Estimation of seasonal diurnal variations in primary and secondary organic carbon concentrations in the urban atmosphere: EC tracer and multiple regression approaches

Woogyung Kim, Hanlim Lee, Jhoon Kim, Ukkyo Jeong, Jung Kweon

Research output: Contribution to journalArticle

20 Citations (Scopus)

Abstract

In order to investigate seasonal and diurnal variation of primary organic carbon (POC) and secondary organic carbon (SOC) concentrations in a megacity, hourly measurements of particulate and gaseous pollutants were carried out in Seoul from January to December 2010. The EC Tracer Method (ECTM) and the Multiple Regression Method (MRM) have been used to estimate seasonal and diurnal concentrations of POC and SOC concentrations. Annual mean SOC concentrations estimated by ECTM (SOC ECTM) and MRM (SOC MRM) accounted for 14.61 and 17.21% of TOC concentrations, respectively. Seasonal patterns in SOC MRM were comparable to those of SOC ECTM, but the annual average SOC MRM was about 15% greater than that of SOC ECTM. In spring, however, a large discrepancy was observed between SOC ECTM and SOC MRM, which is thought to be due to a high ozone concentration and primary TOC/EC ratio. Regarding the annual mean diurnal characteristics, POC concentration showed peaks around 10:00 and 00:00 local time that were also observed in diurnal variations of TOC and EC concentrations. Annual mean SOC concentration, however, showed peaks at around 15:00. In the morning over all seasons, we found discrepancies between SOC ECTM and SOC MRM due to overestimated SOC ECTM concentration. The diurnal variations in SOC concentrations were found to have seasonal characteristics. The diurnal pattern of SOC concentration in spring was similar to that in autumn, and SOC concentrations in all seasons with the exception of winter showed a peak at around 15:00. In summer, however, the SOC concentration peak at around 15:00 was greater by 70%, 81%, and 54% than the peaks seen in spring, autumn, and winter, respectively, which could be explained by the high ozone concentration and strong UV radiation in summer. From 10:00 to 15:00 in summer, the average increase rates in SOC ECTM and SOC MRM were 0.39 and 0.24 μg m -3 h -1, respectively. In winter, negligible diurnal variations of estimated SOC concentrations demonstrate that SOC formation is less active than in other seasons. The high concentration level of mean SOC in winter could be attributed to a low mixing height or stagnant atmospheric condition.

Original languageEnglish
Pages (from-to)101-108
Number of pages8
JournalAtmospheric Environment
Volume56
DOIs
Publication statusPublished - 2012 Sep 1

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urban atmosphere
diurnal variation
multiple regression
tracer
organic carbon
winter
method
summer

All Science Journal Classification (ASJC) codes

  • Environmental Science(all)
  • Atmospheric Science

Cite this

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title = "Estimation of seasonal diurnal variations in primary and secondary organic carbon concentrations in the urban atmosphere: EC tracer and multiple regression approaches",
abstract = "In order to investigate seasonal and diurnal variation of primary organic carbon (POC) and secondary organic carbon (SOC) concentrations in a megacity, hourly measurements of particulate and gaseous pollutants were carried out in Seoul from January to December 2010. The EC Tracer Method (ECTM) and the Multiple Regression Method (MRM) have been used to estimate seasonal and diurnal concentrations of POC and SOC concentrations. Annual mean SOC concentrations estimated by ECTM (SOC ECTM) and MRM (SOC MRM) accounted for 14.61 and 17.21{\%} of TOC concentrations, respectively. Seasonal patterns in SOC MRM were comparable to those of SOC ECTM, but the annual average SOC MRM was about 15{\%} greater than that of SOC ECTM. In spring, however, a large discrepancy was observed between SOC ECTM and SOC MRM, which is thought to be due to a high ozone concentration and primary TOC/EC ratio. Regarding the annual mean diurnal characteristics, POC concentration showed peaks around 10:00 and 00:00 local time that were also observed in diurnal variations of TOC and EC concentrations. Annual mean SOC concentration, however, showed peaks at around 15:00. In the morning over all seasons, we found discrepancies between SOC ECTM and SOC MRM due to overestimated SOC ECTM concentration. The diurnal variations in SOC concentrations were found to have seasonal characteristics. The diurnal pattern of SOC concentration in spring was similar to that in autumn, and SOC concentrations in all seasons with the exception of winter showed a peak at around 15:00. In summer, however, the SOC concentration peak at around 15:00 was greater by 70{\%}, 81{\%}, and 54{\%} than the peaks seen in spring, autumn, and winter, respectively, which could be explained by the high ozone concentration and strong UV radiation in summer. From 10:00 to 15:00 in summer, the average increase rates in SOC ECTM and SOC MRM were 0.39 and 0.24 μg m -3 h -1, respectively. In winter, negligible diurnal variations of estimated SOC concentrations demonstrate that SOC formation is less active than in other seasons. The high concentration level of mean SOC in winter could be attributed to a low mixing height or stagnant atmospheric condition.",
author = "Woogyung Kim and Hanlim Lee and Jhoon Kim and Ukkyo Jeong and Jung Kweon",
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Estimation of seasonal diurnal variations in primary and secondary organic carbon concentrations in the urban atmosphere : EC tracer and multiple regression approaches. / Kim, Woogyung; Lee, Hanlim; Kim, Jhoon; Jeong, Ukkyo; Kweon, Jung.

In: Atmospheric Environment, Vol. 56, 01.09.2012, p. 101-108.

Research output: Contribution to journalArticle

TY - JOUR

T1 - Estimation of seasonal diurnal variations in primary and secondary organic carbon concentrations in the urban atmosphere

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AU - Kim, Woogyung

AU - Lee, Hanlim

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AU - Jeong, Ukkyo

AU - Kweon, Jung

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N2 - In order to investigate seasonal and diurnal variation of primary organic carbon (POC) and secondary organic carbon (SOC) concentrations in a megacity, hourly measurements of particulate and gaseous pollutants were carried out in Seoul from January to December 2010. The EC Tracer Method (ECTM) and the Multiple Regression Method (MRM) have been used to estimate seasonal and diurnal concentrations of POC and SOC concentrations. Annual mean SOC concentrations estimated by ECTM (SOC ECTM) and MRM (SOC MRM) accounted for 14.61 and 17.21% of TOC concentrations, respectively. Seasonal patterns in SOC MRM were comparable to those of SOC ECTM, but the annual average SOC MRM was about 15% greater than that of SOC ECTM. In spring, however, a large discrepancy was observed between SOC ECTM and SOC MRM, which is thought to be due to a high ozone concentration and primary TOC/EC ratio. Regarding the annual mean diurnal characteristics, POC concentration showed peaks around 10:00 and 00:00 local time that were also observed in diurnal variations of TOC and EC concentrations. Annual mean SOC concentration, however, showed peaks at around 15:00. In the morning over all seasons, we found discrepancies between SOC ECTM and SOC MRM due to overestimated SOC ECTM concentration. The diurnal variations in SOC concentrations were found to have seasonal characteristics. The diurnal pattern of SOC concentration in spring was similar to that in autumn, and SOC concentrations in all seasons with the exception of winter showed a peak at around 15:00. In summer, however, the SOC concentration peak at around 15:00 was greater by 70%, 81%, and 54% than the peaks seen in spring, autumn, and winter, respectively, which could be explained by the high ozone concentration and strong UV radiation in summer. From 10:00 to 15:00 in summer, the average increase rates in SOC ECTM and SOC MRM were 0.39 and 0.24 μg m -3 h -1, respectively. In winter, negligible diurnal variations of estimated SOC concentrations demonstrate that SOC formation is less active than in other seasons. The high concentration level of mean SOC in winter could be attributed to a low mixing height or stagnant atmospheric condition.

AB - In order to investigate seasonal and diurnal variation of primary organic carbon (POC) and secondary organic carbon (SOC) concentrations in a megacity, hourly measurements of particulate and gaseous pollutants were carried out in Seoul from January to December 2010. The EC Tracer Method (ECTM) and the Multiple Regression Method (MRM) have been used to estimate seasonal and diurnal concentrations of POC and SOC concentrations. Annual mean SOC concentrations estimated by ECTM (SOC ECTM) and MRM (SOC MRM) accounted for 14.61 and 17.21% of TOC concentrations, respectively. Seasonal patterns in SOC MRM were comparable to those of SOC ECTM, but the annual average SOC MRM was about 15% greater than that of SOC ECTM. In spring, however, a large discrepancy was observed between SOC ECTM and SOC MRM, which is thought to be due to a high ozone concentration and primary TOC/EC ratio. Regarding the annual mean diurnal characteristics, POC concentration showed peaks around 10:00 and 00:00 local time that were also observed in diurnal variations of TOC and EC concentrations. Annual mean SOC concentration, however, showed peaks at around 15:00. In the morning over all seasons, we found discrepancies between SOC ECTM and SOC MRM due to overestimated SOC ECTM concentration. The diurnal variations in SOC concentrations were found to have seasonal characteristics. The diurnal pattern of SOC concentration in spring was similar to that in autumn, and SOC concentrations in all seasons with the exception of winter showed a peak at around 15:00. In summer, however, the SOC concentration peak at around 15:00 was greater by 70%, 81%, and 54% than the peaks seen in spring, autumn, and winter, respectively, which could be explained by the high ozone concentration and strong UV radiation in summer. From 10:00 to 15:00 in summer, the average increase rates in SOC ECTM and SOC MRM were 0.39 and 0.24 μg m -3 h -1, respectively. In winter, negligible diurnal variations of estimated SOC concentrations demonstrate that SOC formation is less active than in other seasons. The high concentration level of mean SOC in winter could be attributed to a low mixing height or stagnant atmospheric condition.

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