Browse > Article
http://dx.doi.org/10.5322/JESI.2015.24.11.1363

Effects of Soil Organic Amendment as Plant Growing Media Component for Restoration of Planting Ground  

Ju, Jin-Hee (Department of Green Technology Convergence, College of Science Technology, Konkuk University)
In, Da-Young (Department of Forest Science Graduate School, Konkuk University)
Kim, Won-Tae (Department of Environment and Landscape Architecture, Cheonan Yonam College)
Yoon, Young-Han (Department of Green Technology Convergence, College of Science Technology, Konkuk University)
Choi, Eun-Young (Department of Agricultural Sciences, Korea National Open University)
Publication Information
Journal of Environmental Science International / v.24, no.11, 2015 , pp. 1363-1370 More about this Journal
Abstract
This study was aimed to determine effects of soil organic amendment as plant growing media component on restoration of planting ground. The changes of soil physical and chemical properties and germination and growth of kentucky bluegrass (Poa pratensis L.) were investigated. For treatments, soil was excavated at depth of 0-50 cm (referred as $S_1$) and at depth of 50-100 cm (referred as $S_2$). Then the half amount of $S_1$ soil was mixed with the soil organic amendment (coir dust 40% (v/v), bottom ash 25%, leaf mold 25%, vermiculite 5%, carbonized rice hull 5%) at a rate of 6% (v/v) (referred as $S_1CC$) and also the half amount of $S_2$ soil was mixed with the soil organic amendment at a rate of 6% (v/v) (referred as $S_2CC$) on pot in a 16 cm diameter and 14 cm height. The experiment was replicated 3 times with 3 pots per replication in randomized block design, and 100 seeds were planted per pot. In results, there was no significant difference in soil pH among the treatments with a slight decrease in soil hydraulic conductivity. However, in the $S_1CC$ treatment, positive increases in soil chemical properties, including electrical conductivity, organic matter, phosphoric acid, total nitrogen, exchangeable cation, and cation exchange capacity. Also, the germination rate, plant height, and number of leaves were higher in the $S_1CC$ treatment than those in other treatments. These results suggest that the addition of organic amendment to the soil at depth of 0-50 cm might be proper for restoring planting ground.
Keywords
Germination rate; Planting bed; Soil organic amendment; Turfgrass growth; Restoration;
Citations & Related Records
Times Cited By KSCI : 7  (Citation Analysis)
연도 인용수 순위
1 Bandaranayake, W., Qian, Y. L., Parton, W. J., Ojima, D. S., Follett, R. F., 2003, Estimation of soil organic carbon changes in turfgrass systems using the century model, Agronomy Journal, 95(3), 558-563.   DOI
2 Bigelow, C. A., Bowman, D. C., Cassel, K., 1999, Germi-nation and establishment with root-zone amendments, Golf Course Manage, 4, 62-65.
3 Choi, J. M., Park, J. Y., Latigui, A., 2011, Impact of physicochemical properties of root substrates on growth of mother plants and occurence of daughter plants in 'Seolhyang' strawberry propagation through bag culture, Kor. J. Hort. Sci. Technol., 29(2), 95-101.
4 Cho, J. M., Park, J. Y., Yoon, M. K., 2010, Impact of physico.chemical properties of root substrates on growth of 'Seolhyang' strawberry daughter plants occurred through bag culture of mother plants, Kor. J. Hort. Sci. Technol., 28(6), 964-972.
5 Cogger, C. G., 2005, Potential compost benefits for restoration of soils disturbed by urban development, Compost Science Utilization, 13, 243-251.   DOI
6 De Kreij, C., Van Leeuwen, G. J. L., 2001, Growth of pot plants in treated coir dust as compared to peat, Communications in Soil Science and Plant Analysis, 32, 2255-2265.   DOI
7 Hansen, N. E., Vietor, D. M., Munster, C. L., White, R. H., Provin, T. L., 2007, Runoff water quality from turfgrass established using volume-based composted municipal biosolids application, J. Environ. Qual., 36, 1013-1020.   DOI
8 Hixson, A., Wei, C. S., Weber, J. B., Yelverton, F. H., Rufty, T. W., 2009, Soil organic matter changes in turfgrass system affect binding and biodegradation of simazine, Crop Science, 49(4), 1481-1488.   DOI
9 Jeon, G. S., Woo, K. J., 2005, A study on application test of cut-slope revegetation measures with organic soil amendment materials, Korean Env. Res. & Tech., 8(3), 13-20.
10 Journal of the Korean Institute of Landscape Architecture, 2013, Standard of Landscape Architecture Design, Kimoondang Press Inc., Seoul, SG.
11 Jung, M. C., Thornton, I., 1996, Heavy metal contami-nation of soils and plants in the vicinity of a lead-zinc mine, Korea. Applied Geochemistry, 11, 53-59.   DOI
12 Kim, K. H., Kim, Y., Joo, P., Hur, Y. J., 2015, Seed germination study to determine the feasibility of local resources as materials for materials for ecological restoration, J. Korean Env. Res. Tech., 18(1), 153-163.
13 Korean Forest Research Institute, 2014, Analysis of Plants and Soils, Korean Forest Research Institute, 159-161.
14 Kim, K. N., 2015, Comparison of seed germination vigor, germination speed and germination peak in kentucky bluegrass cultivars under different germination condi-tions, Korean Env. Res. & Tech., 8(3), 23-38.
15 Kim, K. N., 2012, Effect of polymer, calcium, perlite and chitosan in soil organic amendment on growth in perennial ryegrass. Asian J. Turfgrass Sci., 26(1), 24- 34.
16 Koh, S. K., Tae, H. S., Ryu, C. H., 2006, Effect of animal organic soil amendment on growth of Korean lawn -grass and kentucky bluegrass, Kor. Turfgrass Sci., 20(1), 33-40.
17 Larsen, S. U., Bibby, B. M., 2004, Use of germination curves to describe variation in germination character -istics in three turfgrass species, Crop Science, 44(3), 891-899.   DOI
18 Lee, H. H., Ha, S. K., Kim, B. H., Seol, Y. J., Kim, K. H., 2006, Optimum physical condition of peatmoss-based substrate for growth of chinese cabbage (Brassica campestris L. ssp.) plug seedlings, Kor. J. Hort. Sci. Technol., 24(3), 322-329.
19 Lee, H. W., Jeong, D. Y., Shim, S. R., 2004, Growth characteristics of kentucky bluegrass on different rootzone foundation, Journal of the Korean Institute of Landscape Architecture, 31(6), 95-103.
20 Li, D., Joo, Y. K., Christians, N. E., Minner, D. D., 2000, Inorganic soil amendment effects on sand-based sports turf media, Crop science, 40(4), 1121-1125.   DOI
21 Li, X., Hu, F., Bowman, D., Shi, W., 2013, Nitrous oxide production in turfgrass system: Effect of soil properties and grass clipping recycling, Applied Soil Ecology, 67, 61-69.   DOI
22 Park, J. H., Kim, K. H., Lee, S. B., 2013, Analysis of characteristics of plant, soil physical and chemical of Salix spp. on the environment of Namgang Dam reservoir, Jour. Korean For. Soc., 102, 161-169.
23 Marschner, H., 1995, Mineral nutrition of higher plants, 2nd ed. Academic Press Inc., San Diego, CA.
24 Nelson, P. V., 2003, Greenhouse operation and management, 6th ed. Prentice Hall, Englewood Cliffs, NJ.
25 Park, C. B., Hwang, K. S., Lee, Y. B., 1992, Effects of source and mixing ratio of green topsoil on growth -quality of creeping bentgrass, Korean Journal of Turfgrass Science, 6(1), 1-10.
26 Shan, D., Evanylo, G., Goatley, J. M., 2012, Effect of compost sources and seeding treatments on germination and emergence of four turfgrass species, Compost Science Utilization, 20(3), 165-170.   DOI
27 Shim, S. R., 2015, Flooding tolerance of cool-season turfgrass for the revegetation of waterside slopes, J. Korean Env. Res. Tech., 18(2), 45-52.
28 Shin, B. K., Son, J. E., Choi, J. M., 2012, Physicochemical properties of peatmoss and coir dust currently used as roof medium components for crop production in Korean plant factories, Journal of Bio-Environment Control, 21(4), 362-371.
29 The Korean Institute of Landscape Architecture, 2013, Design Standard of Landscape Architecture, Seoul, KR.
30 Yamazaki, K., 1982, Management of pH in nutrient solution in hydroponics, Agriculture and Horticulture, 57(2), 327-331.