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Assessment of absorption ability of air pollutant on forest in Gongju-city

Journal of Ecology and Environment / Journal of Ecology and Environment, (P)2287-8327; (E)2288-1220
2017, v.41 no.12, pp.328-335
https://doi.org/10.1186/s41610-017-0058-8



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Abstract

Background: Some researchers have attempted to evaluate the ecological function of various additional services, away from the main point of view on the timber production of Korean forests. However, basic data, evaluation models, or studies on the absorption of air pollutants related to major plant communities in Korea are very rare. Therefore, we evaluated the functional value of the forest ecosystem in Gongju-city. Plantation manual for air purification, supplied from the Ministry of Environment in Japan, was referred to process and method for assessment of air pollutant absorption. Results: Gross primary production was calculated about average 18.2 t/ha/year. It was a relatively low value in forests mixed with deciduous broad and evergreen coniferous compared to pure coniferous forest. Net primary production was the highest value in deciduous coniferous and was the lowest value in mixed forest with deciduous broad and evergreen broad. And the mean sequestration amount of each air pollutant per unit area per year assessed from gross primary production and concentration of gas was the highest with 75.81 kg/ha/year in O3 and was 16.87 and 6.04 kg/ ha/year in NO2 and SO2, respectively. In addition, total amounts of CO2 absorption and O2 production were 716,045 t CO2/year and 520,760 t O2/year in all forest vegetation in Gongju-city. Conclusions: In this study, we evaluated the absorption ability of air pollutant in 2014 on forest in Gongju-city area. Gongju-city has the broad mountain area about 70.3%, and area of deciduous broad leaves forest was established the broadest with 47.4% of genus Quercus. Pg was calculated about average 18.2 t/ha/year. The mean sequestration amount of each air pollutant per unit area per year assessed from Pg and Cgas was the highest with 75.81 kg/ha/year in O3 and were 16.87 and 6.04 kg/ha/year in NO2 and SO2, respectively. Absorption rates of O3, NO2, and SO2 were the highest in evergreen coniferous forest about 14.87 kgO3/ha/year, 3.30 kgNO2/ha/year, 1.18 kgSO2/ha/year, and the lowest were 5. 95 kgO3/ha/year, 1.32 kgNO2/ha/year, and 0.47 kgSO2/ha/year in deciduous broad forest. In conclusion, it was evaluated that Japanese model is suitable for estimating air pollutants in Japan to Korean vegetation. However, in Korea, there is a very limited basic data needed to assess the ability of forests to absorption of air pollutants. In this study, the accuracy of a calculated value is not high because the basic data of trees with similar life form are used in evaluation.

keywords
Ecosystem service, Gross primary production, Net primary production, Air pollutant, CO2 absorption, O2 production

Reference

1.

Boumans, R., Costanzs, R., Farley, J., Wilson, M. A., Portela, R., Rotmans, J., Villa, F., & Grasso, M. (2002). Modeling the dynamics of the integrated earth system and the value of global ecosystem services using the GUMBO model. Ecological Economic, 41, 529–560.

2.

Costanza, R., D’Arge, R., de Groot, R. S., Farber, S., Grasso, M., Hannon, B., Limburg, K., Naeem, S., O’Neill, R. V., Paruelo, J., Raskin, R. G., Sutton, P., & van den Belt, M. (1997). The value of world’s ecosystem services and natural capital. Nature, 387, 253–260.

3.

Environmental Restoration and Conservation Agency (2014). Plantation manual for air purification (in Japanese).

4.

Griffin, R., Dabdub, D., & Seinfeld, J. (2002). Secondary organic aerosol 1. Atmospheric chemical mechanism for production of molecular constituents. Journal of Geophysical Research, 92, 1–36.

5.

Kang, N. (2010). A study on carbon storage in aboveground, root, and fine root of major afforestation species of Korea. Doctorial paper of Chungnam University.

6.

Kim, J., G. Kim, R. Kim, H. Yun, S. Lee, H, Chei, J. Kim and C. Park (2010). A study on public assessment of forest. Korea Forest Research Institute Report 10-26.

7.

Kim, J., Kim, R., Yoon, H., Lee, S., Choi, H., Kim, J., Park, C., & Kim, K. (2012). Valuation of nonmarket forest resources. Outdoor Recreation Management, 16(4), 9–18.

8.

Korea Forest Service. (2016). Basic statistics of forest. Statistical Yearbook of Forest, 14.

9.

Korean Forest Affair (2000). Sustainable forest management.

10.

Korean Forest Service (2016). Report of basic assessment of public function in Forest in 2014.

11.

Kweon, S., Park, Y., & Kim, E. (2008). Study on forest functions classification using GIS-Chunyang National Forest Management Planning. Journal of Korean Geographic Information, 11(4), 10–21.

12.

Lee, D. (2002). Ecology of Korea. In the 8th Intecol international congress of ecology 19–46.

13.

Lee, J., Cho, K., Jeon, Y., Kim, J., Lim, Y., Lee, K., & Lee, I. (2017). Characteristics and distribution of terpenes in South Korean forests. Journal of Ecology and Environment, 41(5), 132–141.

14.

Lee, J., Ju, H., & No, J. (2010). Research on priority of forest values based on AHP. The Journal of Korean Policy Studies, 10(3), 301–317.

15.

Millennium Ecosystem Assessment. (2005). Ecosystems and human well-being. Millennium ecosystem assessment (MA). Washington DC: Island Press.

16.

Ministry of Environment (2014). Air Korea (http://www.airkorea.or.kr/eng/index).

17.

Miyake, H. (1990). Evaluation of atmospheric purification function of green space based on plant productivity. Japan Ministry of Education「Human and Environment」Research Report 038-N31, 1530.

18.

Nelson, E., Mendoza, G., Regetz, J., Polasky, S., Tallis, H., Cameron, D. R., Chan, K. M. A., Daily, G. C., Goldstein, J., Kareiva, P. M., Lonsdorf, E., Naidoo, R., Ricketts, T.H., & Shaw, M. R. (2009). Modeling multiple ecosystem services, biodiversity conservation, commodity production, and tradeoffs at landscape scales. Front Ecological Environment, 7(4), 11.

19.

Ogawa, W. (1992). In Japanese title. Saitamakenkougaisenta Research Report 19.33-42.

20.

Shu, S., Yu, R., Lee, G., & An, G. (2006). Application of GIS to evaluate forest functions—focused on Cheonnam National University Experiment Forest. Master paper in Cheonnam University, 14(2), 45–54.

21.

Song, C. I. (2015). Assessment of ecosystem functions and services for air purification of forest. The Degree of master of science in Korea University

22.

Sugahara, K. and I. Aiga (1987). Studies on the role of vegetation as a sink of air pollutants. Research Report from National Institute for Environmental Studies, Japan 108, 1-260.

23.

Totsuka, T., & Miyake, H. (1991). Atmospheric purification of vegetation. Journal of Japan Society of Air Pollution, 26(4), 71–80.

24.

Yun, C., Kim, H., Lee, B., Shin, J., Yang, H., & Lim, J. (2011). Characteristic community type classification of forest vegetation in South Korea. Journal of Korean Forest Society, 100, 504–521.

Journal of Ecology and Environment