• 한국광물학회지
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• 제27권4호
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• pp.235-242
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• 2014

우라늄은 자연적 원인과 인위적 원인에 의해 오염이 가능하지만 국내 지하수 토양환경에서는 자연적 원인에 의한 오염 가능성이 높다. 우라늄은 방사성 독성과 화학적 독성을 동시에 갖고 있어 먹는 물에 포함될 경우 그 위해성이 매우 높다. 본 연구에서는 경북지역의 마을상수도 및 소규모 급수시설, 지하수, 샘물 및 먹는 샘물, 먹는 물 공동시설, 지하수 측정망, 민방위비상급수 등의 시료를 대상으로 우라늄 농도를 측정하였으며 국내외 수질 기준과 비교하여 오염 정도를 평가하였다. 총 803개의 시료 중 미국의 먹는 물 권고기준 또는 우리나라의 권고기준인 $30{\mu}g/{\ell}$를 초과하는 시료의 수는 6개이며 전체시료에서 차지하는 비율은 0.7%이다. 모암의 특성에 따른 우라늄의 농도는 흑운모화강섬록암, 흑운모화강암, 편마상화강암 등과 같은 화강암질 암석이 분포한 지역에서 비교적 높게 나타났다.

• 암석학회지
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• 제15권1호
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• pp.1-9
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• 2006

산청지역에 분포하는 중생대 심성암 복합체의 하나로 산출되는 섬장암체에 대한 Rb-Sr 연대측정을 실시하였다 그 결과 $211{\pm}23(2\sigma)$ Ma의 연대와 $0.70598{\pm}0.00060$의 $^{87}Sr/^{86}Sr$ 초기치를 구했다. 이러한 연대는 산청 섬장암이 중생대의 삼첩기-쥬라기 경계시기 부근에 형성된 암체임을 확인한다. 또한 낮은 $^{87}Sr/^{86}Sr$ 초기치는 산청 섬장암의 생성과정에 오래된 지각물질의 영향이 적었음을 의미한다. 산청-마천 지역과 바로 인접한 북측의 함양-거창 지역에서 산출되는 동시기의 심성암체들 암상은 각각 섬장암-석록암-반려암과 화강암-화강섬록암으로 대조적이다. 또한 $^{87}Sr/^{86}Sr$ 초기치 역시 대조적인 것으로 판단된다. 이러한 차이는 국지적인 지구조적 환경의 차이를 반영하는 것일 가능성을 제기한다.

• 자원환경지질
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• 제11권2호
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• pp.47-57
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• 1978

The study focused on the petrology and petrochemistry of the so called "Ganghwa syenitic rocks" which intruded into metasediment of basement in southeastern part of Ganghwa Island. The geologic sequence of the mapped area was shown in table 1, 10 model analyses and 7 chemical analyses on the rock samples taken from the Ganghwa syenitic rocks and Manisan granite have been used to discuss the nomenclature of the rocks and petrological relationship between rock types. The petrograpical and petrochemical features based on, the analyses are as follows: 1) Ganghwa syenitic rocks consist of Ganghwa alkali syenite and Ganghwa diorite porphyry which based on the classification of the subcommision on systematics of igneous of IGUS. Ganghwa diorite porphyry which occured as dike forms are intruded into Ganghwa alkali syenite. The rock forming minerals of Ganghwa alkali syenite are composed of perthite, plagioclase, quartz, hornblend and chlorite in major, and zircon, apatite, sericite and magnetite in minor. Ganghwa diorite porphyries consist of plagioclase, biotite, hornblend, orthoclase and chlorite, with, porphyritic texture. 2) In silica-oxides variation (Fig. 2) and AMF diagram (Fig_ 3), the Ganghwa alkali syenite is similar to the trend of Daly's average basalt-andesite-dacite-rhyolite than Skaergaard which shows the trend of the fractional crystallization of magma, and equivalent to the alkali rock series by Peacock. 3) The general trend of data points shift to plagioclase, and are superimposed on the alkali rich terminal part of the granodiorite province of SW Finland in normative Q-Kf-Pl(Fig. 4) and Or-Ab-An diagram respectively. The above-mentioned evidences suggested that the Ganghwa syenitic rocks are the differential products resulted by assimilation of intermediated magma and metasedment rock under relatively rapid cooling condition.

• 자원환경지질
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• 제30권2호
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• pp.163-174
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• 1997

Precambrian metapelites and metapsammites of the Jinan-Osu area (so-called Seologri and Yongamsan Formation) consist of black slate, phyllite, mica schist, quartzite and rarely calc schist. They are intruded by Sunkagsan granite gneiss, Foliated granodiorite, Amphibolite, Sunchang foliated granite and Namwon granite. Mylonite texture, crenulation cleavage and minor shear zone are common. The meta-sedimentary rocks include various rock-fragments xenoliths in size (up to 3 cm) and rock-type. They have various porphyroblastic spots in size (up to 1 cm) and their mineral composition is different. The xenoliths are schists, granite and quartzite, which are rectangular or lens form and recrystallized muscovite, chlorite and quartz. Spots are andalusite and biotite aggregates extensively replaced by chlorite. The metamorphic terrain is divided into three zones of progressive metamorphism on the basis of mineral assemblage. They are chlorite zone, chloite-biotite zone and andalusite-biotite zone ascending order, from west to east approximately. Isograd reactions are phengitic muscovite + chlorite = less phengitic muscovite + biotite + quartz + $H_2O$ and muscovite + chlorite + quartz = andalusite + biotite + $H_2O$ between the chlorite zone and chlorite-biotite zone, and between the chloritebiotite zone and andalusite-biotite zone, respectively. Sample B6 (exposed near the Obong-ri) includes staurolites and greenish biotites, that is different in mineral assemblage and chemical composition from the meta-sedimentary rocks. Sample A12 (exposed near the Shinam-ri) has greenish white spots (up to 1 cm in diameter) mainly composed of Kfeldspar, quartz and sillimanite replaced by muscovite.

• 한국지구과학회지
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• 제23권1호
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• pp.87-96
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• 2002

Aeromagnetic and gravity data were analyzed to delineate the subsurface structure of the Yeongdong basin and its related fault movement in the Okcheon fold belt. The aeromagnetic data of the total intensity (KIGAM, 1983) were reduced to the pole and three dimensional inverse modeling, which considers topography of the survey area in the modeling process, were carried out. The apparent susceptibility map obtained by three dimensional magnetic inversion, as well as the observed aeromagnetic anomaly itself, show clearly the gross structural trend of the Yeongdong basin in the direction on between $N30^{\circ}E$ and $N45^{\circ}E$. Gravity survey was carried out along the profile, of which the length is about 18.2 km across the basin. Maximum relative Bouguer anomaly is about 7 mgals. Both forward and inverse modeling were also carried out for gravity analysis. The magnetic and gravity results show that the Yeongdong basin is developed by the force which had created the NE-SW trending the magnetic anomalies. The susceptibility contrast around Yeongdong fault is apparent, and the southeastern boundary of the basin is clearly defined. The basement depth of the basin appears to be about 1.1 km beneath the sea level, and the width of the basin is estimated to be 7 km based on the simultaneous analysis of gravity and magnetic profiles. There exists an unconformity between the sedimentary rocks and the gneiss at the southeastern boundary, which is the Yeongdong fault, and granodiorite is intruded at the northwestern boundary of the basin. Our results of gravity and magnetic data analysis support that the Yeongdong basin is a pull-apart basin formed by the left-stepping sinistral strike-slip fault, which formed the Okcheon fold belt.

• 자원환경지질
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• 제39권2호
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• pp.191-212
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• 2006

사금광상은 주로 따까오이 지역에 분포한다. 충적층은 미고화 또는 반고화된 자갈층, 사질층과 토양층으로 구성된다. 이들은 석탄기-페름기 편암과 백악기 화강섬록암위에 부정합으로 놓인다. 상 분석에 의하면 충적층은 하도 충진의 자갈과 모래 퇴적광상 및 범람원 토양광상을 포함하는 전형적인 하성퇴적광상으로 사료된다. 금 입자는 주로 자갈층 내에 함유되어 있으며, 자갈층을 구성하는 역들 중에서 석영맥 기원의 역들만이 금을 함유하고 있다. 이러한 양상은 원암이 석영맥이었고, 이동과 삭박작용 동안 석영맥으로부터 금입자가 분리되었음을 지시한다. 이 지역에서의 금 매장량은 최소 792kg에 달한다.

• 자원환경지질
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• 제3권4호
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• pp.199-222
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• 1970

One of the biggest sulfide metallic (Cu, Pb, Zn) ore deposits of South Korea is located in the area of Seo-myeon, Shiheung-gun, Gyeonggi-do. Geology of the region is mostly composed of metasediments of biotite schist, graphite schist, injection gneiss, sericite schist, limesilicate and quartzite from bottom, those are applicable to so-called Yeoncheon System of Pre-Cambrian, and granodiorite, quartz porphyry, basic dykes are outcroped in a small scope as intrusives. The origin of the ore deposit is pyrometasomatic contact deposits due to hydrothermal replacement and the ore bodies are imbedded in lower bed of limesilicate formation as impregnation and ore minerals are galena, sphalerite, marmatite, chalcopyrite, bornite, chalcocite, covellite, and the later two minerals are both hypogene and supergene. Gangue minerals are mostly skarn minerals those hornblende, diopside, epidote, hedenbergite, chlorite, garnet and quartz except primary calcite and quartz. Boundary plane (NS strike) between schists and limesilicate seemed to be primary opening of ore solution and fractures bearing $N50^{\circ}{\sim}80^{\circ}W$ are secondary structural control for localization of ore minerals and the third structural controls are both irregular gashes and schistosity in small scale. Photogeological study was carried with vertical aerial photo scaled 1: 38,000 and enlarged 1 : 10,000 under stereoscope. The study on the area convinced the fact that the geologic boundaries between rocks, limesilicates and quartzites, are traced easily by their typical topographic feature and drainage, and the main fracture patterns which derived from the result of fracture traces, that photogeologic lineament observed under stereoscope, are those bearing (1) $N20^{\circ}W$, (2) $N58^{\circ}W$, (3) $N76^{\circ}W$, (4) EW, (5) $N20^{\circ}W$, (6) $N62^{\circ}W$, (7) $N77^{\circ}W$. Among the written fractures, (5) (not schistosity, in case of fault) (6) (7) are post-mineral faults and others are pre-mineral faults and others are pre-mineral structures, and (2) (3) (6) (7) are coincided with statistical figure of 208 fractures surveyed in underground. By the result of the study, mineralized zone, are presumed to extend north and southward, total length about 4km.

• 보존과학회지
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• 제29권1호
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• pp.1-14
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• 2013

홍지문 오간수문은 홍지문에 부속된 홍예 수문이다. 이들의 주요 구성암석은 흑운모화강암, 홍장석화강암, 화강섬록암으로서 서울 인근에 분포하는 화강암류와 암석기재적 특징이 매우 유사하다. 오간수문에 나타난 손상현상은 주로 백색, 흑색 및 황색 변색이며 백화현상이 가장 심각하다. 5기의 홍예 수문에서 공통적으로 측벽의 변색이 천장보다 심하고, 천장에서는 종유석이 성장하고 있다. 오염물 분석 결과, 백화현상을 야기하는 물질은 다양한 형태를 보이는 방해석으로 판명되었다. 보존처리는 오간수문 전면에 대한 건식세정과 표면에 피각되어 있는 백화물질을 제거하기 위해 부분적으로 고압세척 및 백화제거제 등을 사용하였다. 현재는 일차적인 보존처리가 완료되어 양호한 상태를 보이고 있으나 향후 오간수문의 훼손을 저감하기 위해서는 수문 상부에 배수로를 확보하여 수분의 이동과 배출을 제어하는 것이 필요하다.

• 자원환경지질
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• 제18권4호
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• pp.381-397
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• 1985

A petrological study has been done in the pyeongchang-Jaecheon area which is a northwestern part of the basement of Ogcheon zone for the purpose of comparison of the area to the Nogjeon-Yeongchun area which is the antipodal basement of the zone in the petrological and geotectonical view points. The major units of the area are Precambrian granitic gneissic complex, banded gneiss, linea ted leucocratic gneiss and pegmatitic leucogranitic gneiss in the west, elongated exposure of quartz schist (or partly quartzite) and phyllite, named as Jungdaegal-bong Group correlated to the lower sequence of Joseon Group, in the middle, and limestone and calcic dolomite, Iptanri Formation, correlated to the middle of Joseon Group in the east. Igneous plutons are distributed in the areas of gneissic complex and limestone formation as well as in the Eosangcheon and Daedaeri areas in the southeastern out of the area. Present study reveals that the gneissic complex are the products of granitization to metamorphism of amphibolite facies in the order of above mentioned from the metasediments of schists and calcareous rocks. A notable characteristics of the phyllite of Jungdaegal-bong Group is the presence of syntectonically segregated quartz rods in the forms of lens, swirl or boudinage in evenly distributed in the phyllitic to chloritic matrix. Igneous rocks range in composition from gabbro through diorite, granodiorite, to schistosed and porphyritic granites in stock and dike. The orogenic movement of the Ogcheon zone initiated in the middle Proterozoic time, pre-sedimentation of Ogcheon Group and superposed the granitization in Permian, Jurassic Daebo orogeny with granitic batholiths and stocks, and Cretaceous plutonic intrusion.

• 자원환경지질
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• 제18권1호
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• pp.23-39
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• 1985

The northeastern part of Ogcheon zone which consisted mainly of Cambro-Ordovician arenaceous, argillaceous and calcareous formations and Carboni-Triassic arenaceous and argillaceous formations is delineated as the eastern mass of a thrust fault along Choongju-Moongyong-Cheongsan in the middle of the zone. The present study proposes a geotectonic line, Imgye-Samchog fault(see, figure 1) which divides the northeastern part into two blocks, Hambacksan block in the west and East coast block in the east. The igneous rocks in the Hambacksan block ranging from granite to gabbro are distributed in a symmetrical zones parallel to general direction of Ogcheon zone as follows (Fig. 2 and Table 2). Southeast igneous rock zone: it aligns Jurassic granites in its south and Precambrian leucocratic granites in its north. Central igneous rock zone: it aligns Cretaceous granites in its south and Jurassic granites, and some of diorite and gabbro in its north. Northwest igneous rock zone: aligns Jurassic granites in its south and huge batholithic granodiorite in its north. The distribution of the igneous rocks in the East coast block shows an entirely different features from those of Hanbacksan block. In the southern part of the block they assemble in a narrow area ranging in age from Early Proterozoic, through Middle to Late Proterozoic, Devonian, Jurassic, Cretaceous to Tertiary, whereas, the igneous rocks in the northern part of the block gathered to a restricted area, in ages of Middle Proterozoic and Cretaceous. The assemblage of the igneous rocks in the studied area shows a compositionally restricted, mixed S-type and I-type granites, $^{87}Sr/^{86}Sr$ > 0.706, rare volcanics and shortening with upright folding. These lithologic and structural features suggest that the igneous activity in this part related intimately to Hercynotype Orogeny of Pitcher(1979). Chronological episodes of igneous activity from Early Proterozoic to Early Tertiary in the northeastern part are figured.