基于重氮化反应分光光度法测定微量亚硝酸根

基于在盐酸介质中微量亚硝酸根与罗丹明ＧＯ发生的重氮化褪色反应,建立了光度法测定微量亚硝酸根的新方法,并对机理进行了初步讨论。方法的线性范围为０．０２－０．４μｇ／ｍＬ,检出限为０．０２μｇ／ｍＬ。方法已用于水呈微量亚硝酸根的测定。     

溴酸钾氧化吡口罗红G催化动力学光度法测定痕量NO-2

研究了在磷酸介质中亚硝酸根催化溴酸钾氧化吡口罗红Ｇ而使其褪色，建立了催化动力学光度法测定痕量亚硝酸根的新方法，测定范围为０．２～２０μｇ／ｍＬ，检出限为０．２ｎｇ／ｍＬ，用于食品和水样中的亚硝酸根测定获得满意结果     

溴酸钾氧化吡罗红G催化动力学光度法测定痕量NO2^—

研究了在磷酸介质中亚硝酸根催化溴酸钾氧化吡罗红Ｇ而使褪色，建立了催化动力学光度法测定痕量亚硝酸根的新方法，测定范围为０．２－２０μｇ／ｍＬ，检出限为０．２ｎｇ／ｍｌ，用于食品和水样中的亚硝酸根测定获得满意结果。     

非平衡流动注射光度法测定微量亚硝酸根的研究

采用流动注射分析技术,研究了在酸性介质中碱性品红与亚硝酸根的反应,用自制的微机化流动注射分析仪准确控制反应时间,利用非平衡法原理,优化了实验条件,建立了测定微量亚硝酸根的新方法。线性范围为０．０～５．０ｍｇ／Ｌ,分析速度达每小时测定３６次。应用该法直接测定煤矿塌陷湖水、鱼塘水、电厂废水和地下水中的亚硝酸根获得满意结果。     

荧光动力学光度法同时测定硝酸根及亚硝酸根的研究

基于亚硝根对溴酸钾氧化罗丹明６Ｇ的催化及锌粉使硝酸根还原为亚硝酸根的原理，建立了同时测定亚硝酸根和硝酸根的荧光动力学法，用于饮用水、质控水样、饮料中硝酸根及亚硝酸根的测定，测定下限分别为０．０７４ｎｇＮＯ２＾－／ｍｌ和０．２５ｎｇＮＯ３＾－／ｍｌ。     

溴酸钾氧化酸性品红催化光度法测定亚硝酸根

研究了在强酸介质中亚硝酸根催化溴钾氧化酸性品红的褪色反应及其动力学条件，建立了高灵敏测定痕量亚硝酸根的新催化光度法。方法灵敏度为３．７×１０＾－１１ｇ／ｃｍ＾２亚硝酸态氮，线性范围为０．０６－０．４２μｇ／１０ｍＬ，用于测定唾液及硝钾中亚硝酸根。     

亚硝酸根的催化光度法测定

本法基于甲酸介质中，亚硝酸根对溴酸钾氧化甲基橙褪色的催化效应，用正交法确定最佳测定条件。本法测定亚硝酸根的线性范围为０～０．２０μｇ／ｍＬ灵敏度为２．８３×１０－１０ｇ／ｍＬ。用于测定水样中的亚硝酸根，结果良好。     

基于亚硝化反应吖啶红极谱法测定亚硝酸根

研究了在稀盐酸介质中吖啶红与亚硝酸根发生亚硝化反应,建立了极谱法测定亚硝酸根的新方法。反应产物的２．５次微分波的峰谷电位为－０．４９Ｖ,亚硝酸根浓度在０．０２－０．６μｇ．ｍｌ＾－１范围内与峰高呈线性关系,检出限为６．２＊１０＾－３μｇ．ｍｌ＾－１。相对标准偏差为１．８４％,用于测定环境水样中亚硝酸根,结果满意。     

离子色谱法测定NO_2~－时Cl~－的干扰及消除

研究了氯离子对化学抑制型高效离子色谱法测定亚硝酸根时的干扰。当亚硝酸根的浓度大于２．０ｍｇ／Ｌ时，５．０ｍｇ／Ｌ的氯离子不会对亚硝酸根的峰高信号产生明显的干扰；但当亚硝酸根浓度小于０．５０ｍｇ／Ｌ时，即可引起正干扰。该正干扰随着Ｃｌ~－／ＮＯ~－２浓度比的增加而迅速增大，但与流动相的流速（在２．５～３．０ｍＬ／ｍｉｎ之间）无关。还对４种可能消除氯离子干扰的方法进行了讨论。     

以酚藏花红为指示剂催化荧光法测定痕量亚硝酸根的研究

基于稀磷酸介质中，亚硝酸根对溴酸钾氧化酚藏花红反应的催化作用，建立了催化荧光法测定痕量亚硝酸根的新方法。反应在５５℃水浴中进行８ｍｉｎ，线性范围为０．２７～７．３μｇ／Ｌ，其回归方程为ΔＦ＝０．４０＋１０．９３ｃ，ｒ＝０．９９９４。用于水样中痕量亚硝酸根的测定，结果良好。     

Kinetic Spectrophotometric Determination of Trace Amounts of Nitrite Ion Using Its Reaction With Neutral Red

Abstract

A rapid, simple, sensetive and selective method for the determination of trace amounts of nitrite ion(30-800 ng/ml) is developed. It depends on the reaction of nitrite with Neutral Red. The reaction is monitored spectrophotometrically by measuring the decrease in absorbance at 530 nm by a fixed time method. The limit of detection is 14 ng/ml. The method is used for the determination of nitrite ion in waste water.     

The Determination of Nitrite and Nitrate Ions by Differential Pulse Polarography

Abstract

A previously reported method for the determination of nitrite ion has been extended to include nitrate ion. Nitrate is reduced to nitrite by a cadmium column and the nitrite ion determined as diphenylnitrosamine. Cadmium interference is removed by pH adjustment and the use of KDTA.     

Use of Griess reagent containing vanadium(III) for post-column derivatization and simultaneous determination of nitrite and nitrate in baby food

An ion chromatographic method with post-column derivatization and spectrophotometric detection is presented for the determination of nitrate and nitrite (NOx) in baby food. NOx residues found naturally or added as preservatives were extracted from baby foods and determined by using ion chromatography with post-column derivatization and spectrophotometric detection. Nitrate was reduced to nitrite online by post-column reduction using vanadium(lll) chloride and heat. Nitrite reacted with Griess reagent to produce a dye that was detected at 525 nm. The use of V(III) and heat to promote the reduction of nitrate to nitrite online is a novel feature of this detection system. The determination of incurred NOx residues in samples by using AOAC Method 993.03 yielded results comparable to those obtained by ion chromatography with spectrophotometric detection. The toxic and carcinogenic metal cadmium used in the AOAC Method to reduce the nitrate to nitrite was avoided. The proposed method provides simultaneous determination of nitrate and nitrite. Average recoveries of nitrate and nitrite residues ranged from 82 to 107% for fortification levels of 25-400 ppm.     

Simultaneous determination of nitrate and nitrite in saliva and foodstuffs by non-suppressed ion chromatography with bulk acoustic wave detector.

In the present paper, nitrate and nitrite in foodstuffs and saliva were simultaneously determined using a non-suppressed ion chromatography (IC) method with a bulk acoustic wave sensor (BAW) as detector, and 1.5 mmol/L potassium hydrogenphthalate (KHP) as mobile phase. The IC-BAW method is simple, rapid and accurate. The determination limits for nitrite and nitrate are 0.20 and 0.30 mg/L, respectively. The IC-BAW is comparable and agrees with the conventional spectrophotometric method for nitrite and nitrate determination.     

Determination of nitrate and nitrite in mixtures with a nitrate ion electrode

A rapid method for the determination of nitrate and nitrite ions is described. The potential of a mixture of nitrate and nitrite was measured with a nitrate ion selective electrode. The nitrite in the mixture is then oxidized to nitrate with permanganate in acid solution, and the potential of the oxidized solution is also measured with the electrode. The fundamental equations for the response of the nitrate ion electrode to nitrate ion in the presence of interfering ions were used, and a new equation was developed for calculating the original nitrate concentration of the mixture. The absolute errors for solutions of known concentrations (2.5–100 p.p.m. each) were 1.8 p.p.m. nitrate and 2 p.p.m. nitrite. When the results are calculated by computer, five determinations can be performed in 30 min. The method was applied to the determination of the oxides of nitrogen in cigarette smoke as nitrite and nitrate after dissolution in basic solution.     

比率型荧光探针结合先进校正模型用于环境水样中亚硝酸根离子的定量分析

将新型荧光光谱定量分析模型与比率型荧光探针2,3-二氨基萘相结合,发展了一种用于水溶液中亚硝酸根离子( NO-2)定量分析的新方法;并考察了本方法对含有散射物质和吸光物质的浑浊水样中NO-2进行直接定量分析的性能。结果表明,本方法对实际浑浊环境水样中NO-2的检出限和定量下限分别为1.9和5.8 nmol/L,其定量分析结果的回收率在90.8%~103%之间,与高效液相色谱-二极管阵列检测器联用仪的定量分析结果的回收率没有显著性差异。     

Determination of nitrites by the formation of bisazo dye

A facile, sensitive and rapid spectrophotometric method for the determination of nitrite is presented. The method involves the reaction of nitrite with 4-aminoazobenzene under acidic conditions in the presence of a bromide ion allowing to complete the diazotization reaction almost instantaneously. The formed diazonium ion is then coupled with acetyl acetone to give bisazo dye in an aqueous alkaline medium having maximum absorption at 500 nm. The molar absorptivity and Sandell’s sensitivity of the method were found to be 4.2 × 10⁴ dm³ mol⁻¹ cm⁻¹ and 1.1 ng cm⁻², respectively. The system obeys the Beer’s law within the concentration range of 0.1–9 μg of nitrite in the final sample volume of 10 cm³. Optimum reaction conditions were evaluated and the influence of ionic interference on the determination of nitrite has been studied. The developed method has been applied in the determination of nitrite in water and soil samples, and the results were statistically evaluated.     

Simultaneous determination of inorganic nitrogen species by microcolumn ion chromatography

Inorganic nitrogen species (nitrate, nitrite and ammonium ions) were simultaneously determined by microcolumn ion chromatography. Nitrate and nitrite were determined by UV detection at 206 nm, whereas ammonium ion was determined by fluorescence detection at excitation 410 nm and emission 470 nm. The latter fluorescence detection is based on the postcolumn reaction of ammonium ion with o-phthalaldehyde in the presence of 2-mercaptoethanol. Effects of the reagent concentration, pH, and other reaction conditions on the signal intensity were examined, and the optimum condition was explored. The present method allowed simultaneous determination of nitrate, nitrite and ammonium ions in river water.     

Simultaneous determination of bromide, nitrite and nitrate ions in seawater by capillary zone electrophoresis using artificial seawater as the carrier solution

We describe capillary zone electrophoresis (CZE) for the simultaneous determination of bromide, nitrite and nitrate ions in seawater. Artificial seawater was adopted as the carrier solution to eliminate the interference of high concentrations of salts in seawater. The artificial seawater was free from bromide ion to enable the determination of bromide ion in a sample solution. For the purpose of reversing the electroosmotic flow (EOF), 3 mM cetyltrimethylammonium chloride (CTAC) was added to the carrier solution. A 100 microm ID (inside diameter) capillary was used to extend the optical path length. The limits of detection (LODs) for bromide, nitrite, and nitrate ions were 0.46, 0.072, and 0.042 mg/L (as nitrogen), respectively. The LODs were obtained at a signal to noise ratio (S/N) of 3. The values of the relative standard deviation (RSD) of peak area for these ions were 1.1, 1.5, and 0.97%. The RSDs of migration time for these ions were 0.61, 0.69, and 0.66%. Artificial seawater samples containing various concentrations of bromide, nitrite, and nitrate ions were analyzed by the method. The error was less than +/-12% even if the concentration ratio of bromide ion to nitrite or nitrate ion was 20-240. The proposed method was applied to the determination of bromide, nitrite, and nitrate ions in seawater samples taken from the surface and the seabed. These ions in other environmental waters such as river water and rainwater samples were also determined by ion chromatography (IC) as well as this method.     

Photometric determination of nitrite

A new sensitive colour reaction for nitrite determination is presented. The method is based on the reaction of nitrite with p-aminobenzoic acid to form a diazonium ion, which is coupled with 8-hydroxyquinoline, in alkaline medium, to form a reddish-orange water-soluble azo dye. Diazotization and coupling are very fast and control of temperature is unnecessary. Moreover, the colour is stable and its intensity is in direct proportion to nitrite concentration over a wide range.