Mineralogical Characteristics and Physico-Chemical Properties of a Newly Reclaimed Tidal Flat of Haenam Bay in the Southwestern Coast of Korea

Kyo S. Lee; Jin-Hee Ryu; Dong-Sung Lee; Beong-Deuk Hong; Il-Hwan Seo; Chul-Soon Lim; Hyun-Kyu Jung; Doug-Young Chung

doi:10.7745/KJSSF.2019.52.4.475

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Original research article

Mineralogical Characteristics and Physico-Chemical Properties of a Newly Reclaimed Tidal Flat of Haenam Bay in the Southwestern Coast of Korea

30 November 2019. pp. 475-488

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Abstract

The aim of this investigation was to identify the soil physical and chemical properties and the mineralogies of recently reclaimed tidal flat land (RTFL) consisted of five different soil series within the investigation site located in Youngsan-river Bay of Southwestern coast in Korea, that has to be only used as upland according to the policy of designated absolute agricultural land. The results show that the soil textures of the soil horizons are sandy loam and silt loam for all five soil series, with typical soil colors of yellow to pale yellow for Ap horizons containing higher clay content greater (> 18%) and greenish gray containing higher sand content (> 60%). The pHs of surface horizons for Bokchun (BC), Junbook (JB) and Poseung (PS) soil series are not only acidic (< 4.5) but also soil color is dark brown with reddish brown mottles. The X-ray diffraction (XRD) analyses represent the major minerals are illite, kaolinite and quartz for BC, JB and PS soil series while quartz and illite are major minerals for Taehan (TH) and Gwangpo (GP) soil series. Silicon and aluminum dominant in the Ap and Bg horizons are significantly higher in the soil series of BC, JB and PS than those in TH and GP. Also, we found that the kaolinite particles of varying sizes are arranged in face-to-face patterns along with the presence of spherical particles of quartz, especially in BC, JB and PS.

Index map and Locations of soil profile investigation pits and soil sampling points for five soil series within the experimental site at the RTFS within the Haenam Bay. Numerous dendritic streams on the wide tidal flat and main tidal channel (maximum depth of 25 m) comprise the coastal embayment.

Keywords

Mineralogy

XRD

SEM-EDS

Reclaimed tidal flat soils

References

Ahern, C.R., M.R. Ahern, and B. Powell. 1998. Guidelines for Sampling and Analysis of Lowland Acid Sulfate Soils (ASS) in Queensland 1998. Department of Natural Resources, Indooroopilly, Queensland, Australia. pp. 28-30.

Attanandana, T. and S. Vacharotayan. 1986. Acid sulfate soils: their characteristics, genesis, amelioration and utilization. Southeast Asian Studies. 24:154-180.

Black, K.S., T.J. Tolhurst, S.E. Hagerthey, and D.M. Paterson. 2002. Working with natural cohesive sediments. J. Hydraulic Eng. Forum. 128:1-7.

10.1061/(ASCE)0733-9429(2002)128:1(2)

Choi, J.H. 1981. Recent clay minerals in the Kunsan estuary and the adjacent continental shelf. MSc thesis, Seoul National Univ. Korea.

Chung, D.Y., H. Kim, M. Park, and S.E. Lee. 2012. Characteristics of a Reclaimed Tidal Soil for Effective Resalization at Saemangum and Youngsan-River. Korean J. Soil Sci. Fert. 45:1222-1229.

10.7745/KJSSF.2012.45.6.1222

CSIRO. 2003. Acid sulfate soil technical manual 1.2 http://www.clw.csiro.au/publications/acid-sulfate-soils/barker_ inlet_reports/Final_App1_coastal_ ASS_tech_manual_v1.2.pdf

Eswaran, H., and W.C Bin. 1978. A study of a deep-weathering profile on granite in Peninsular Malaysia. III. Alteration of feldspars. Soil Sci. Soc. Amer. J. 42:154-158.

10.2136/sssaj1978.03615995004200010034x

Gilkes, R.J., A. Suddhprakarn, and T.M. Armitage. 1980. Scanning electron microscope morphology of deeply weathered granite. Clays and Clay Minerals. 28:29-34.

10.1346/CCMN.1980.0280104

Hey, K.M., and C.R. Ahern. 2000. Preliminary methods for recognition of acid sulfate soils: Desktop assessment and use of on-site indicators. In: Acid Sulfate Soils: Environmental Issues, Assessment and Management, Technical Papers. Ahern CR, Hey KM, Watling KM and Eldershaw VJ (eds), Brisbane, 20-22 June, 2000. Department of Natural Resources, Indooroopilly, Queensland, Australia.

Hey, K.M., C.R. Ahern, and K.M. Watling. 2000. Using Chemical Field Tests to Identify Acid Sulfate Soils Likelihood. In Acid Sulfate Soils: Environmental Issues, Assessment and Management, Technical Papers. Ahern CR, Hey KM, Watling KM and Eldershaw VJ (eds), Brisbane, 20-22 June, 2000. Department of Natural Resources, Indooroopilly, Queensland, Australia. pp. 16-9-16-12.

Hwang, M. 1999. Coastal Land-use Change by Reclamation of Tidal Flats along the Western Coast of the Capital Region in Korea Seoul National University, Seoul, Korea.

Ismail, F.T. 1970. Biotite weathering and clay formation in arid and humid region of California. Soil Sci. 109:257-261.

10.1097/00010694-197004000-00011

Jayalath, N. 2012. Laboratory Protocols for Acid Sulfate Soils. CSIRO, Australia.

Kim, B.K. 1988. Sedimentological study of the muddy deposits in the Yellow Sea. MSc thesis, Seoul National Univ., Korea.

Kim, D.C. 1980. Recent clay minerals of the Yeongsan estuary and the adjacent continental shelf. MSc thesis. Seoul National Univ. Korea.

Lee, H.J., S.S. Chun., J.H. Chang, and S.J. Han. 1994. Landward migration of isolated shelly sand ridge (chenier) on the macrotidal flat of Gomso Bay, west coast of Korea: controls of storms and typhoon. Journal of Sedimentary Research, A64:886-893.

10.1306/D4267EF6-2B26-11D7-8648000102C1865D

Lim, D.I., H.N. Kim, and H.S. Jung. 2003. Geochemical-mineralogical characteristics of the pre-Holocene sediments in Haenam Bay, west coast of Korea. Geo-Mar Lett (2003) 22:210-217.

10.1007/s00367-002-0115-9

McElnea, A.E., C.R. Ahern, and N.W. Menzies. 2002. The measurement of actual acidity in acid sulfate soils and the determination of sulfidic acidity in suspension after peroxide oxidation. Australian Journal of Soil Research. 40(7):1133-1157.

10.1071/SR01118

Moon, J.W., Y. Song, H.S. Moon, and G.H. Lee. 2000. Clay minerals from tidal flat sediments at Youngjong Island, Korea, as a potential indicator of sea- level change, Clay Minerals (2000)35:841-855.

10.1180/000985500547278

Oh, Y.Y., S.H. Lee, J. Jung, J.C. Ko, W.Y. Choi, J.H. Jeong, S. Kim, J.H. Ryu, Y.J. Kim, H.S. Bae, J.H. Kim, K.Y. Kim, Y.D. Kim, and. S.L. Kim. 2016. Change of soil properties and crop productivity by paddy-upland rotation in newlyreclaimed tidal land. Journal of Korean Society of International Agriculture. 28:390-396.

10.12719/KSIA.2016.28.3.390

Park, S.C., Y.S. Kim, and S.K. Hong. 1991. Shallow seismic stratigraphy and distribution pattern of late Quaternary sediments in a macrotidal bay: Gunhung Bay, west coast of Korea. Marine Geology. 98:135-144.

10.1016/0025-3227(91)90041-2

Park, Y.A., and B.K. Khim. 1990. Clay minerals of the recent fine-grained sediments on the Korean continental shelves. Cont. Shelf Res. 10:1179-1191.

10.1016/0278-4343(90)90015-E

Park, Y.A., and K.S. Choi. 1998. Late Quaternary stratigraphy in the reclaimed tidal flat of Youngjong Island, west cost of Korea: Implication on the climate and sea-level changes. pp. 40-41 in: Proc. 1st Int. Symp. on the Geoenvironmental Changes and Biodiversity in northeast Asia, Seoul, Korea.

Park, Y.A., J.Y. Choi, D.I. Lim, K.W. Choi, and Y.G. Lee. 1995. Unconformity and stratigraphy of late Quaternary tidal deposits, Namyang Bay, west coast of Korea. Journal of Korean Society Oceanography. 30:332-340.

RDA. 2016. http://www.okdab.com/news/issueTrend/trendView.do?listType=press&issueSeq=3185&searchYear= 2016&searchMonth=11&searchKey=subject&searchValue=&currentPage=1

RDA. 2017. Soil series of a reclaimed tidal soil. http://www.nongsaro.go.kr/portal/ps/psb/psbk/kidofcomdtyDtl.ps; jsessionid=Lc3cJtjh1sW6QdwMOvjgejWK0WLhvjXAOEPcSzAVZUarp3BcM6OFgxoebEBT74wD.nongsaro-web_servlet_engine1?menuId=PS00067&kidofcomdtyNo=20506

Reynolds, Jr., R.C. 1989. Principles of powder diffraction. in Modern Powder Diffraction: v. 20, (eds) Bish D. L., and Post J. E. The Mineralogical Society of America, Washington, D.C.

10.1515/9781501509018-004

Ryu, J.H., J.S. Won, and K.D. Min. 2002. Waterline extraction from Landsat TM data in a tidal flat a case study in Gomso Bay, Korea, Remote Sensing of Environment. 83:442-456.

10.1016/S0034-4257(02)00059-7

Sengupta, P., P.C. Saikia, and P.C. Borthakur. 2008. SEM-EDX characterization of an iron-rich kaolinite clay Journal of Scientific and Industrial Research. 67:812-818.

Supiandi, S., and B. Sumawinata. 1989. Studies on Peat in the Coastal Plains of Sumatra and Borneo : Part II : The Clay Mineralogical Composition of Sediments in Coastal Plains of Jambi and South Kalimantan. Southeast Asian Studies. 27(1):35-54.

USDA Soil Survey Staff. Soil Conservation Service. 1975. Soil Taxonomy: A Basic System of Soil Classification for Making and Interpreting Soil Surveys. USDA Agric. Handb, 436. Washington, D.C.: US. Government Printing Office. 754p.

van Breeman, N. 1973. Soil forming processes in acid sulfate soils. In: Dost, H. (Ed.) 'Acid Sulphate Soils. Proceedings of the International Symposium on Acid Sulphate Soils 13-20 August 1972, Wageningen. The Netherlands. I. Introductory Papers and Bibliography.' pp. 66-130. Publication No.18, International Institute for Land Reclamation and Improvement, Wageningen, The Netherlands.

WADE(Western Australian Department of Environment). 2006. Identification & Investigation of Acid Sulfate Soils. https://www.qld.gov.au/environment/land/soil/acid-sulfate/ identified/# physical

Information

Publisher :Korean Society of Soil Science and Fertilizer
Publisher(Ko) :한국토양비료학회
Journal Title :Korean Journal of Soil Science and Fertilizer
Journal Title(Ko) :한국토양비료학회 학회지
Volume : 52
No :4
Pages :475-488
Received Date : 2019-10-02
Accepted Date : 2019-10-28
DOI :https://doi.org/10.7745/KJSSF.2019.52.4.475

Korean Journal of Soil Science and Fertilizer ISSN:0367-6315(Print) 2288-2162(Online) 한국토양비료학회 학회지

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