Hong Sang B, Kim Guy S, Jung Yong G, Lee Jai H
Advanced Environmental Monitoring Research Center (ADERC), Department of Environmental Science and Engineering, Gwangju Institute of Science and Technology (GIST), 1 Oryong-Dong, Buk-Gu, Gwangju, 500-701, South Korea.
Environ Monit Assess. 2008 Mar;138(1-3):1-15. doi: 10.1007/s10661-007-9786-z. Epub 2007 Jun 12.
An enhanced dual coil 2,4-dinitrophenylhydrazine (DNPH) derivatization method (dual coil/DNPH) allowed the quantitative determination of formaldehyde (HCHO) in ambient air. In this method, traceable HCHO was collected using a coil sampler connected in series and lacking a long sampling tube. It was then analyzed using liquid chromatography followed by UV detection of the DNPH derivatives. The method is based on the reaction of formaldehyde with DNPH to produce 2,4-dinitrophenylhydrazone. The detection limits (3sigma) were 0.10-0.40 ppbv with a precision ranging from 0.84 to 4.09% RSD. The results of dual coil/DNPH and conventional DNPH cartridge methods were generally well correlated: HCHO (dual coil/DNPH)=0.97 (+/-0.13) vs. HCHO (DNPH Cartridge)+0.33 (+/-0.33), r=0.82. The dual coil/DNPH method was used to measure gaseous HCHO in the atmosphere of Metropolitan Seoul during the summer 2000 and 2001, and in Gwangju during the fall of 2001 and 2002. The daytime mean concentration of HCHO was 4.52 (+/-5.69) and 3.21 (+/-1.27) ppbv in Metropolitan Seoul for 10-12 August 2000 and 29-31 May 2001, respectively, and 1.73 (+/-0.98), 3.04 (+/-2.25), 2.70 (+/-1.70), and 2.01 (+/-2.28) ppbv in Gwangju City during 22-27 September 2001, 17-24 October 2001, 9-13 October 2002, and 28 October to 2 November 2002, respectively. The HCHO in Seoul from 10-12 August 2000 was mainly the result of photochemical processes, while direct emissions from vehicles and long-range transport of air from China contributed during 29-31 May 2001. During 22-27 September 2001, 17-24 October 2001, and 9-13 October 2002 in Gwangju, the HCHO came primarily from photochemical processes, although some air affected by biomass burning admixed in the late afternoon. The increase in the HCHO concentration on 20 October 2001 and from 28 October to 2 November 2002 was attributed mainly to direct emissions from biomass burning in farmland near the measurement site.
一种改进的双线圈2,4 - 二硝基苯肼(DNPH)衍生化方法(双线圈/DNPH)可用于定量测定环境空气中的甲醛(HCHO)。在此方法中,使用串联的且没有长采样管的线圈采样器收集可溯源的HCHO。然后采用液相色谱法对DNPH衍生物进行紫外检测分析。该方法基于甲醛与DNPH反应生成2,4 - 二硝基苯腙。检测限(3σ)为0.10 - 0.40 ppbv,相对标准偏差(RSD)精度范围为0.84%至4.09%。双线圈/DNPH方法与传统DNPH滤筒方法的结果通常具有良好的相关性:HCHO(双线圈/DNPH)= 0.97(±0.13),而HCHO(DNPH滤筒)+ 0.33(±0.33),r = 0.82。双线圈/DNPH方法用于测量2000年和2001年夏季首尔市以及2001年和2002年秋季光州市大气中的气态HCHO。2000年8月10 - 12日和2001年5月29 - 31日,首尔市白天HCHO的平均浓度分别为4.52(±5.69)和3.21(±1.27)ppbv;2001年9月22 - 27日、2001年10月17 - 24日、2002年10月9 - 13日以及2002年10月28日至11月2日,光州市的HCHO浓度分别为1.73(±0.98)、3.04(±2.25)、2.70(±1.70)和2.01(±2.28)ppbv。2000年8月10 - 12日首尔市的HCHO主要是光化学过程的结果,而2001年5月29 - 31日则是车辆直接排放以及来自中国的空气长距离传输所致。2001年9月22 - 27日、2001年10月17 - 24日以及2002年10月9 - 13日光州市的HCHO主要来自光化学过程,不过在下午晚些时候有一些受生物质燃烧影响的空气混入。2001年10月20日以及2002年10月28日至11月2日HCHO浓度的增加主要归因于测量地点附近农田生物质燃烧产生地直接排放。
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