JOURNAL BROWSE
Search
Advanced SearchSearch Tips
Differences of Rare Earth Element Concentrations of Plants in Top Soils of Gapyeong Serpentine Area: Based on the M. sinensis, A. vulgaris and R. crataegitolius
facebook(new window)  Pirnt(new window) E-mail(new window) Excel Download
 Title & Authors
Differences of Rare Earth Element Concentrations of Plants in Top Soils of Gapyeong Serpentine Area: Based on the M. sinensis, A. vulgaris and R. crataegitolius
Song, Suck-Hwan; Shin, Byung-Cheol;
  PDF(new window)
 Abstract
Rare earth contents(REE) were analysed for the plants, M. sinensis. A. vulgaris and R. crataegitolius, from two different soils serpentine area consisting of serpentinite(SP) and non-serpentine area, containing amphibole schist(AS) of Gapyeong area, and were compared with soils and host rocks. The AS were high with the differences of several times in the top soils, and with the differences of several to ten times in the host rocks relative to the SP. In the same area, the SP were high in the soil, but the rocks for the AS. In the plants, the A. vulgaris were high, but low in the R. crataegitolius. Root parts were higher than the upper parts. Differences between the upper and root parts were big in the SP rather than the AS, and were big in the R. crataegitolius, but small in the M. sinensis. Among the parts of the plants, high elements were shown in the R. crataegitolius of the SP, and the A. vulgaris and M. sinensis of the AS. In the correlation coefficients, most of the REE showed positive relationships among the element pairs, especially high positive correlation coefficients in the upper parts of the SP.Differences of the soils and plants(average) were smalle in the M. sinensis and big in the R. crataegitolius. In the upper parts. contents of the A. vulgaris were close to the soils while the R. crataegitolius showed large discrepancies with the soils. In the root parts, contents of the A. vulgaris showed discrepancies with the soils regardless of soil types, but close in the R. crataegitolius of the SP and M. sinensis of the AS.
 Keywords
Rare earth element;M. sinensis;A. vulgaris;R. crataegitolius;Serpentinite;Amphibole schist;
 Language
Korean
 Cited by
 References
1.
Storozheva M. M., 1954, Teratological Phenomena in Pulsatilla patens under the Conditions of Nickel Ore Field(in Russ.), Trudy Biogeokhim. Lab., 10, 64-75

2.
Susuki J., 1952, Ultrabasic rocks and associated ore deposits of Hokkaido Japan, J. Fac. Sci. Hokk. Univ. Ser., 8, 175-210

3.
Baker A. J. M., Protocor J., Reeves R. D., 1992, The Vegetation of Ultramafic (Serpentinite) Soils, Intercepts Ltd., Andover, United Kingdom, 234pp

4.
Brooks R. R., 1987, Serpentine and its vegetation; A multidisciplinary approach, Dioscorides Press, Portland, Oregon, 454pp

5.
Dymek R. F., Brothers S. c., Schiffries C. M., 1988, Petrogenesis of ultramafic metamorphic rocks from 3800 Ma lsua supracrustal belt, western Greenland, J. Petrol., 29, 1353-1397 crossref(new window)

6.
Hebert R., Serri G., Hekinian R., 1989, Mineral chemistry of ultramafic tectonites and ultramafic to gabbroic cumulates from the major oceanic basins and northem Apennine ophiolites (Italy): A comparison, Chemical Geol., 77, 183-207 crossref(new window)

7.
Mittsede S. K., Stoddard E. F., 1989, Ultramafic Rocks of the Appalachian Piedmont. (ed.), Geol. Soc. Amer. Spec. Pub., 231, 103pp

8.
Spell T. L., Norrell G. T., 1990, The Ropes Creek assemblage:Petrology, geochemistry and tectronic setting of an ophiolitic thrust sheet in the southem Appalachians, Amer. J. Sci., 290, 811-842 crossref(new window)

9.
Moores E. M., Jackson E. D., 1974, Ophiolites and oceanic crust, Nature, 250, 136-138 crossref(new window)

10.
Girardeau J., Mercier J. C. C., 1988, Petrology and texture of the ultramafic rocks of the Xigaze ophiolite (Tibet): Constraints for mantle structurc beneath slow-spreading ridges, Tectonophy., 147, 33-58 crossref(new window)

11.
Mevel C., Canat M., Gente P., Marion E., Auzende J. M., Karson J. A., 1991, Emplacement of deep crustal and mantle rocks on the West median valley, Wall of the mark area (MAR), 23$^{\circ}$ N, Tectonophy., 190, 31-53 crossref(new window)

12.
Bodinier J. L., 1988, Geochemistry and petrogenesis of the Lanzo peridotite body, western Alps, Tectonophy., 149, 67-88 crossref(new window)

13.
Den T. E., 1969, Origin of ultramafic rocks, thcir tectonic setting and history: A contribution to the discussion of the paper, 'The origin of ultramafic and ultrabasic rocks' by P. J. Wyllie. Tectonophy., 7, 457-488 crossref(new window)

14.
Rampone E. M., Hofmann A. W., Piccardo G. B., Vanuggi R., Bottazzi P., Ottolini L., 1995, Petrology, mineral and isotope geochemistry of the external Liguride peridotites (Northern Apennines, Italy), J. Petrol., 36, 81-105 crossref(new window)

15.
송석환, 송윤섭, 2001, 충남 서부 신곡 지역에 분포하는 초염기성암의 광물 조성 및 지구화학, 자원환경지질, 34, 395-415

16.
오창환, 최선규, 송석환, 2002, 백동지역의 변성염기성암과 주변 편마암의 변성진화과정과 지구조적의미, 암석학회지, 11, 103-129

17.
우영균, 최석원, 박기화, 1991, 충남 예산지구 활석광산의 성인에 대한 연구, 광산지질, 24, 363-378

18.
김옥준, 김서운, 유병화, 박병권, 1974, 한국 지질도(1:50000), 가평 도폭 및 설명서, 한국자원연구소, 26pp

19.
Wee S. M., Choi S. G., So C. G., 1994, Preliminary study on ultramafic rocks from the Chungnam Province, Korea, Econ. Environ. Geol., 27, 171-180

20.
Yun S. P., Moon H. S., Song Y., 1994, Mineralogy and Genesis of the Pyoungan and Daeheung Talc Deposits in Ultramafic Rocks, the Y oogoo Area, Econ. Environ. Geol., 27, 131-145

21.
Song S. H., Choi S. G., Woo J. G., 1997, Genetic implications of ultramafic rocks from the Bibong area in the Kyeonggi gneiss complex, Econ. Environ. Geol., 30, 477-491

22.
송석환, 김명희, 민일식, 장인수, 1999, 충남 서부 백동 사문암지역 식물체내 중금속 함량, 한국토양환경학회지, 4, 113-125

23.
김명희, 민일식, 송석환, 1997, 사문암지역에서 생육하는 대나물(Gypsophola oldhamian)의 중금속 함량, 한국생태학회지, 20, 385-391

24.
Rollinson H. R., 1993, Using Geochemical Data:Evaluation, Presentation, Interpretation. Longman Scientific. Technical., UK, 352pp

25.
농촌진흥청, 1988, 토양화학분석법. -토양, 식물체, 토양미생물-, 농업기술연구소, 450pp

26.
Hoffinan E. L., 1977, Instrumental Nentron Activation in geo-analysis, J. Geochemical Exploritation, 44, 273-319 crossref(new window)

27.
Henderson P., 1984, Rare Earth Element Chemistry, Elsevier, Amsterdam, New York, 510pp

28.
Nesbitt H. W., 1979, Mobility and fractionation of rare earth elements during weathering of granodiorite, Nature, 279, 206-210 crossref(new window)

29.
Taylor S. R, McLennan S. M., 1981, The Composition and Evolution of Continental Crust: Rare Earth Element Evidence from Sedimentary Rocks, Phil. Tran. Roy. Soc., A301, 381pp crossref(new window)

30.
Homer F. A., Morrison R. S., Brooks R. R, Clemens J., Reeves R. D., 1991, Comparative Studies of Nickel, Cobalt and Copper Uptake by Some Nickel Hyperaccumulators of the Genus Alyssum, Plant and Soil, 138, 195-205 crossref(new window)

31.
Chaney R. L., Malik M., Lee Y. M., Brown S. L., Angle J. S., Baker A. J. M., 1997, Phytoremediation of soil metals, Manuscript for Current opinions in biotechnology, 248pp

32.
Nanda K. P., Viatcheslave D., Harry M., lIya R, 1995, Phyto- extraction: The use of Plants to Remove Heavy Metalsfrom Soils, Environ. Sci. Technol., 29, 1232-1235 crossref(new window)

33.
송석환, 민일식, 유선균, 이용규, 2006, 금산 인삼과 토양의 희토류 원소 함량 관계, 고려인삼학회지, 30, 31-40 crossref(new window)

34.
임수길, 김정규, 김동엽, 1996, 유용식물을 이용한 오염토양 정화기술 개발, 제1회 농업과학 심포지엄 21세기 농업과학 연구의 발전방향, 교육부 농업과학 심사평가위원회, 236-241

35.
정기채, 김복진, 한상국, 1993, 아연광산 인접지역 야생식물중의 중금속함량 조사, 한국환경농학회지, 12, 105-111

36.
Alina K. P., Henryk P., 1985, Trace Elements in Soils and Plants, CRC Press Inc., Boca Raton, Florida, 315pp