二氧化碳中一氧化氮气体标准物质研制

研制二氧化碳中一氧化氮气体标准物质。以高纯二氧化碳和一氧化氮气体标准物质为原料,采用称量法制备二氧化碳中一氧化氮气体标准物质,用气体分析仪对制备的标准物质浓度进行检测,并对该标准物质定值结果的不确定度进行评定。研制的二氧化碳中一氧化氮气体标准物质中一氧化氮的浓度为5,25,50 μmol/mol,相对扩展不确定度为3.0% (k=2)。该气体标准物质具有良好的均匀性和稳定性,可用于食品级二氧化碳分析方法的确认和评价。     

氮中二氧化氮气体标准物质的研制

采用称量法制备并计算定值,研制(10～5000)μmol.mol-1氮中二氧化氮气体标准物质。考察了气体标准物质随贮存时间和钢瓶压力变化的稳定性,将制备的气体标准物质与GBW 08180进行比对验证,结果表明研制的气体标准物质定值的扩展不确定度优于3%(k=3),有效期限为12个月。     

氮气中1 μmol·mol~(-1)硫化氢气体标准物质的研制

介绍了瓶装氮气中1μmol·mol-1硫化氢气体标准物质的研制过程,对称量法制备过程、均匀性、稳定性引入的不确定度进行了评定。该气体标准物质的相对扩展不确定度为Uc=2.0%,k=2,使用有效期为一年,取得了国家一级标准物质证书。     

氦气分析用杂质成分气体标准物质研制

采用称量法研制了氦气中微量氖、氢、氧、氮、甲烷、二氧化碳和一氧化碳7种杂质成分气体标准物质,介绍了称量法制备技术、稀释气中相关杂质的定量等过程,并分别用F检验和回归曲线法对研制的气体标准物质进行了均匀性和稳定性检验.结果表明,研制的氦气分析用杂质成分气体标准物质具有良好的均匀性和稳定性,气体标准物质定值结果为10μmo...     

大气本底温室气体测量标准物质研究进展

综述了温室气体标准物质的制备技术与研究进展。归纳了温室气体标准物质种类和量值不确定度的要求,考察了各种配气技术对温室气体监测需求的适用性。综合讨论了配气技术中的稀释操作、钢瓶处理方式及阀门管线材质对温室气体标准物质量值稳定性的影响,并比较了BIPM和WMO量传体系的差异。     

甲烷中甲硫醇气体标准物质的研制

以甲硫醇钠为原料,通过与稀硫酸反应制备甲硫醇。对甲硫醇和甲烷分别进行纯化,采用气相色谱-火焰光度检测器与气相色谱法氦离子放电检测器对纯化后的甲硫醇和甲烷进行纯度分析,甲硫醇纯度（摩尔分数）为99.75%,甲烷纯度（摩尔分数）为99.997%。通过称量法制备了甲烷中甲硫醇气体标准物质。采用气相色谱法火焰光度检测器对标准物质进行了均匀性检验、稳定性考察。研制的甲烷中甲硫醇标准物质标称浓度为100μmol/mol,F检验和回归曲线法实验结果表明,在压力0.5～10 MPa范围内,该标准物质具有良好的均匀性和稳定性,定值结果的相对扩展不确定度为2%(k=2),有效期为12个月。     

卡尔费休库仑法测定六氟化硫中痕量水

采用改进后的卡尔费休库仑装置测定六氟化硫中痕量水,平均相对标准偏差为1．8％,与五氧化二磷电解法的测定结果进行对比,相对误差为2．11％,其准确度和精密度均良好,可以满足实际生产的需要。     

牛磺酸标准物质的研制

研制了牛磺酸标准物质。采用红外光谱(IR)法对牛磺酸进行定性,经均匀性初检后分装成200瓶样品,利用超高效液相色谱(UPLC)及高效毛细管电泳(HPCE)两种不同原理的方法进行定值,从样品中随机抽取15瓶采用超高效液相色谱(UPLC)法进行了均匀性检验,经F检验表明在95%的置信区间范围内样品均匀性良好,稳定性考察按照短期稳定性(1个月)和长期稳定性(12个月)分别进行,结果表明在考察期间样品稳定性良好。评定了定值结果的不确定度,牛磺酸标准物质定值结果为99.6%,相对扩展不确定度为0.5%(k=2)。     

氮中丙烯腈气体标准物质的研制

以高纯丙烯腈和高纯氮气为原料,采用称量法配制氮中丙烯腈气体标准物质。对配制的气体标准物质分别进行机械混匀试验、压力均匀性和时间稳定性试验。经F检验,2.00μmol/mol及5.00μmol/mol两种浓度的样品在0.5~10 MPa范围内标准值无显著变化,具有较好的压力均匀性;在–20℃和40℃条件下保存7 d,其量值无显著变化,可满足运输环节量值稳定;在常温下贮存9个月量值无显著变化,表明其稳定性良好,满足国家二级标准物质对有效期的要求。对定值结果的不确定度进行评定。配制的氮中丙烯腈气体标准物质标准值为(2~5)×10~(–6)mol/mol,相对扩展不确定度为9%(k=2)。该标准物质达到国家二级标准物质的相关技术要求,可用于对丙烯腈气体报警器的校准。     

称量法制备气体标准物质称量不确定度评定的简化方法

气体标准物质作为保证分析测量结果准确性的计量标准而在科学研究、环境检测、医疗卫生、石油化工、电力、煤炭、机械等国民经济的各个领域得到广泛的应用.其制备方法多种多样,目前国际上通用的配气方法有分压法[1]、静态容量法[2]、称量法[3]和动态容积法[4]等.称量法是以国际单位制基本单位质量作为基准的绝对方法,它具有最高的准确度,是国际上公认的基准方法.国际标准化组织也出版了相应的标准(ISO 6142-2001) [5]以对称量法配气进行规范.     

Clathrate Hydrates of Sulfur Hexafluoride at High Pressures

The pressure dependence (0.4 Mpa–1.3 GPa) of the hydrate decomposition temperatures in the sulfur hexafluoride-water system has been studied. In addition to the known low-pressure hydrate SF₆17H₂O of Cubic Structure II, two new high-pressure hydrates have been found. X-ray analysis in situ showed the gas hydrate forming in the sulfur hexafluoride-water system above 50 MPa at room temperature to be of Cubic Structure I. The ability of water to form hydrates whose structures depend on the guest molecule size under normal conditions and at high pressures is discussed.     

Picogram Detection of Sulfur Hexafluoride by High Pressure Charge Exchange Mass Spectrometry

Abstract

Since air quality in industrial atmospheres is important for personal comfort and safety, tracer experiments using sulfur hexa-fluoride (SF₆) are commonly used to monitor air distributions and flow patterns.

This method involves the determination of SF₆ by high pressure charge exchange mass spectrometry at levels as low as 3 × 10^?12 grams. It employs specific ion detection in combination with gas chromatography to insure a high degree of specificity.     

低浓度氮中二氧化硫气体标准物质的制备

以二氧化硫纯度标准物质和高纯氮气为原料,采用与一级标准物质比较法制备了摩尔分数为10~100μmol/mol的氮中二氧化硫标准物质。用二氧化硫分析仪对配制的标准物质进行了机械混匀试验、压力均匀性和时间稳定性试验。结果表明,滚动30~80 min后该标准物质机械混匀良好;经F检验,在10~0.5 MPa范围内该标准物质量随压力变化无显著差异,具有较好的压力均匀性;在–20℃和40℃条件下保存7 d,其量值无显著变化,可满足运输环节量值稳定性要求;在常温下贮存11个月,量值无显著性变化,满足国家二级标准物质稳定性要求。采用与一级标准物质比较法定值,并对定值结果的不确定度进行了评定。研制的低浓度氮中二氧化硫气体标准物质的标准值分别为9.89,55.4,101.2μmol/mol(U_(rel)=2%,k=2),该标准物质满足国家二级标准物质的相关技术要求,可用于仪器校准、测量过程质量控制及分析方法的确认和评价。     

Heat of Adsorption of Pure Sulfur Hexafluoride on Micro-Mesoporous Adsorbents

The isotherms and the isosteric heats of adsorption of pure SF₆ were measured on two microporous zeolites (NaX and Silicalite), one mesoporous alumina, and two activated carbons (BPL and PCB) at 305 K. The adsorption isotherms were Type I by Brunauer classification. The PCB carbon adsorbed SF₆ most strongly and the alumina adsorbed SF₆ most weakly. The adsorption of SF₆ on the other three materials were comparable in the low pressure region despite their drastic differences in the physicochemical properties. The heat of adsorption of SF₆ on the silicalite and the alumina remained practically constant over a large range of coverage. The heat of adsorption of SF₆ increased with increasing adsorbate loading on the NaX zeolite in the high coverage region. The heat of adsorption of SF₆ on the activated carbons decreased with increasing adsorbate loading before leveling off in the high coverage region.     

Catalytic Degradation of Sulfur Hexafluoride by Rhodium Complexes

The development of a safe and efficient method for the degradation of SF₆ is of current environmental interest, because SF₆ is one of the most potent greenhouse gases. SF₆ is thermally and chemically extremely inert, and therefore, it has been used in various industrial applications. However, this inertness results in a major challenge for its depletion. We report on a process for a catalytic degradation of SF₆ in the homogeneous phase by using rhodium complexes as precatalysts. The SF₆ activation reactions feature mild reaction conditions, low catalyst loadings, and a high selectivity. The employment of phosphines and hydrosilanes for scavenging the sulfur and fluorine atoms of the SF₆ molecule allows the selective transformation of SF₆ into nongaseous and nontoxic compounds.     

Nucleophilic Activation of Sulfur Hexafluoride: Metal‐Free,Selective Degradation by Phosphines

The development of new methods for the chemical activation of the extremely inert greenhouse gas sulfur hexafluoride (SF₆) not only is of current environmental interest, but also offers new opportunities for applications of SF₆ as a reagent in organic synthesis. We herein report the first nucleophilic activation of SF₆ by Lewis bases, namely by phosphines, which results either in its complete degradation to phosphine sulfides and difluorophosphoranes or in the selective conversion of SF₆ into a bench‐stable, crystalline salt containing the SF₅^? anion. Quantum chemical calculations reveal a nucleophilic substitution mechanism (S_N2) for the initial fluorine abstraction from SF₆ by the phosphine. Furthermore, a scalable one‐pot procedure for the complete decomposition of SF₆ into solid, nonvolatile products is presented based on cheap and commercially available starting materials.     

离子色谱法测定气体中痕量二氧化硫

建立了测定气体中痕量二氧化硫的离子色谱法。采用氢氧化钠–过氧化氢溶液为吸收液,将气体样品中痕量二氧化硫转化为硫酸根离子,以离子色谱法测定硫酸根离子,从而得到气体中二氧化硫含量。二氧化硫气体含量在1~100μL/L范围内与色谱峰面积线性关系良好,相关系数为0.999 9。二氧化硫的检出限为0.1μg/L,测量结果的重复性小于2%(n=6),测定标准样品的回收率在98.1%~99.6%之间,准确度优于对照方法。     

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。     

气相色谱–火焰光度法测定进口天然气中4种形态硫

建立气相色谱–火焰光度法测定进口液化天然气中4种形态硫的方法。探讨了色谱柱、进样口温度、分流比、柱流速、升温程序和FPD检测器等对测定结果的影响。在优化的实验条件下,评价了方法的可靠性。4种形态硫化物的质量浓度在10.0~200.0μg/L范围内,其对数与峰面积对数呈良好的线性关系,线性相关系数r在0.983 3~0.999 2之间,检出限为1.7~7.7μg/L,测定结果的相对标准偏差为0.56%~0.68%(n=5)。用该法测定天然气形态硫标准气体,测定值与标准值相比,相对误差为–1.6%~–1.2%。该方法具有较高的准确度,可应用于进口天然气中4种形态硫的分析。