Aims & Scope | Editorial Board| Review Policy | Ethical Policy | Open Access | Contact us
Archives | Search

Quantifying Inhibitory Effects of Reclaimed Soils on the Shoot and Root Growth of Legume plant Lentil(Lens culinaris)
Hyesun Park·Sua Kang·Bumhan Bae
Department of Civil & Environmental Engineering, Gachon University
정화 처리토가 렌틸(콩과식물)의 지상부 및 뿌리 성장에 주는 영향에 대한 정량평가
박혜선·강수아·배범한*
가천대학교 토목환경공학과
This article is an open access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

References

1. 국립산림과학원, 2014, 토양및 식물체 분석법: 토양 물리성, 등록번호 11-1400377-000748-01.
2. Han, S.H., Jung, M.C., Kim, J.W., Jeon, S.W., Nguyen, Q.T., Yoon, K.W., and Min, S.K., 2020, The occurrence and treatment status of off-site contaminated soils in Korea, J. Soil Groundw. Environ., 25(4), 1-6.
3. 환경부, 2013, 토양정화실적 통계자료.
4. 환경부, 2020, 제2차 토양보전 기본계획.
5. Ahmed, F.R.S., Alexander, I.J., Mwinyikione Mwinyihija, M., and Killham, K., 2012, Effect of arsenic contaminated irrigation water on Lens culinaris L. and toxicity assessment using lux marked biosensor, J. Environ. Sci., 24(6), 1106-1116.
6. Alam, M.Z., Hoque, Md. A., Ahammed, G.J., McGee, R., and Carpenter-Boggs, L., 2019, Arsenic accumulation in lentil (Lens culinaris) genotypes and risk associated with the consumption of grains, Sci. Am., 9, 9431.
7. Besalatpour, A., Hajabbasi, M.A., Khoshgoftarmanesh, A.H., and Dorostkar, 2011, Landfarming process effects on biochemical properties of petroleum-contaminated soils, Soil Sediment Contam., 20(2), 234-248.
8. Besalatpour, A., Khoshgoftarmanesh, A.H., Hajabbasi, M.A., and Afyuni, M., 2008, Germination and growth of selected plants in a petroleum contaminated calcareous soil, Soil Sediment Contam., 17(6), 665-676.
9. Bergsveinson, J., Perry, B.J., Simpson, G.L., Yost, C.K., Schutzman, R.J., Hall, B.D., and Cameron, A.D.S., 2019, Spatial analysis of a hydrocarbon waste-remediating landfarm demonstrates influence of management practices on bacterial and fungal community structure, Microb. Biotechnol., 12(6), 1199-1209.
10. Choi, M.-Z., Kim, J.-Y., Kim, J-H., and Choi, S.-I., 2010, A study on effects of oil contaminated soil on the growth of plant, J. Soil Groundw. Environ., 15(1), 50-56.
11. Cokkizgin, A. and Cokkizgin, H., 2010, Effects of lead (PbCl2) stress on germination of lentil (Lens culinaris Medic.) lines, Afr. J. Biotechnol., 9(50), 8608-8612.
12. Doran, J.W. and Zeiss, M.R., 2000, Soil health and sustainability: Managing the biotic component of soil quality, Appl. Soil Ecol., 15(1), 3-11.
13. Eissenstat, D.M., 1991, On the relationship between specific root length and the rate of root proliferation : A field study using citrus rootstocks, New Phytol., 118(1), 63-68.
14. Janas, K.M., Zielinska-Tomaszewska, J., Rybaczek, D., Maszewski, J., Posmyk, M.M., Amarowicz, R., and Kosinska, A., 2010, The impact of copper ions on growth lipid peroxidation and phenolic compound accumulation and localization in lentil(Lens culinaris Medic.) seedlings, J. Plant Physiol., 167(4), 270-276.
15. Khan, Z., Shahwar, D., Ansari, M.K.A., and Chandel, R., 2019, Toxicity assessment of anatase (TiO2) nanoparticles: A pilot study on stress response alterations and DNA damage studies in Lens culinaris Medik, Heliyon, 5(7), e02069.
16. Kramer-Walter, K.R., Bellingham, P.J., Millar, T.R., Smissen, R.D., Richardson, S.J., and Laughlin, D.C., 2016, Root traits are multidimensional: specific root length is independent from root tissue density and the plant economic spectrum, J. Ecol., 104(5), 1299-1310.
17. Lee, S.H., Lee, J.H., Jung, W.C., Park, M., Kim, M.S., Lee, S.J., and Park, H., 2020, Changes in soil health with remediation of petroleum hydrocarbon contaminated soils using two different remediation technologies, Sustainability, 12(23), 10078.
18. Lichtenthaler, H.K., 1987, [34] Chlorophylls and carotenoids: Pigments of photosynthetic biomembranes, Methods Enzymol., 148, 350-382.
19. Lim, S.J., Kim, J.H., Choi, G.H., Kwon, Y.B., Kim, D.H., and Park, B.J., 2013, Germination rate and radicle growth inhibition in crops by total petroleum hydrocarbons (TPH), Korean J. Environ. Agric., 32(4), 273-278.
20. Lukic, B., Panicoc, A., Huguenotd, D., Fabbricino M., van Hullebusch, E.D., and Esposito, G., 2017, A review on the efficiency of landfarming integrated with composting as a soil remediation treatment, Environ. Technol. Rev., 6(1), 94-116.
21. Lobet, G., Pages, L., and Draye, X., 2011, A novel image-analysis toolbox enabling quantitative analysis of root system architecture, Plant Physiol., 157(1), 29-39.
22. Maccarrone, M., Veldink, G.A., Vliegenthart, J.F.G., and Agro, A.F., 1997, Ozone stress modulates amine oxidase and lipoxygenase expression in lentil(Lens culinaris) seedlings, FEBS Lett., 408(2), 241-244.
23. OECD, 2003, OECD Guideline for the Testing of Chemicals, Terrestrial Plant Test, 208: Seedling Emergence and Seedling Growth Test.
24. Ostonen, I., Puttsepp, U., Biel, C., Alberton, O., Bakker, M.R., Lohmus, K., Majdi, H., Metcalfe, D., Olsthoorn, A.F.M., Pronk, A., Vanguelova, E., Weih, M., and Brunner, I., 2007, Specific root length as an indicator of environmental change, Plant Biosyst., 141(3), 426-442.
25. Pape, A., Switzer, C., Mccosh, N., and Knapp, C.W., 2015, Impacts of thermal and smouldering remediation on plant growth and soil ecology, Geoderma, 243-244, 1-9.
26. Picado, A., Nogueira, A., Baeta-Hall, L., Mendonça, E., de Fátima Rodrigues, M., do Céu Sàágua, M., Martins, A., and Anselmo. A.M., 2001, Landfarming in a PAH-contaminated soil, J. Environ. Sci. Health, A36(9), 1579-1588.
27. Schneider, C.A., Rasband, W.S., and Eliceiri, K.W., 2012, NIH Image to ImageJ: 25 years of image analysis, Nat. Methods, 9(7), 671-675.
28. Tang, J., Wang, M., Wang, F., Sun, Q., and Zhou, Q., 2011, Eco-toxicity of petroleum hydrocarbon contaminated soil. J. Environ. Sci., 23(5) 845-851.
29. Tepe, M. and Aydemir, T., 2011, Antioxidant responses of lentil and barley plants to boron toxicity under different nitrogen sources, Afr. J. Biotechnol., 10(53), 10882-10891.
30. Wani, P.A., Khan, Md.S., and Zaidi, A. 2008, Impact of zinc-tolerant plant growth promoting rhizobacteria on lentil grown in zinc-amended soil, Agron. Sustainable Dev., 28(3), 449-455.
31. Yi, Y.M., Oh, C., Kim, G., Lee, C., and Sung, K., 2012, Changes in the physicochemical properties of soil according to soil remediation methods, J. Soil Groundw. Environ., 17(4), 36-43.
32. Yi, Y.M., Kim, G., and Sung, K., 2013, Effects of soil remediation methods on the biological properties of soils, J. Soil Groundw. Environ., 18(8), 73-81.

This Article

2021; 26(5): 1-8

Published on Oct 31, 2021
10.7857/JSGE.2021.26.5.001
Received on Aug 16, 2021
Revised on Sep 15, 2021
Accepted on Sep 28, 2021

This Article

Services

Shared

Correspondence to