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http://dx.doi.org/10.13087/kosert.2018.21.4.1

Investigation on Translocation of De-icing Salts influenced by the Intensity of Foliar Damage of Roadside Trees in Chung-ju City  

Kim, Jae-Young (Department of Green Technology Convergence, College of Science Technology, Graduate School of Konkuk University)
Kim, Won-Tae (Department of Environment and Landscape Architecture, Yonam College)
Yoon, Young-Han (Department of Green Technology Convergence, College of Science Technology, Konkuk University)
Ju, Jin-Hee (Department of Green Technology Convergence, College of Science Technology, Konkuk University)
Publication Information
Journal of the Korean Society of Environmental Restoration Technology / v.21, no.4, 2018 , pp. 1-10 More about this Journal
Abstract
Use of de-icing salts results in accumulation of high concentrations of ions on roadside soils and tree. The purpose of this study isto determine translocation of seasonal impact of exchangeable cations originating from de-icing salt on roadside surface soil-plant influenced by the intensity of foliar damage (NY = 0-25%, SY = 26-50%, CY = 51-75%) of trees. This paper investigated the concentration of four exchangeable cations ($K^+$, $Ca^{2+}$, $Na^+$, and $Mg^{2+}$) on the roadside surface soil. The tree (Ginko biloba) samples were collected from the Konkuk and Judeok intersections in Chung-ju city. The sequential extraction procedure was applied to 120 soil samples of the soilsurface and 30 tree samples. Four cation exchange ions were determined by ICP-OES. The content of four exchangeable cations present on roadside soil was found to be the lowest in NY but highest in CY from tree pits in the order of NY < SY < CY. Especially, the results were apparent during spring time compared to other seasons. Soil collected from tree pits had the highest concentration of $Ca^{2+}$ possibly due to a higher volume of traffic on those streetsresulting in splashing of more calcium chloride ($CaCl_2$). The analysis of three exchangeable cations ($K^+$, $Mg^{2+}$, and $Na^+$) in the tree leaves revealed higher levels than roadside surface soil when foliar damage ratio increased in the order of NY < SY < CY in summer. In addition, a strong positive linear relationship was observed between the concentration of exchangeable cations in soil and trees. It is hypothesized that the results of this study can be a valuable baseline for managing de-icing salt on roadside soil and trees, in order to mitigate the salt stress that can damage the roadside soil and trees.
Keywords
Exchangeable Cations; Foliar Damage Intensity; Ginkgo biloba; Roadside Soil; Phytodesalination;
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Times Cited By KSCI : 7  (Citation Analysis)
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1 Bertrand, M.․T. B. Gaelle․R Galvez and M. Louis. 2015. Nutrient and removal kinetics impacts on salt phytoremediation by Atriplex patula and Typha angustifolia. Journal of Environmental Engineering 141: 1.
2 Cekstere, G. and A. Osvalde. 2013. A study of chemical characteristics of soil in relation to street trees status in Riga (Latvia). Urban For. Urban Green. 12(1) : 68-78.
3 Choi, H. S.․J. S. Hong․T.G. Noh and L. H. Kim. 2017. Evaluation of an LID bioretention facilities caused by ($CaCl_2$). Journal of Korean Society of Water and Wastewater 2016(0) : 59-60.
4 Choi, G. H.D. Y. Lee.J. Y. Bae.J. H. Rho.B.C. Moon and J. H. Kim. 2018. Bioconcentration factor of perfluorochemicals for each aerial part of rice. J. Appl. Biol. Chem. 61(2) : 191-194.   DOI
5 Cunningham, M. A.․E. Snyder․D. Yonkin․ M. Ross and T. Elsen. 2008. Accumulation of deicing salts in soils in an urban environment. Urban Ecosyst. 11 : 17-31.   DOI
6 Frausto da Silva, J. J. R. and R. J. P. Williams. 1991. The biological chemistry of the elements: The inorganic chemistry of life. Oxford : Clarendon Press.
7 Jacobi, W. R.․J. G. Hardin․B. A. Goodrich and C. M. Cleaver. 2012. Retail firewood can transport live tree pests. J. Econ. Entomol. 105(5) : 1645-1658.   DOI
8 Je, S. M. and S. H. Kim. 2017. Growth and physiological responses of Pinus strobus to $CaCl_2$. J. KILA. 45(3) : 1-8.
9 Je, S. M. and S. H. Kim. 2016. Effect of $CaCl_2$ on gas exchange and stomatal responses in the leaves of Prunus serrulata. J. Korean For. Soc. 105(3) : 303-308.   DOI
10 Ju, J. H.․J. Y. Park․H. Xu․E. Y. Lee․K. H. Hyun․J. S. Jung.E. Y. Choi and Y. H. Yoon. 2016a. Growth and physiological response of three evergreen shrubs to de-icing salt ($CaCl_2$) at different concentrations in winter. J. KILA. 44(2) : 122-129.
11 Ju, J. H.․X. Hui․J. Y. Park․E. Y. Choi and Y. H. Yoon. 2016b. Evaluation of salt tolerance of Liriope plantyphylla and Pachysandra terminalis to deicing salt ($CaCl_2$) concentration in winter. Korean J. Environ. Ecol. 30(4) : 651-657.   DOI
12 Jung, G. B․W. I. Kim․J. S. Lee․J. D. Shin․ J. H. Kim and J. T. Lee. 2006. Availability of heavy metals in soil and their translocation to water dropwort(Oenanthe javanica DC.) cultivated near industrial complex. Korean Journal of Environmental Agriculture 25(4) : 323-330.   DOI
13 Kim, L. S. and D. W. Lee. 2014. Effect of chloride-deicers on growth of wheat, barley and spinach. Korean J. Environ. Agric. 33(4) : 350-357.   DOI
14 Kwon, H. B. and T. J. Kim. 2008. Evaluation of the coating liquid sprayed on landscape plants to prevent de-icing stresses. J. KILA. 35(6) : 29-36.
15 Kwon, M. Y․S. H. Kim and J. H. Sung. 2014. The responses of growth of physiological traits of Acer triflorum on calcium chloride ($CaCl_2$) concentration. Korean J. Environ. Ecol. 28(5) : 500-509.   DOI
16 NIAST(National Institute of Agricultural Science and Technology). 2000. Method of soil and plant analysis. NIAST, Rural Development Administration, Korea. (in Korean)
17 Lee. J. G..B. D. Lee and H. J. Kang. 2006. Characteristics of deicing agent concentrations in highway roadside soils. Korean Society Of Civil Engineers 10 : 1742-1745.
18 Lee, S. Y.․W. T. Kim․J. H. Ju and Y. H. Yoon. 2013. Effect of calcium chloride concentration on roadside ground cover plant growth. J. KILA. 41(4) : 17-23.
19 Li, F.․Y. Zhang․Z. Fan and K. Oh. 2015. Accumulation of de-icing salts and its short-term effect on metal mobility in urban roadside soils. Bull. Environ. Contm. Toxicol. 94 : 525-531.   DOI
20 Patil, B. N.․S. G. Patil․M. Hebbara․M. V. Manjunatha․R. K. Gupta and P. S. Minhas. 2005. Bioameliorative role of tree species in salt-affected Vertisols of India. Journal of Tropical Forest Science 17(3) : 346-354.
21 Ryu, S. K. 2012. A study on the decline and regeneration of urban center in Cjungju. Journal of the Korean Regional Development Association 24(4) : 77-94.
22 Kim, J. Y․J. Y. Park․Y. H. Yoon and J. H. Ju. 2017. The seasonal impacts of de-icing salts on soil and vegetation in Chung-ju city. Journal of Environmental Science International 26(8) : 993-998.   DOI
23 Shin. S. S..S. D. Park.H. S. Kim and K. S. Lee. 2010. Effects of calcium chloride and ecofriendly deicer on the plant growth. Korean Society of Environmental Engineers 32(5) : 487-496.
24 Stephanie L. N. and D. B. David. 2005. Alleviation of salt-induced stress on seed emergence using soil additives in a greenhouse. Plant and Soil 268 : 303-307.   DOI
25 Zhang, Y.․F. Li․T. Sun and J. Wang. 2012. Effect of deicing salts on urban soils and the health of roadside pines (Pinus tabulaeformis) in Northeast China. Appl. Mech. Mater. 178 : 353-356.
26 Subbarao, G. V.․R. M. Wheeler․ G. W. Stutte and L. H. Levine. 1999. How far can sodium substitute for pottassium in red beet?. Journal of Plant Nutrition 22 : 1745-1761.   DOI
27 Sung, J. H.․S. M. Je․S. H. Kim and Y. K. Kim. 2010. Effect of calcium chloride($CaCl_2$) on chlorophyll fluorescence image and photosynthetic apparatus in the leaves of Prunus sargentii. Jour. Korean For. Soc. 99(6) : 922-928.
28 Willis, K.J.․G. Petrokofsky. 2017. The natural capital of city trees. Science 356(6336) : 374-376.   DOI