液液萃取电感耦合等离子体光谱法测定碳酸盐岩中的单质硫

建立了碳酸盐岩样品中单质硫的分析方法,此法以正己烷为萃取剂,在180.7 nm和182.0 nm波长下用电感耦合等离子体光谱法(ICP-AES)测定国家标准物质GBW(E)07108和碳酸盐岩样品。正己烷萃取碳酸盐岩中单质硫的回收率在90%～110%之间;每个样品测定7次,相对标准偏差(RSD)<5.0%。结果表明,此法满足实验要求,可用于大批量碳酸盐岩样品中单质硫的测定。      

胶束电动毛细管色谱法测定海底表层沉积物中的苯系化合物

用胶束电动毛细管色谱法对海底表层沉积物中的苯系化合物进行了分析测定。采用57cm×50μm毛细管柱，以50mmol/L十二烷基硫酸钠-2.0mmol/L四硼酸钠溶液（pH9.16）作为操作缓冲溶液，并加入φ=20%的甲醇作为有机改性剂，电压25kV，检测波长200nm，15min内苯、甲苯、乙苯和二甲苯可获得良好的分离。用峰面积定量，线性范围为2～100mg/L，最小检测浓度分别为0.75mg/L苯，0.45mg/L甲苯，0.39mg/L乙苯，0.1mg/L邻-二甲苯，0.31mg/L对-二甲苯。将该法用来分析石油勘探远景区域海底表层沉积物中的苯系化合物，检测浓度范围为(0.0x～0.x)μg/g。     

快速连续提取沉积物中还原性无机硫的实验方法与应用

还原性无机硫是沉积物硫中最活跃的部分,其含量变化控制沉积物中铁、磷及重金属等元素的地球化学行为,在地质过程和环境污染方面都具有至关重要的影响。化学连续提取法是目前沉积物中硫形态提取基本方法,但常用的冷扩散法处理单个样品耗时长,难以实现对大批量样品的快速连续提取。为实现快速、准确地测定沉积物样品各形态还原性无机硫的含量,本文采用热蒸馏法,改进基于前人的三步提取过程,通过优化实验装置预先制备实验所需的二氯化铬溶液,实现了样品还原性无机硫形态的快速连续提取;以过氧化氢为氧化剂,将提取的各形态硫氧化为SO24-后采用离子色谱进行检测。选取三峡库区沉积物样品进行重复实验检验,得到提取酸挥发性硫、黄铁矿硫、元素硫的标准偏差(RSD,n=3)分别为5.26%、1.22%和3.09%,重复性较好。进一步对酸挥发性硫、黄铁矿硫、元素硫的加标回收率进行测定,得到这三种硫形态的回收率分别为92.8%、93.6%、94.1%。本实验方法采用的热蒸馏法对单个硫形态提取时间为1.5h,用时较短,玻璃装置连接便捷、操作简单,分析检测准确度好,实现了一套装置对沉积物还原性无机硫形态的连续提取,可适用于大批量样品的硫形...     

X射线荧光光谱法测定土壤和沉积物中的锰

X射线荧光光谱法(XRF)是测定土壤和沉积物中锰的重要方法,具有制样简单、非破坏性测定、检测速度快等优点。目前用于建立工作曲线的土壤和沉积物标准物质的锰含量最高为2490mg/kg,采用XRF法测定受污染土壤和沉积物中的锰含量时易超出工作曲线测定范围。本文将锰标准溶液定量加入到土壤标准物质中,制备锰含量更高的校准样品,工作曲线的测定上限范围由2490mg/kg提高至3780mg/kg。该方法测定不同含量标准物质中锰含量的结果均在认定值范围内,实际样品的加标回收率为97.8%～108.3%,高含量锰的实际样品测定值与电感耦合等离子体发射光谱法测定值的相对偏差小于5.7%,相对标准偏差(RSD)小于0.4%(n=7)。实验结果表明该法测定锰含量高的土壤和沉积物的准确度和精密度良好。     

中高含硫量煤中硫的形态分析

利用超声提取、高速离心分离和加入助分散剂等手段，实现了中，高含硫量煤中单质硫，硫酸盐硫，硫化物硫，有机硫等主要形态硫的分步提取和顺序测定。所建分析方法测定了国家一级标样，统样样品和部分有分析结果的样品，其主要形态硫的加和与标准样品参考值，统检样品定值，原样品的总硫分析结果相符，RSD（n=3)为0．80％－4．23％，方法可用于煤中各主要形态硫的测定。     

高效液相色谱-荧光检测同时测定污泥中7种氟喹诺酮类抗生素

为了监测污泥中氟喹诺酮类抗生素(FQs)的含量和水平,建立了基于固相萃取高效液相色谱荧光检测法测定污泥中7种FQs的分析方法。污泥样品选用乙腈∶磷酸盐缓冲液(1∶1,V∶V)(pH=3)提取,以亲水亲油平衡(hydrophilic-lipophilic balance, HLB)小柱净化富集,经甲醇洗脱、浓缩后用高效液相色谱荧光检测器(HPLC-FLD)检测,采用乙腈/0.1%的甲酸作为流动相并以外标法定量。FQs在0.005～1.0 mg/L浓度范围内呈现良好线性关系,R2为0.992 7～0.999 8。添加量为0.05、0.5和1.0 mg/kg时,污泥中7种氟喹诺酮类的加标回收率为78.3%～106.4%,其相对标准偏差为3.68%～12.06%(N=5)。方法的检出限为0.001～0.01 mg/kg,方法定量限为0.004 6～0.038 4 mg/kg。用该方法对北京地区3个污水处理厂活性污泥样品中7种FQs进行分析,检出浓度范围为未检出至1.09 mg/kg。     

复方化学消毒剂中苯扎氯铵的高效液相色谱测定

建立了一种测定复方化学消毒剂中苯扎氯铵成分十二烷基二甲基苄基氯化铵、十四烷基二甲基苄基氯化铵和十六烷基二甲基苄基氯化铵的反相离子对高效液相色谱法。色谱柱为Platisil ODS(5μm,250 mm×4.6mm),流动相为甲醇-0.2 mol/L己烷磺酸钠(含1%三乙胺,V/V,用高氯酸调节至pH=6.0,体积比85∶15),紫外220 nm检测。用己烷磺酸钠作为离子对试剂,增强了苯扎氯铵成分的保留,三乙胺作为扫尾剂,通过抑制固定相表面残存的硅羟基对苯扎氯铵成分的吸附,减少了色谱峰拖尾。3种苯扎氯铵成分分离良好,标准曲线的线性范围分别为0.002～5 mg/mL、0.005～10 mg/mL和0.005～10 mg/mL,检测限分别为0.0005 mg/mL、0.001mg/mL和0.001 mg/mL。方法具有良好的准确度和精密度,在测定低浓度样品时优势明显。实际用于测定苯扎氯铵消毒液和医用消毒纸巾中3种苯扎氯铵成分的含量,回收率为99.3%～104.1%,日内和日间测定相对标准偏差(RSD)均小于2.0%。     

高频燃烧—红外碳硫仪测定地质样品中的碳和硫

应用HIR-944B型高频-红外碳硫分析仪,对不同地质样品中碳、硫的测定进行了研究,称样30～60mg,加入0.4g纯铁屑及1.7g钨粒助熔剂,高温燃烧分解试样,红外检测,可定量地质样品中质量为0～O.9mg的硫及质量为0～15mg的碳.用该仪器测定地质标样中碳、硫的结果与标准值符合,碳和硫11次测定的RSD分别是＜2.6%和＜3.0%.     

江汉平原第四系沉积物中砷的垂向分布规律及其对地下水中砷浓度的影响

含水层沉积物是江汉平原地下水中砷的主要来源,沉积物地球化学特征对地下水的水化学具有重要控制作用。为查明江汉平原第四系沉积物中砷的垂向分布及赋存环境,在典型高砷地下水分布区内选取2个深钻(JH002孔及YLW01孔,深度分别为230m和201m)采集沉积物样品进行了地球化学分析。结果表明全新统和上更新统含水层沉积物以黏土、粉土、淤泥质黏土、粉砂、细砂为主,指示着弱水动力的沉积环境;2个钻孔沉积物地球化学特征相似,w(As)=2.0~22.6mg/kg(平均9.0mg/kg),w(Fe)=11.8~55.0mg/g(平均37.8mg/g),w(S)=0.1~2.1mg/g(平均0.4mg/g)。中、下更新统沉积物岩相变化较大,以砂和砾石居多,局部含有黏土夹层,指示着沉积时较强的水动力沉积环境;其中JH002孔沉积物w(As)=2.7~160.5mg/kg(平均40.9mg/kg),w(Fe)=20.1~179.5mg/g(平均50.5mg/g),w(S)=0.1~17.7mg/g(平均4.9mg/g);YLW01孔沉积物砷、铁、硫质量分数均低于JH002孔,w(As)=5.2~56.1mg/kg(平均16.2mg/kg),w(Fe)=10.9~117.5 mg/g(平均36.4 mg/g),w(S)=0.3~7.8mg/g(平均1.8mg/g)。YLW01孔中、下更新统沉积物颗粒较JH002孔更细,所处的水动力条件更弱,砷、铁、硫质量分数均低于JH002孔,说明沉积历史环境影响着砷、铁、硫等元素的分布。沉积物地球化学数据聚类分析结果表明全新统和上更新统砷与铁具有显著的相关性,而中、下更新统沉积物砷与硫化物矿物紧密相关。结合不同深度含水层水化学特征差异指示上更新统含水层中含砷铁氧化物的还原性溶解导致浅层地下水中砷的富集,富硫的中、下更新统深层含水层中强还原环境下砷受到硫化物矿物的固定作用难以释放进入地下水中。     

原子荧光光谱法测定土壤和水系沉积物国家标准物质中砷

用王水浸提法和硝酸-高氯酸-氢氟酸混合酸消解法处理样品,原子荧光光度光谱法测定土壤和水系沉积物国家标准物质样品中的砷。方法检出限为0.02 mg/kg。两种前处理方法砷的测定值与标准值相符,均可以满足土壤和水系沉积物样品中砷含量的测定要求。单纯测定样品中砷含量时,王水浸提法更好;如果在测定砷同时还要测定其他元素,则可以选用混合酸消解法。     

Determination of total sulfur in geothermal water by inductively coupled plasma-atomic emission spectrometry

Sulfur speciation and concentration in geothermal water are of great significance for the research and utilization of the water resources. In most situations, it is necessary to determine the total sulfur in geothermal water. In this study, the method was established for the determination of determining total sulfur content — the inductively coupled plasma-atomic emission spectrometry (ICP-AES), with the wavelength of 182.034 nm selected in spectral line of sulfur. It was identified that the optimal working conditions of the ICP-AES instrument were 1 200 W for high frequency generator power 9 mm for vertical observation height, 0.30 MPa atomizer pressure, and 50 r/min analytical pump speed. The matrix interference of the method was eliminated by the matrix matching method. Using this method, sulfur detection limit and minimum quantitative detection limit were 0.028 mg/L and 0.110 mg/L, respectively, whilst the linear range was 0.0–100.0 mg/L. The recovery rate of sample was between 90.67% and 108.7%, and the relative standard deviation (RSD) was between 0.36% and 2.14%. The method was used to analyze the actual samples and the results were basically consistent with the industry standard method. With high analysis efficiency, the method has low detection limit and minimum quantitative detection limit, wide linear range, good precision and accuracy, and provides an important detection method for the determination of total sulfur in geothermal water.     

Geochemistry of highly acidic mine water following disposal into a natural lake with carbonate bedrock

Acid mine drainage (AMD) from the Zn–Pb(–Ag–Bi–Cu) deposit of Cerro de Pasco (Central Peru) and waste water from a Cu-extraction plant has been discharged since 1981 into Lake Yanamate, a natural lake with carbonate bedrock. The lake has developed a highly acidic pH of ∼1. Mean lake water chemistry was characterized by 16,775 mg/L acidity as CaCO₃, 4330 mg/L Fe and 29,250 mg/L SO₄. Mean trace element concentrations were 86.8 mg/L Cu, 493 mg/L Zn, 2.9 mg/L Pb and 48 mg/L As, which did not differ greatly from the discharged AMD. Most elements showed increasing concentrations from the surface to the lake bottom at a maximal depth of 41 m (e.g. from 3581 to 5433 mg/L Fe and 25,609 to 35,959 mg/L SO₄). The variations in the H and O isotope compositions and the element concentrations within the upper 10 m of the water column suggest mixing with recently discharged AMD, shallow groundwater and precipitation waters. Below 15 m a stagnant zone had developed. Gypsum (saturation index, SI ∼ 0.25) and anglesite (SI ∼ 0.1) were in equilibrium with lake water. Jarosite was oversaturated (SI ∼ 1.7) in the upper part of the water column, resulting in downward settling and re-dissolution in the lower part of the water column (SI ∼ −0.7). Accordingly, jarosite was only found in sediments from less than 7 m water depth. At the lake bottom, a layer of gel-like material (∼90 wt.% water) of pH ∼1 with a total organic C content of up to 4.40 wet wt.% originated from the kerosene discharge of the Cu-extraction plant and had contaminant element concentrations similar to the lake water. Below the organic layer followed a layer of gypsum with pH 1.5, which overlaid the dissolving carbonate sediments of pH 5.3–7. In these two layers the contaminant elements were enriched compared to lake water in the sequence As < Pb ≈ Cu < Cd < Zn = Mn with increasing depth. This sequence of enrichment was explained by the following processes: (i) adsorption of As on Fe-hydroxides coating plant roots at low pH (up to 3326 mg/kg As), (ii) adsorption at increasing pH near the gypsum/calcite boundary (up to 1812 mg/kg Pb, 2531 mg/kg Cu, and 36 mg/kg Cd), and (iii) precipitation of carbonates (up to 5177 mg/kg Zn and 810 mg/kg Mn; all data corrected to a wet base). The infiltration rate was approximately equal to the discharge rate, thus gypsum and hydroxide precipitation had not resulted in complete clogging of the lake bedrocks.     

Geochemical investigation of phosphorus and nitrogen in the hypersaline Dead Sea

Dissolved and particulate phosphorus, ammonia, and nitrate concentrations were measured in the Dead Sea water column (330 m depth, salinity ca. 340 g/L), in the Lower Jordan River and in springs along its western coast. Dissolved phosphate in the water column is fairly homogeneous, at about 35 μg P/L. Particulate P shows larger variability, 30–50 μg/L. The main inputs of dissolved phosphate into the lake are diffusion from bottom sediments (58%) and the Jordan River inflow (41%). Input from springs is negligible (1%). Biological uptake is a minor removal pathway because in the present Dead Sea, primary production takes place only when major floods occur and dilute the upper layer, about once in 10 years. When this happens, only about 200 ton P, out of a whole-lake reservoir of ca. 5000 ton P, are removed from the biologically active upper layer of about 7 m. Chemical removal pathways, not yet investigated, such as coprecipitation with authigenic aragonite, could be of importance. The average ammonia concentration in the water column has gradually increased from 5.9 mg/L in 1960 to 8.9 mg/L, in 1991. Diffusion from the bottom sediments is a major source of ammonia to the Dead Sea. The annual input from freshwater inflows has been of lesser importance in the 1960s and 1970s. A pollution-derived increase in the ammonia concentration of the Jordan River in the 1980s may partially explain the concomitant rise in the ammonia load of the lake. It is also suggested that following the 1979 overturn, and the yearly turnovers of the 1980s, ammonia might have been produced within the oxygenated water column by mineralization. Nitrate concentration was very low, 20 μg N/L, in the 1960s and increased to 0.2 to 0.5 mg/L in 1981. This increase is shown to be due to human pollution of the Jordan River. We conclude that nutrient concentration in the Dead Sea water column is controlled by physical and chemical factors, whereas biological effects are minimal.     

气相色谱-质谱联用法测定土壤中邻苯二甲酸酯类增塑剂

应用加速溶剂萃取,气相色谱-质谱联用法测定土壤中6种邻苯二甲酸酯类有机污染物。对邻苯二甲酸酯类污染物的提取溶剂进行了优化选择,确定二氯甲烷作为最佳提取溶剂。对色谱柱升温程序进行了优化,以使两个出峰时间较接近的目标物邻苯二甲酸二甲酯(DMP)、邻苯二甲酸二乙酯(DEP)能够达到基线分离。方法标准曲线的线性范围为0.50～20.0mg/L,线性相关系数均大于0.9970,方法检出限为67μg/kg,加标回收率为81.9%～111.4%。方法检出限较低,精密度好,简便快速,可满足大批量样品分析对质量和进度的要求。     

离子色谱法检测饮用水中的草甘膦

建立了离子色谱法直接测定饮用水中草甘膦的分析方法。水样加入抗坏血酸除去余氯,微孔滤膜过滤后直接进样测定。用IonPac AS11-HC阴离子交换柱为分析柱,淋洗液为20 mmol/L KOH溶液,流速为1.00mL/min,进样量100μL进行检测。方法的线性范围0~1.5 mg/L,检出限为0.1 mg/L,加标回收率为95%~106%,相对标准偏差为5.08%~7.09%。方法操作简便快捷,灵敏度高,结果准确可靠。     

离子色谱法检测二次精盐水中的痕量铵

建立了利用分离-抑制型电导检测离子色谱法测定30%二次精盐水中痕量铵的方法。以高容量IonPac CS16阳离子交换分离柱分离,甲烷磺酸淋洗液一步梯度洗脱,抑制型电导检测。对铵离子检测方法的线性范围为5~100μg/L,相关系数为0.9995,铵的检出限(S/N=3)为1.9μg/L。方法成功用于二次精盐水中痕量铵的检测。对样品进行加标回收试验,回收率为88%~107%。样品只需简单稀释、过滤后即可直接进样分析。方法操作简单、选择性好、灵敏度高。     

Distribution and isotopic composition of sulfur in lake sediments of northern Ontario

Sediments from unpolluted and highly polluted lakes in northern Ontario have been fractionated into acid volatile sulfide, HCl-soluble sulfur, elemental sulfur, pyrite sulfur, ester sulfate and carbon-bonded sulfur and the isotopic composition of each fraction determined. In general, reduced inorganic S constitutes 25–50% of the total S in the polluted surficial sediments, but is <20% in the unpolluted samples, with pyrite formation being a minor process of S diagenesis in lake sediment ecosystems. Organic S in the form of ester sulfate and carbon-bonded S predominates and both the C/S ratios and the isotopic data suggest that, in unpolluted lakes, plant detritus can be a major contributor of organic-S to the sediments. The depth profiles observed suggest that the more labile ester sulfate is diagenetically converted to the carbon-bonded form. For the polluted sediments from the Sudbury basin, the isotopic data suggest that (a) the elemental S is derived from the oxidation of acid volatile sulfide in the aerobic surficial sediments, and (b) the isotopically light reduced S species are incorporated into the organic material. S diagenesis in lake sediments generally results in the release of ³⁴S to the overlying water. The suggestion is made that sulfate concentrations over 5 mg/1 accompanied by an enrichment of surficial sediments with isotopically different S may signal significant inputs of pollutant S into the lake and its basin.     

电感耦合等离子体发射光谱法同时测定卤水中锂钠钾钙镁硼硫氯

建立了电感耦合等离子体发射光谱法(ICP-AES)同时测定碳酸盐型、硫酸盐型、氯化物型三种类型卤水中Li、Na、K、Ca、Mg、B、S、Cl等高低含量元素的分析方法。选择仪器最佳的工作条件为射频功率1400W,炬管位置位于-3,载气流量0.60 L/min。确定了各元素测定谱线,使用ICP-AES的双向观测模式、轴向观测模式测定Li、Ca、B、S、Cl以及低含量的K、Mg,径向观测模式测定高含量的Na、K、Mg,可确保卤水中不同含量的元素同时检出。Li、Na、K、Ca、Mg、B、S的检测下限为0.07～3.00 mg/L,Cl的测定下限为165mg/L。方法精密度(RSD,n=10)均小于5%,回收率为92.4%～109.7%。其中Na、K、Mg、S、Cl测定结果与传统方法测定结果基本吻合。