海水和大气中挥发性硫化物分析方法的研究

建立了大气和海水中挥发性硫化物的气相色谱分析方法,确定了最佳实验条件.为了适应不同的基质和保存方式,大气和海水样品采用了不同的分析方法.测定大气样品时,采用大气采样罐及三级冷阱预浓缩气相色谱-质谱联用技术,而海水样品采用吹扫捕集-气相色谱测定.本方法测定大气挥发性硫化物的线性范围较好,精密度为7.7%~15.1%,检出限为0.23~4.7 ng;海水中挥发性硫化物的精密度为3.5%~5.3%,检出限为2.5~3.5 ng.将本方法用于青岛近海海水和大气中硫化物的测定,测得海水中羰基硫、二甲基硫和二硫化碳的平均浓度分别为(268±58)pmol/L、(1264±0.2)pmol/L、(19±2)pmol/L,大气中的平均浓度为543±39、39±9和56±20(×10-12,V/V).本方法可准确测定海洋环境中的挥发性硫化物.     

顶空固相微萃取-气相色谱-质谱法测定废水中痕量挥发性烷基硫化物

建立了顶空固相微萃取(HS-SPME)和气相色谱/质谱(GC/MS)联用测定人工湿地废水中的痕量挥发性烷基硫化物的方法。针对废水中两种主要的挥发性烷基硫化物(二甲基硫、二甲基二硫),详细研究了萃取纤维头的种类、萃取时间、萃取温度、pH值、离子强度、样品量及解析条件对HS-SPME的影响。载气为高纯氦气,流速为1.0mL/min,色谱柱为DB-5ms毛细管柱(0.25μm,30m×0.32mm),柱温:25℃(5min)■40℃(1min)■60℃(5min);在优化的实验条件下,本法测定二甲基硫及二甲基二硫的线性范围分别为10～10000ng/L和1～10000ng/L;检出限(3σ)分别为1.9ng/L和1.8ng/L;相对标准偏差小于10%;回收率分别为81.0%～94.6%和84.0%～100.9%。用二乙基硫为内标物质,将本法用于人工湿地废水中主要的烷基硫化物二甲基硫和二甲基二硫的测定,获得满意结果。     

气相分子吸收法快速测定工业废水中硫化物

建立气相分子吸收法快速测定工业废水中硫化物的方法。水样经乙酸锌溶液固定后转化成硫化锌沉淀，硫化锌沉淀与盐酸反应转化成硫化氢，用载气将硫化氢气体载入气相分子吸收光谱仪的吸光管中，于202.6 nm波长处测定吸光度，吸光度与硫化物质量浓度之间的关系符合朗伯-比尔定律。硫化物质量浓度在0.02～10.0 mg/L范围内与吸光度线性关系良好，相关系数为0.999 6，方法检出限为0.005 mg/L。采用所建方法分别对水质硫化物标准样品、硫化物标准溶液和加标工业废水平行测定6次，测定值的相对标准偏差为1.3%～7.9%。对水质硫化物标准样品和硫化物标准溶液进行测定，测定值与标准值基本一致，相对误差为-5.0%～2.3%。含硫和不含硫工业废水实际样品的加标回收率分别为85.6%和80.1%。该方法快速、灵敏、准确，可用于工业废水中硫化物的检测。     

吹扫捕集气相色谱-质谱联用测定地表水中挥发性有机物

采用吹扫捕集和气相色谱-质谱联用对地表水中21种挥发性有机物进行检测.水样的加标回收率在86%～112%之间,最低检测限在0.08～0.29 μg/L之间,10 μg/L的挥发性有机物标准溶液经重复6次测定,其相对标准偏差基本小于5.0%,相关系数大于0.998.方法适合地表水中挥发性有机物的分析测定.     

直接进样气相色谱法测定密闭环境中有机硫化合物

建立了直接进样气相色谱-硫化学发光法测定密闭环境空气中微痕量有机硫化合物的方法。密闭环境空气通过直接进样、DB-SULFUR毛细管色谱柱分离、硫化学发光检测器进行检测，实现了对密闭环境空气中二硫化碳、甲硫醇等8种有机硫化物完全分离并准确测定。以目标组分的色谱峰面积响应值对相应质量浓度进行线性回归，计算线性方程和相关系数。建立的8种有机硫化物标准曲线线性良好，相关系数达0.999，加标回收率为96.4%～111.2%，测定结果的相对标准偏差不大于3%(n=6)，方法检出限为0.003～0.008 mg/m³，部分有机硫化物的检出限低于人体嗅觉阈值。     

汽油馏分的硫化物形态分布研究

采用气相色谱和硫化学发光检测(GC-SCD)技术,经过对色谱条件的优化,建立了汽油馏分中硫化物形态分布的测定方法。用标准物质的保留时间辅以化学法脱除硫醇、硫醚的方法对107个硫化物进行了定性;标准硫化物保留时间重复测定结果的相对标准偏差(RSD)≤0.25%。用内标法对主要的硫化物和总硫含量进行了定量,方法的加标回收率为96%~115%;同一样品重复测定5次,含硫大于7 mg/kg的硫化物组分重复测定结果的RSD≤8.9%。所建立的方法可用于不同装置的汽油馏分的硫化物形态分布规律的研究。     

亚甲蓝光度法测定废水中硫化物

在环境分析中,硫化物指的是水溶性无机硫化物和酸溶性金属硫化物,包括溶解性的H2S、HS^-、S^2-和存在于悬浮物中的可溶性硫化物以及酸溶性金属硫化物。用亚甲蓝吸光光度法测定废水中硫化物时,由于废水中的还原性物质、带色物和悬浮物对测定有干扰,故测定前需使用适当的预处理方法将硫化物与干扰物质分离,无色透明、不含悬浮物的水样,可采用沉淀分离法进行预处理,     

催化裂化汽油中硫化物类型分布的气相色谱-硫化学发光检测的方法研究

采用气相色谱-硫化学发光检测器(GC-SCD),建立了催化裂化汽油(FCC汽油)中各种硫化物类型分布的分析方法。考察了色谱条件对催化裂化汽油中各种硫化物分离的影响,定性了某催化裂化汽油中的58个硫化物。采用该方法,硫化物中的硫在其质量浓度为0.5~800.0 mg/L时,其峰面积与质量浓度呈较好的线性关系,相关系数达0.999,其响应与硫化物的类型无关。FCC汽油中几种主要硫化物(噻吩、正丁硫醇、2-甲基噻吩、3-甲基噻吩、2,4-二甲基噻吩)的浓度测定值的相对标准偏差(RSD)均小于5.0%。当信噪     

哈密煤温和液化固体产物热解过程中硫的变迁规律

利用固定床反应器研究了哈密煤温和液化固体产物(MLS)在热解过程中含硫气体的释放规律以及不同形态硫的变迁规律,并分析了矿物质对硫变迁规律的影响。结果表明,在实验考察的条件范围内,MLS热解过程中大部分的硫残留在半焦中,仅有不到10%的硫迁移到焦油中或转化为含硫气体逸出。热解生成的含硫气体以H2S为主,当热解温度为400℃时H2S的逸出速率达到最大。通过改进方法测定了M LS及其热解半焦中各种形态硫的含量,发现M LS热解过程中以硫化物硫和有机硫的分解和转化为主。随着热解温度的升高,MLS中有机硫逐渐分解并以含硫气体的形式逸出;当热解温度低于600℃时,M LS中硫化物硫逐渐转化为含硫气体、有机硫和少量的黄铁矿硫;当热解温度高于600℃时,M LS中碱性矿物质吸收气相中的H2S转化为硫化物硫,硫化物硫缓慢增加。醋酸酸洗可以保留M LS中大部分的硫化物硫,且酸洗后M LS热解生成的H2S逸出速率增大,峰温向低温方向移动;当热解温度高于600℃时,有机硫和硫化物硫的脱硫反应速率降低,并且M LS中的碱性矿物质与H2S反应生成金属硫化物,导致H2S逸出速率明显降低。     

流动注射光度法测定污泥中可酸解硫化物

1　引　　言由于动植物腐败分解和造纸、制革等行业废水的外排 ,释放的硫化物对环境造成污染。特别是水体的污染 ,可能使水体变质、河流淤泥沉积。因此 ,在环境监测和水处理过程中 ,硫化物的准确测定特别重要。目前硫化物的光度法测定有间接光度法、亚甲基蓝比色法等。在HCl溶液中 ,基于N ,N 二甲对苯二胺二盐酸盐 (DMPD)和FeCl3的介质中 ,用亚甲基蓝反应 ,建立了测定可酸解硫化物的流动注射光度分析的新方法。该法简便、快速 ,线性范围为 0 .0 5～ 2mg L ;检出限为 0 .0 4mg L ,测定频率为 5 0次 h。已用于测定湘江污泥中的可酸解硫…     

固相萃取-气相色谱-高分辨质谱法测定巢湖水中半挥发性有机化合物

描述了巢湖水中半挥发性有机化合物的提取、测定过程和初步结果。湖水中半挥发性有机化合物的提取采用XAD-2和XAD-4混合树脂富集，用气相色谱-高分辨质谱法测定了所萃取的有机化合物，并给出相应的分子式和结构式。春季湖水中检测到14种有机化合物。     

Rapid and accurate determination of trace volatile sulfur compounds in human halitosis by an adaptable active sampling system coupling with gas chromatography

Halitosis with the main components of trace volatile sulfur compounds widely affects the quality of life. In this study, an adaptable active sampling system with two sample‐collection modes of direct injection and solid‐phase microextraction was developed for the rapid and precise determination of trace volatile sulfur compounds in human halitosis coupled with gas chromatography–flame photometric detection. The active sampling system was well designed and produced for efficiently sampling and precisely determining trace volatile targets in halitosis under the optimized sampling and detection conditions. The analytical method established was successfully applied for the determination of trace targets in halitosis. The limits of detection of H₂S, CH₃SH, and CH₃SCH₃ by direct injection were 0.0140–23.0 μg/L with good recoveries ranging from 82.2 to 118% and satisfactory relative standard deviations of 0.4–9.5% (n = 3), respectively. The limit of detections of CH₃SH and CH₃SCH₃ by solid‐phase microextraction were 2.03 and 0.186 × 10^?3 μg/L with good recoveries ranging from 98.3 to 108% and relative standard deviations of 5.9–9.0% (n = 3). Trace volatile targets in positive real samples could be actually found and quantified by combination of direct injection and solid‐phase microextraction. This method was reliable and efficient for the determination of trace volatile sulfur compounds in halitosis.     

A purge and trap technique to capture volatile compounds combined with comprehensive two‐dimensional gas chromatography/time‐of‐flight mass spectrometry to investigate the effect of sulfur‐fumigation on Radix Angelicae Dahuricae

Sulfur‐fumigation is known to reduce volatile compounds that are the main active components in herbs used in herbal medicine. We investigated changes in chemical composition between sun‐dried and sulfur‐fumigated Radix Angelicae Dahuricae using a purge and trap technique to capture volatile compounds, and two‐dimensional gas chromatography/time‐of‐flight mass spectrometry for identification. Using sun‐dried Radix Angelicae Dahuricae samples as a reference, the results showed that 73 volatile compounds, including 12 sulfide compounds, were found to be present only in sulfur‐fumigated samples. Furthermore, 32 volatile compounds that were found in sun‐dried Radix Angelicae Dahuricae samples disappeared after sulfur‐fumigation. The proposed method can be applied to accurately discriminate sulfur‐fumigated Radix Angelicae Dahuricae from different commercial sources. Copyright © 2014 John Wiley & Sons, Ltd.     

Volatile sulfur compounds in Cheddar cheese determined by headspace solid-phase microextraction and gas chromatograph-pulsed flame photometric detection

The aim of this study was to develop a methodology for the analysis of volatile sulfur compounds (VSCs) in Cheddar cheese. Solid-phase microextraction (SPME) was employed to extract VSCs from the cheese matrix using a CAR-PDMS fiber. This extraction method was combined with gas chromatography-pulsed flame photometric detection (GC-PFPD) to achieve high sensitivity for sulfur compounds. The impact of extraction parameters, including time, temperature and sample size, was evaluated to determine the best conditions to analyze sulfur compounds in Cheddar cheese. Hydrogen sulfide, methanethiol, and dimethyl sulfide were found to constitute the majority of the overall sulfur profile while dimethyl disulfide and dimethyl trisulfide were present in lesser amounts. Artifact formation of volatile sulfur compounds was found to be minimal. Two commercial cheese samples were analyzed and differences in sulfur content were observed. Overall, SPME-GC-PFPD was found to be a highly sensitive technique for the analysis of sulfur compounds in Cheddar cheese.     

Acid volatile sulfide determination in sediments using elemental analyzer with thermal conductivity detector

A method for the determination of acid volatile sulfides (AVS) in sediments, using a common elemental analyzer with thermal conductivity detector, is proposed. The method uses a mixture of Sn and V(2)O(5) for pyrolysis and combustion to determine total sulfur (TS), and non volatile sulfur (NVS), after an acidic attack. AVS is calculated as the difference between TS and NVS. The method for TS is validated by analyzing a certified reference material. The recovery in the determination of acid volatile sulfide is determined by spiking a river sediment with ZnS. The method is accurate and gives a good reproducibility, recovering 97.7-99.6% of the sulfur in the 0-3% total sulfur content, with SD of approximately 0.015%.     

液化气中元素硫的高效液相色谱法分析

应用溶剂萃取、冷却气化方法对液化气样品进行前处理。对前处理制备的样品使用高效液相色谱法进行测定,以甲醇／水＝９５／５（Ｖ／Ｖ）为流动相,紫外检测（２５４ｎｍ）,在Ｃ１８柱上成功地分离并测定了元素硫的含量。方法检测限为０．１ｎｇ／ｇ,有良好的准确度与精密度,能充分满足各种液化气中元素硫的测定需要。     

Quantitative determination of wine highly volatile sulfur compounds by using automated headspace solid-phase microextraction and gas chromatography-pulsed flame photometric detection. Critical study and optimization of a new procedure

The quantitative determination of wine volatile sulfur compounds by automated headspace solid-phase microextraction (HS-SPME) with a carboxen-polydimethylsiloxane (CAR-PDMS) fiber and subsequent gas chromatography-pulsed flame photometric detection (GC-PFPD) has been evaluated. The direct extraction of the sulfur compounds in 5 ml of wine has been found to suffer from matrix effects and short linear ranges, problems which could not be solved by the use of different internal standards or by multiple headspace SPME. These problems were attributed to saturation of the fiber and to competitive effects between analytes, internal standards and other wine volatiles. Another problem was the oxidation of analytes during the procedure. The reduction in sample volume by a factor 50 (0.1 ml diluted with water or brine) brought about a reduction in the amount of sulfur compounds taken in the fiber by a factor just 3.3. Consequently, a new procedure has been proposed. In a sealed vial containing 4.9 ml of saturated NaCl brine, the air is thoroughly displaced with nitrogen, and the wine (0.1 ml) and the internal standards (0.02 ml) are further introduced with a syringe through the vial septum. This sample is extracted at 35 degrees C for 20 min. This procedure makes a satisfactory determination possible of hydrogen sulfide, methanethiol, ethanethiol, dimethyl sulfide, diethyl sulfide and dimethyl disulfide. The linear dynamic ranges cover the normal ranges of occurrence of these analytes in wine with typical r2 between 0.9823 and 0.9980. Reproducibility in real samples ranges from 10 to 20% and repeatability is better than 10% in most cases. The method accuracy is satisfactory, with errors below 20% for hydrogen sulfide and mostly below 10% for the other compounds. The proposed method has been applied to the analysis of 34 Spanish wines.     

Evaluation of a purge-and-trap injection system for capillary gas chromatography-microwave induced plasma-atomic emission spectrometry for the determination of volatile selenium compounds in water

A method is presented for the selective determination of the volatile selenium species dimethylselenide and dimethyldiselenide, using a commercially available purge-and-trap injection system coupled to capillary gas chromatography-microwave induced plasma-atomic emission spectrometry. The efficiency of the purging step was evaluated and the parameters affecting the purge and trap processes were optimized. The method was applied to the determination of volatile selenium compounds in lake water. Relative detection limits of 2ng/l for dimethylselenide and dimethyldiselenide, corresponding to an absolute detection limit of 10 pg, were achieved.     

便携式气相色谱-质谱联用仪现场测定畜禽粪便堆肥中挥发性有机物

采用便携式气相色谱-质谱联用仪进行了畜禽粪便堆肥排放气体中挥发性有机物质的现场分析.结果表明,在堆肥排放气体中可检测到含硫物质、脂肪烃、芳香烃及含氯有机物共20种物质.在已定量的8种物质中,CS2浓度最高,达到204 mg/m3;CS2和二甲二硫超过《恶臭污染物排放标准》(GB1455-93)的限值;SO2和苯超过《室内空气质量标准》(GB/T 18883-2002)的限值.本方法避免了常规检测中易出现的组分分解等问题,SO2测定值较常规方法提高59.3％.本方法操作方便,结果准确,适于对挥发性有机化合物的在线监测.     

Continuous flow thin-layer headspace (TLHS) analysis

Summary A new method of a continuous determination of volatile organohalogens in water is presented, based on the so-called thin layer headspace (TLHS) technique. Volatile analytes are isolated from the aqueous phase in a thermostatted spiral tube (TLHS column), where the sample flows in a form of a thin film countercurrently to a stream of purified air. The isolated compounds are mineralized in an empty quartz tube at 900°C, and the mineralization products are washed with triply distilled water. The conductivity of the wash solution is proportional to the VOX concent. The detection limit is of the order of a few ppb. The effect of the possible interfering substances has been examined and a method for the elimination of the effect of sulfur is presented. The results of the analysis of natural tap water samples are given. The theory of the THLS process is discussed and has been verified experimentally.