Asian Journal of Atmospheric Environment

Korean Society for Atmospheric Environment (한국대기환경학회)
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Air Pollution Trends in Japan between 1970 and 2012 and Impact of Urban Air Pollution Countermeasures

  • Wakamatsu, Shinji (Atmospheric Environmental Sciences Research Laboratory (AESRL), Faculty of Agriculture, Ehime University, National University Corporation) ;
  • Morikawa, Tazuko (Energy and Environment Research Division, Japan Automobile Research Institute (JARI)) ;
  • Ito, Akiyoshi (Energy and Environment Research Division, Japan Automobile Research Institute (JARI))
  • Received : 2013.11.18
  • Accepted : 2013.12.05
  • Published : 2013.12.31
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Abstract

Air pollution trends in Japan between 1970 and 2012 were analyzed, and the impact of air pollution countermeasures was evaluated. Concentrations of CO decreased from 1970 to 2012, and in 2012, the Japanese environmental quality standard (EQS) for CO was satisfied. Concentrations of $SO_2$ dropped markedly in the 1970s, owing to use of desulfurization technologies and low-sulfur heavy oil. Major reductions in the sulfur content of diesel fuel in the 1990s resulted in further decreases of $SO_2$ levels. In 2012, the EQS for $SO_2$ was satisfied at most air quality monitoring stations. Concentrations of $NO_2$ decreased from 1970 to 1985, but increased from 1985 to 1995. After 1995, $NO_2$ concentrations decreased, especially after 2006. In 2012, the EQS for $NO_2$ was satisfied at most air quality monitoring stations, except those alongside roads. The annual mean for the daily maximum concentrations of photochemical oxidants (OX) increased from 1980 to 2010, but after 2006, the $98^{th}$ percentile values of the OX concentrations decreased. In 2012, the EQS for OX was not satisfied at most air quality monitoring stations. Non-methane hydrocarbon (NMHC) concentrations generally decreased from 1976 to 2012. In 2011, NMHC concentrations near roads and in the general environment were nearly the same. The concentration of suspended particulate matter (SPM) generally decreased. In 2011, the EQS for SPM was satisfied at 69.2% of ambient air monitoring stations, and 72.9% of roadside air-monitoring stations. Impacts from mineral dust from continental Asia were especially pronounced in the western part of Japan in spring, and year-round variation was large. The concentration of $PM_{2.5}$ generally decreased, but the EQS for $PM_{2.5}$ is still not satisfied. The air pollution trends were closely synchronized with promulgation of regulations designed to limit pollutant emissions. Trans-boundary OX and $PM_{2.5}$ has become a big issue which contains global warming chemical species such as ozone and black carbon (so called SLCP: Short Lived Climate Pollutants). Cobeneficial reduction approach for these pollutants will be important to improve both in regional and global atmospheric environmental conditions.

Keywords

References

  1. MOE (Ministry of Environment, Japan). (2012) Survey report for photochemical air pollution: Focusing on future survey and research, 1-180 (in Japanese).
  2. Wakamatsu, S., Ogawa, Y., Murano, K., Goi, K., Aburamoto, Y. (1983) Aircraft survey of the secondary photochemical pollutants covering the Tokyo metropolitan area. Atmospheric Environment 17, 827-835. https://doi.org/10.1016/0004-6981(83)90434-1
  3. Wakamatsu, S., Uno, I., Suzuki, M. (1990) A field study of photochemical smog formation under stagnant meteorological conditions. Atmospheric Environment 24A, 1037-1050.
  4. Wakamatsu, S., Schere, K.L. (1991) A study using a three dimensional photochemical smog formation model under conditions of complex flow: Application of the Urban Airshed Model to the Tokyo metropolitan area. US EPA Report, EPA/600/S3-91/015, 1-84.
  5. Wakamatsu, S., Ohara, T., Uno, I. (1996) Recent trends in precursor concentrations and oxidant distribution in the Tokyo and Osaka areas. Atmospheric Environment 30, 715-721. https://doi.org/10.1016/1352-2310(95)00274-X
  6. Wakamatsu, S., Uno, I., Ohara, T., Schere, K.L. (1999) A study of the relationship between photochemical ozone and its precursor emissions of nitrogen oxides and hydrocarbons in the Tokyo area. Atmospheric Environment 33, 3097-3108. https://doi.org/10.1016/S1352-2310(97)00493-7
  7. Wakamatsu, S. (2005) Japanese countermeasures against urban air pollution. The 5th Korea/China/Japan Tripartite Joint Environmental Training, National Institute of Environmental Research, Ministry of Environment, Republic of Korea, November 20-26, 2005, Inchon, Republic of Korea, 33-47.

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