艾士卡熔融–离子色谱法测定沉积物中全硫
|
摘要
建立了测定沉积物中全硫的艾士卡熔融–离子色谱法。以艾士卡试剂为熔融剂,将沉积物样品在马弗炉中于850℃灼烧2 h,使各种形态的硫全部转化为硫酸根离子,用离子色谱法测定提取液中的硫含量。硫酸根离子的质量浓度在1.0~20 mg/L范围内与色谱峰面积呈良好的线性关系,相关系数为0.999 6,硫的检出限为1.2 mg/kg,测定结果的相对标准偏差为4.85%~7.36%(n=6),样品加标回收率为76.3%~90.0%。该方法与硫酸钡比浊法测定结果无显著性差异,操作简便、快速,可用于测定沉积物中的全硫含量。
Eschka reagent alkali fusion–ion chromatography was established to determine total sulfur in deposit sediment.The sediment sample was mixed with Eschka reagent which was treated as melting agent, then doped at 850℃ in muf?e furnace for 2 h, making all sulfur in sediment present as sulfate, ?nally sulfur in it was determined by using ion chromatography. The concentration of sulfate was linear with the chromatographic peak area in the range of 1.0–20 mg/L with the correlation coef?cient of 0.999 6. The detection limit of sulfur was 1.2 mg/kg, the relative standard deviations of the detection results were 4.85%–7.36%(n=6), and the recoveries were 76.3%–90.0%. The detection result by this method agreed with that by barium sulfate turbidimetry. The method is simple and rapid, and it can be used to determine total sulfur content in sediment.
Eschka reagent alkali fusion–ion chromatography was established to determine total sulfur in deposit sediment.The sediment sample was mixed with Eschka reagent which was treated as melting agent, then doped at 850℃ in muf?e furnace for 2 h, making all sulfur in sediment present as sulfate, ?nally sulfur in it was determined by using ion chromatography. The concentration of sulfate was linear with the chromatographic peak area in the range of 1.0–20 mg/L with the correlation coef?cient of 0.999 6. The detection limit of sulfur was 1.2 mg/kg, the relative standard deviations of the detection results were 4.85%–7.36%(n=6), and the recoveries were 76.3%–90.0%. The detection result by this method agreed with that by barium sulfate turbidimetry. The method is simple and rapid, and it can be used to determine total sulfur content in sediment.
引文
[1]李文超,王文浩,何岩,等.黑臭河道沉积物中硫铁行为与氮磷循环的耦合机制[J].华东师范大学学报(自然科学版),2015(2):1-8.
[2]傅娇艳,丁振华,吴彦憨,等.硫酸钡分光光度比浊法测定高硫环境样品[J].厦门大学学报(自然科学版),2007,46(6):880-883.
[3]王红卫,张爱平,熊伟,等.管式炉燃烧-碘量库仑滴定法测定石油焦中总硫含量[J].化学分析计量,2017,26(6):15-18.
[4]张宝元,贺静雯.浅谈煤中全硫测定及库仑测硫仪的日常维护保养[J].煤质技术,2013(6):67-70.
[5]朱慕萌,姚家敏,衷明华.氧弹燃烧-离子色谱法测定芹菜中氯、氮、硫元素的含量[J].江西化工,2017(2):113-115.
[6]刘攀,杜米芳,唐伟,等.无机固体样品中硫的测定方法的研究进展[J].理化检验(化学分册),2017,53(8):984-992.
[7]周慧.关于用硫酸钡比浊法测定叶片中硫化物的探讨[J].生物技术世界,2013(4):12-14.
[8]杨璐,依丽米努尔,朱苗苗,等.植物叶片中硫含量测定方法研究[J].应用化工,2015(3):575-579.
[9]孙海涛,张颖.艾士卡-离子色谱法测定植物叶片中含硫量[J].环境监控与预警,2017,9(4):35-37.
[10]赵娟儿.关于煤中全硫测定的思考[J].能源与节能,2015,121(10):105-106.
[11]GB/T 214-2007煤中全硫测定的方法[S].
[12]周梅素,郭东龙.离子色谱法测定蔬菜中硝酸盐的含量[J].分析化学,2000,28(8):1 056-1 058.
[13]袁英贤.离子色谱技术在环境监测中的应用[J].环境监测管理与技术,1997,9(3):14-16.
[14]石磊,钟春明,林青峰,等.离子色谱安培法测定尿液中的胱氨酸[J].化学分析计量,2017,26(3):72-75.
[15]张津铭,武增礼.艾士卡法测定全硫各影响因素的深入研究[J].煤质技术,2014(2):48-50.
[16]黄选忠,杜宏山,向培文,等.碱化底液消除水负峰离子色谱法测定水中F-,Cl-等7种阴离子[J].化学分析计量,2014,23(1):48-52.
[17]LY/T 1255-1999森林土壤全硫的测定[S].
[2]傅娇艳,丁振华,吴彦憨,等.硫酸钡分光光度比浊法测定高硫环境样品[J].厦门大学学报(自然科学版),2007,46(6):880-883.
[3]王红卫,张爱平,熊伟,等.管式炉燃烧-碘量库仑滴定法测定石油焦中总硫含量[J].化学分析计量,2017,26(6):15-18.
[4]张宝元,贺静雯.浅谈煤中全硫测定及库仑测硫仪的日常维护保养[J].煤质技术,2013(6):67-70.
[5]朱慕萌,姚家敏,衷明华.氧弹燃烧-离子色谱法测定芹菜中氯、氮、硫元素的含量[J].江西化工,2017(2):113-115.
[6]刘攀,杜米芳,唐伟,等.无机固体样品中硫的测定方法的研究进展[J].理化检验(化学分册),2017,53(8):984-992.
[7]周慧.关于用硫酸钡比浊法测定叶片中硫化物的探讨[J].生物技术世界,2013(4):12-14.
[8]杨璐,依丽米努尔,朱苗苗,等.植物叶片中硫含量测定方法研究[J].应用化工,2015(3):575-579.
[9]孙海涛,张颖.艾士卡-离子色谱法测定植物叶片中含硫量[J].环境监控与预警,2017,9(4):35-37.
[10]赵娟儿.关于煤中全硫测定的思考[J].能源与节能,2015,121(10):105-106.
[11]GB/T 214-2007煤中全硫测定的方法[S].
[12]周梅素,郭东龙.离子色谱法测定蔬菜中硝酸盐的含量[J].分析化学,2000,28(8):1 056-1 058.
[13]袁英贤.离子色谱技术在环境监测中的应用[J].环境监测管理与技术,1997,9(3):14-16.
[14]石磊,钟春明,林青峰,等.离子色谱安培法测定尿液中的胱氨酸[J].化学分析计量,2017,26(3):72-75.
[15]张津铭,武增礼.艾士卡法测定全硫各影响因素的深入研究[J].煤质技术,2014(2):48-50.
[16]黄选忠,杜宏山,向培文,等.碱化底液消除水负峰离子色谱法测定水中F-,Cl-等7种阴离子[J].化学分析计量,2014,23(1):48-52.
[17]LY/T 1255-1999森林土壤全硫的测定[S].
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |