集大气中的微量汞.解析后用冷原子吸收法测定.研究了FJ-1型汞富集解析器与WYX-405原子吸收分光光度计联用的工作条件,相对标准偏差为1.7％.     

离子色谱法同时测定大气中二氧化硫和氮氧化物

建立以2.2mmol/L的Na2CO3和2.7mmol/L的NaHCO3的混合溶液为吸收液,同时串联两个大气采样瓶采样,第一个采样瓶的吸收液内含质量体积比为0.05%的乙二胺四乙酸二钠盐(EDTA)吸收大气中SO2和NO2,第二个采样瓶的吸收液中内舍质量体积比为0.9%的过氧化氢采集大气中的NO,采样后用离子色谱法测定,若用10ml吸收液,采样体积为30L时,SO2的检出限为0.004mg/m3,可测浓度范围为0.03～26.7mg/m3;NO2的检出限为6.7×10-4mg/m3,可测浓度范围为0.03～20mg/m3.方法简便快速、准确、选择性好,完全满足环境监测对大气中二氧化硫和氮氧化物的同时测定.     

二氧化硫手工连续采样方法研究

方法一 四氯汞钾吸收液—盐酸付玫瑰苯胺比色法 本法检测限为0.30μg SO_2/10ml。 一、仪器: 1.吸收瓶:75ml多孔玻板吸收瓶。 2.大气采样器:流量范围0～1L/min,湖北省环保仪器研究所生产的成套设备。 3.72分光光度计。 二、采样: 用一个内装50ml吸收液的多孔玻板吸收瓶,以0.2L/min流量,从8:00至次日8:00,采样时间24±0.5小时,采样体积约为288L。记录采样口的温度、压力。采样后,将样品带回实验室分析,或保存在冰箱里,一周后一起分析。     

乙二羟肟酸溶液吸收法测定大气中的二氧化硫

本文讨论了乙二羟肟酸溶液吸收——盐酸副玫瑰苯胺比色测定大气中的二氧化硫的方法。该法采样效率为98.8％,精密度为3.73％,平均回收率为98.7％,在室温下,样品至少可稳定4天。该法测定结果与四氯汞钠溶液吸收法无显著性差异。     

大气中不同形态汞的采集和分析方法

作为一种环境优先污染物,汞对人体和其它生物毒性很大。大气是全球汞生物地球化学循环的重要场所。不同形态的汞由于理化性质不同,迁移转化过程及其对生态环境的影响也不同,准确测定大气环境中各种形态的汞对于了解其在大气中的行为具有重要意义。1990年以来,大气汞的采集和分析方法技术已经取得了长足进步,一些自动测汞仪、低汞空白和高时间分辨率的采样及分析技术相继出现,使得准确测定大气中不同形态的痕量汞成为可能。文章就国内外近10多年来在这些方面所取得的研究进展进行了回顾和总结,主要介绍了气态总汞、颗粒态汞、活性气态汞、甲基汞等的采集和分析方法。     

关于大气采样效率的含义、测定和应用

一、大气采样效率的提出:大气样品采样方法通常有三种:直接采样法、富集采样法和无动力采样法.第一种方法适合于大气中某污染物含量较高的测定,可直接以注射器、采气袋或采气管等进行采样;第三种方法则不需以任何动力,根据污染物的某些性质,使大气中的某污染物直接与试纸或采样用滤纸上某物质发生物理的或化学的反应,得到可供测定用的样品;第二种方法富集采样法,也称浓缩采样法,则适合于大气中某污染物含量较低的测定,用得较多的是溶液吸收法,其次是固体阻留法,而冷冻法则用得较少.不管对于哪种采样方法,都存在着     

微粒尘干扰盐酸副玫瑰苯胺比色法测定SO2

监测大气中SO_2浓度,普遍采用四氯汞钾吸收液-盐酸副玫瑰苯胺比色法,我们发现该法在实际测定过程中存在尘的干扰问题。这里采用在采样过程中硫酸预吸收来消除干扰的方法,并用SO_2标准气体同步测定检验。现将其有关实验方法和结果公布如下:     

塞曼原子吸收光谱法测定固定污染源废气中的汞

用PMS 30B型汞采样器采集固定污染源废气,再用塞曼原子吸收汞分析仪测定样品中的汞,高、低浓度汞标准样品测定结果均在标准范围内,相对误差分别为0和4.3%。汞吸收管对高、低浓度含汞废气的穿透效率表明,当废气汞质量浓度达到mg/m3级别时,穿透率仅为1.3%。用该方法测定稳定工况固定污染源废气中的汞,6次测定结果的RSD为5.9%,方法检出限为1.04 ng,当采样体积为20 L时,检出限为0.05μg/m3。实际监测表明,钢铁企业、燃煤电厂、垃圾焚烧厂废气中汞为0.07μg/m3~1 031μg/m3。     

AMA254汞分析仪测定颗粒物中痕量总汞的研究

采用AMA254汞分析仪测定大气颗粒物和煤中的痕量总汞,建立了直接测定颗粒物中痕量总汞的分析方法.测定结果表明,在汞绝对含量为0～35ng范围内线性良好,测定大气颗粒物和煤中的痕量总汞的检出限分别为0.06ng/m3和0.02ng/g,标准样品测定的RSD≤0.78%,加标回收率为92%～108%.该方法具有无需消解直接进样测定、极其简便、省时等特点,适合多种固体样品中痕量汞的测定.     

Effect of sample flow rate and sampling duration on the absorption of NO2 in the sodium arsenite monitoring method

The effect of the two most critical parameters, the sample flow rate and sampling duration, on the absorption efficiency of NO2 in the sodium arsenite method of nitrogen dioxide determination in ambient air was studied. Laboratory experiments showed a high sensitivity to these parameters, which were subjected to variation during actual field monitoring. The reported NO2 absorption efficiency of the method of 82% at a flow rate of 0.2 l min-1 was found to be as low as 33% at a flow rate of 1.0 l min-1 for a sampling duration of 24 h. Similarly, a considerable decrease in absorption efficiency with increasing sampling duration from 2 to 24 h was observed at a particular flow rate. Correction factors for the absorption efficiency were evolved that can be used to update the existing database, as well as future NO2 data generated using this manual monitoring method.     

Speciation and mass-balance of mercury from pulverized coal fired power plants burning western Canadian subbituminous coals

This report summarizes the results of a study carried out on six pulverized coal-fired power plants in western Canada burning subbituminous coal for the mass-balance and speciation of mercury. The main objectives of this study were to: determine the total gaseous mercury (TGM) emitted from stacks of power plants using the Ontario Hydro method; identify the speciation of emitted mercury such as metallic (Hg(0)) and gaseous elemental (GEM) mercury; and perform mass-balance calculations of mercury for milled-coal, bottom ash, electrostatic precipitators (ESP) fly ash and stack-emitted mercury based on three tests. Sampling of mercury was carried out using the Ontario Hydro method and mercury was determined using the USEPA method 7473 by cold vapor atomic absorption (CVAAS). The sample collection efficiencies confirmed that both oxidized and the elemental mercury had been successfully sampled at all power plants. The total gaseous mercury emitted (TGM) is 6.95-15.66 g h(-1) and is mostly in gaseous elemental mercury (GEM, Hg(0)) form. The gaseous elemental mercury is emitted at a rate of 6.59-12.62 g h(-1). Reactive gaseous mercury (RGM, Hg(2+)) is emitted at a rate of 0.34-3.68 g h(-1). The rate of emission of particulate mercury (Hg(p)) is low and is in the range 0.005-0.076 g h(-1). The range of mass-balances for each power plant is more similar to the variability in measured mercury emissions, than to the coal and ash analyses or process data. The mass-balance calculations for the six power plants, performed on results of the three tests at each power plant, are between 86% and 123%, which is acceptable and within the range 70-130%. The variation in mass-balance of mercury for the six power plants is mostly related to the variability of coal feed rate.     

热分解-冷原子吸收法测定土壤中汞

采用热分解处理土壤样品,用冷原子吸收法测定样品中的汞,通过优化固体测汞仪的分析条件、确定校准曲线的线性范围和样品的称样量,使该方法在0.025 mg/kg~1.50 mg/kg范围内线性良好。当取样量为0.2 g时,方法检出限为0.000 9 mg/kg,有证标准物质的测定结果在保证值范围内,高、低浓度标准物质6次测定结果的RSD分别为4.6%和4.8%。用热分解法与国标法同时处理样品并测定,其测定结果无显著差别。     

高通量固定污染源废气颗粒物中总汞的测定

用玻璃纤维滤筒采集固定污染源废气颗粒物,借助硝酸和氢氟酸的作用,使滤筒和废气颗粒物在160℃下消解,再用原子荧光法测定消解液中总汞。用50%热硝酸溶液处理玻璃纤维滤筒,消除滤筒本底值不一对测定结果的干扰,并优化消解过程,使该方法在0.050μg/L~1.00μg/L范围内线性良好。当采样体积为10 L时,方法检出限为4.5×10~(-5)mg/m~3,空白加标样6次测定结果的RSD为7.2%,加标回收率为87.0%~113%。将该方法用于测定某固定污染源废气颗粒物中总汞,测定值在标准排放限值内。     

Measurements of fractionated gaseous mercury concentrations over northwestern and central Europe, 1995-99

Although it makes up only a few per cent. of total gaseous mercury (TGM) in the atmosphere, the fraction of oxidised (divalent) mercury plays a major role in the biogeochemical cycle of mercury due to its high affinity for water and surfaces. Quantitative knowledge of this fraction present in mixing ratios in the parts-per-10(15) (ppq) range is currently very scarce. This work is based on approximately 220 data for divalent gaseous mercury (DGM) collected during 1995-99 in ambient air. Over the course of the measurements, the sampling and analytical methods were modified and improved. This is described here in detail and includes transition from wet leaching and reduction procedures to thermo-reductive desorption, the use of annular as well as tubular denuders and adoption of an automated sampling system. The concentration of DGM exhibited a strong seasonal behaviour in contrast to atomic gaseous mercury, with low values in winter and maximum values in summer. The DGM/TGM ratios were frequently found to be below the detection limit (< or = 1%) and in the range 1-5%. A trend of diurnal DGM patterns was observed and implies photolytically induced sources. Scavenging of DGM during rain events was also noticed.     

热分解齐化原子吸收光度法测定废水中的总汞

建立用热分解齐化原子吸收光度法测定废水中总汞的方法。将样品加热至650℃,使所有汞转化成蒸气,利用催化管将蒸气中的二价汞转化成零价汞,再利用金管捕集零价汞,加热金管释放零价汞并使其进入分析单元,在253.7 nm处以冷原子光谱法测定汞含量。方法检出限(t S)为0.045μg/L,测定下限为0.180μg/L。相对标准偏差RSD为2.3%~4.6%,加标回收率P为86.2%~94.8%。用热分解齐化原子吸收光度法直接测定废水中总汞,操作简单,污染小,毒性低,可替代《水质总汞的测定冷原子吸收分光光度法》(HJ 597-2011)。     

双道原子荧光同时测定海水中痕量砷和汞

建立了双道原子荧光同时测定海水中痕量砷和汞的方法。在试验条件下,砷和汞测定的相对标准偏差≤4．0％．加标回收率在92．0％～104％之间。方法操作简便,灵敏快速,适用于海水及其他水体中砷和汞的测定。     

Sampling techniques for the assessment of anthropogenic vapour and particulate mercury in the Brazilian Amazon atmosphere

A system, based on annular gold-coated denuders, was optimized and used in the atmospheric sampling of mercury in urban and rural sites of the Alta Floresta, a region in the Brazilian Amazon. Results showed that vapour phase mercury (Hgv) is dominant in samples collected in both sites. However, particulate mercury (Hg) may sometimes be significant at the urban site, with values representing up to 77% of the total Hg collected during sampling, but may also be insignificant at the same site, depending on the gold commercialization activity and, probably, on the meteorological conditions during the sampling period. The presence of mercury in both the vapour and particulate phases in the atmosphere of the urban site can explain the high mercury concentrations found in urban dust reported for some cities in the Amazon, and also the relatively high Hg concentrations found in soils adjacent to the urban centre of Alta Floresta. It appears that the urban dust of "garimpo" areas in the Amazon can act as an efficient adsorber of Hgv emitted by gold dealer operations during the purification process. Mercury emissions from gold dealer shops in the Amazon have been considered as a human health risk through the inhalation of Hg vapour. However, although true for indoor sites, the significant contribution of particulate phase Hg shown in this study in outdoor urban sites calls for a re-evaluation of the risk assessment estimates performed up to now in urban centres in the Amazon.