Browse > Article
http://dx.doi.org/10.5572/ajae.2017.11.1.029

Emission of Biogenic Volatile Organic Compounds from Trees along Streets and in Urban Parks in Tokyo, Japan  

Matsunaga, Sou N. (Tokyo Metropolitan Research Institute for Environmental Protection)
Shimada, Kojiro (Tokyo Metropolitan Research Institute for Environmental Protection)
Masuda, Tatsuhiko (Tokyo Metropolitan Research Institute for Environmental Protection)
Hoshi, Junya (Tokyo Metropolitan Research Institute for Environmental Protection)
Sato, Sumito (Tokyo Metropolitan Agriculture and Forestry Research Center)
Nagashima, Hiroki (Tokyo Metropolitan Agriculture and Forestry Research Center)
Ueno, Hiroyuki (Tokyo Metropolitan Research Institute for Environmental Protection)
Publication Information
Asian Journal of Atmospheric Environment / v.11, no.1, 2017 , pp. 29-32 More about this Journal
Abstract
Ozone concentration in Tokyo Metropolitan area is one of the most serious issues of the local air quality. Tropospheric ozone is formed by radical reaction including volatile organic compound (VOC) and nitrogen oxides ($NO_x$). Reduction of the emission of reactive VOC is a key to reducing ozone concentrations. VOC is emitted from anthropogenic sources and also from vegetation (biogenic VOC or BVOC). BVOC also forms ozone through $NO_x$ and radical reactions. Especially, in urban area, the BVOC is emitted into the atmosphere with high $NO_x$ concentration. Therefore, trees bordering streets and green spaces in urban area may contribute to tropospheric ozone. On the other hand, not all trees emit BVOC which will produce ozone locally. In this study, BVOC emissions have been investigated (terpenoids: isoprene, monoterpenes, sesquiterpenes) for 29 tree species. Eleven in the 29 species were tree species that did not emit BVOCs. Three in 12 cultivars for future planting (25 %) were found to emit no terpenoid BVOCs. Eight in 17 commonly planted trees (47%) were found to emit no terpenoid BVOC. Lower-emitting species have many advantages for urban planting. Therefore, further investigation is required to find the species which do not emit terpenoid BVOC. Emission of reactive BVOC should be added into guideline for the urban planting to prevent the creation of sources of ozone. It is desirable that species with no reactive BVOC emission are planted along urban streets and green areas in urban areas, such as Tokyo.
Keywords
Biogenic volatile organic compound; Street lining trees; Urban vegetation; Oxidant formation; Photochemical reaction;
Citations & Related Records
Times Cited By KSCI : 4  (Citation Analysis)
연도 인용수 순위
1 Calfapietra, C., Fares, S., Manes, F., Morani, A., Sgrigna, G., Loreto, F. (2013) Role of Biogenic Volatile Organic Compounds (BVOC) emitted by urban trees on ozone concentration in cities: A review. Environmental Pollution 183, 71-80.   DOI
2 Chameides, W.L., Lindsay, R.W., Richardson, J. Kiang, C.S. (1988) The role of biogenic hydrocarbons in urban photochemical smog: Atlantic as a case study. Science 241, 1473-1475.   DOI
3 Curtis, A.J., Helmig, D., Baroch, C., Daly, R., Davis, S. (2014) Biogenic volatile organic compound emissions from nine tree species used in an urban tree-planting program. Atmospheric Environment 95, 634-643.   DOI
4 Ishikawa, N., Fukushige, M. (2012) Effect of street landscape planting and urban public parks on dwelling environment in Japan. Urban Forestry Urban Greening 11, 390-395.   DOI
5 Jiang, X., Yang, Z.-L., Liao, H., Wiedinmyer, C. (2010) Sensitivity of biogenic organic aerosols to future climate change at regional scales: An online coupled simulation. Atmospheric Environment 44, 4891-4907.   DOI
6 Kiriyama, Y., Shimadera, H., Itahashi, S., Hayami, H., Miura, K. (2015) Evaluation of the Effect of Regional Pollutants and Residual Ozone on Ozone Concentrations in the Morning in the Inland of the Kanto Region. Asian Journal of Atmospheric Environment 9, 1-11.   DOI
7 Lee, K.-Y., Kwak, K.-H., Ryu, Y.-H., Lee, S.-H., Baik, J.-J. (2014) Impacts of biogenic isoprene emission on ozone air quality in the Seoul metropolitan area. Atmospheric Environment 96, 209-219.   DOI
8 Matsunaga, S.N., Guenther, A.B., Potosnak, M.J., Apel, E.C. (2008) Emission of sunscreen salicylic esters from desert vegetation and their contribution to aerosol formation. Atmospheric Chemistry Physics 8, 7367-7371.   DOI
9 Matsunaga, S.N., Mochizuki, T., Ohno, T., Endo, Y., Kusumoto, D., Tani, A. (2011) Monoterpene and sesquiterpene emissions from Sugi (Cryptomeria japonica) based on a branch enclosure measurements. Atmospheric Pollution Research 2, 16-23.   DOI
10 Matsunaga, S.N., Guenther, A.B., Greenberg, J.P., Potosnak, M., Papiez, M., Hiura, T., Kato, S., Nishida, S., Harley, P., Kajii, Y. (2009) Leaf level emission measurement of sesquiterpenes and oxygenated sesquiterpenes from desert shrubs and temperate forest trees using a liquid extraction technique. Geochemical Journal 43, 179-189.   DOI
11 Nishimura, H., Shimadera, H., Kondo, A., Akiyama, K., Inoue, Y. (2015) Numerical Analysis on Biogenic Emission Sources Contributing to Urban Ozone Concentration in Osaka, Japan. Asian Journal of Atmospheric Environment 9, 259-271.   DOI
12 Sakulyanontvittaya, T., Duhl, T., Wiedinmyer, C., Helmig, D., Matsunaga, S., Potosnak, M., Milford, J., Guenther, A. (2008) Monoterpene and Sesquiterpene Emission Estimates for the United States. Environmental Science and Technology 42, 1623-1629, doi:10.1021/es702274e.   DOI
13 Weber, F., Kowarik, I., Saumel, I. (2014) A walk on the wild side: Perceptions of roadside vegetation beyond trees. Urban Forestry Urban Greening 13, 205-212.   DOI
14 Shon, Z.-H. (2015) Emissions of Ozone Precursors from a Biogenic Source and Port-related Sources in the Largest Port City of Busan, Korea. Asian Journal of Atmospheric Environment 9, 39-47.   DOI
15 Song, S.-K., Shon, Z.-H., Son, H.K. (2015) Characteristics of Ozone Precursor Emissions and POCP in the Biggest Port City in Korea. Asian Journal of Atmospheric Environment 9, 146-157.   DOI