• 암석학회지
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• 제2권2호
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• pp.122-129
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• 1993

We report Rb-Sr whole rock, K-Ar and fission track mineral ages for the Chuncheon granite in the Precambrian Gyeonggi massif. The Rb-Sr whole rock define an age of $196{\pm}9$ Ma with an initial ratio of $0.7159{\pm}0.0006$, suggesting that the granitic magma might have been generated from crustal sources (S-type), or probably mixed mantle and crustal materials, and emplaced into the massif in the late Triassic or the early Jurassic. K-Ar mineral ages of hornblende, muscovite and biotite are ~210 Ma, ~180 Ma and 166-170 Ma respectively, and fission track zircon and apatite ages are 65-70 Ma, ~35 Ma respectively. These ages indicate that the granitic magma might have been emplaced at about 7 to 9 km from the paleosurface, and rapidly cooled down up to $300^{\circ}C$ until middle Jurassic (~170 Ma) with a rate of about $10^{\circ}C$/Ma, due to thermal difference between the magma and the wall rock. During middle Jurassic to late Cretaceous (about 170-70 Ma), the granite pluton is assumed to have uplifted to 4 to 6 km level under the paleosurface with a rate of 30 m/Ma and slowly cooled down with a rate of about $1^{\circ}C$/Ma owing to relatively slow denudation of the massif. In late Cretaceous to the present, the pluton might have more rapidly uplifted to the present level with a rate of 85 m/Ma and rapidly cooled down with a rate of about $3^{\circ}C$/Ma compared to those of middle Jurassic to late Cretaceous time because of extensive igneous activities accompanied by tectonism in the Gyeonggi massif.

• 암석학회지
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• 제12권2호
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• pp.55-69
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• 2003

남미 콜럼비아의 골고나섬에서 산출된 스피네훽스 조직을 갖는 제3기 코마티아이트를 암석학적 및 지화학적으로 연구하여, 이전의 연구결과 (남아프리카, 서부 호주 그리고 캐나다 온타리오 지역의 선캠브리아기 코마터아이트와 골고나섬의 제3기 코마티아이트 등의 연구)와 비교하였다 이 시료는 암석의 비중(2.98), 밀도(3.2), 그리고 조암광물, 스피네훽스 조직, 주성분원소와 미량원소, 희토류원소 등의 함량 및 분포경향 등, 코마티아이트의 암석학적, 지화학적 특징을 잘 나타낸다. 특히 희토류원소의 분포경향은 이 골고나섬의 코마티아이트가 depleted mantle에서 만들어진 마그마로부터 결정된 것임을 암시하며, 이는 캐나다 온타리오 일대의 Munro Township지역의 선캠브리아기 코마티아이드와 아주 유사한 특성을 보여주는 Group I의 휘석 코마티아이트 또는 현무암질 코마티아이트임이 확실시된다.

• 자원환경지질
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• 제1권1호
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• pp.35-46
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• 1968

Some of geologists in Korea recently postlated that Okchon system previously known to be precambrian age was the metamorphosed sediments of post-Chosen (Ordovician and pre-Kyeongsang (late Jurassic to Cretaceous) periods, or even definitely of Triassic period simply on the basis of the fact that Okcheon system overlies the Great Limestone series of Chosen system of Camber-ordovician age, and of other few assumptions of minor importance. As a result of such correlation, thick series of metasediments and Okcheon system of unknown age were established in this particular region and vaguely correlated to Paleozoic and Mesozoic sediments. Recent study done by the author reveled that: 1) only the upper Okcheon bed of S. Nakamura was true Okcheon system, and the middle and lower Okcheon beds were excluded, because they were correlated to Cambrian and Permian sediments resfectively, 2) Sangnaeri, Seochangri, and rengam formations of unknown age, and Baekhwasan, Jobong, and Ihwaryeong formations of Okcheon system of also unknown age were the metamorphosed Yangdeok system of Cambrian age, all of these formations were differentiated by the previous workers and were equivalent to the middle Okcheon system of S. Nakamure, and. 3) These metamorphosed Yangdeok system overlaid apparently the Great Limestone series in forms of overthrust and klippe which were produced by the orogeny took place during post-Daedong and pre-Kyeongsang period (probably middle to the Jurassic). The Sobaeksan Range, folded mountain Chains was also formed by this orogeny. Thus, Okcheon system newly defined by the author is precambrain age and consists in ascending order of Kemyenogsan, Hyangsan dolomite, and Daehangsan quartzite formation which were previously classified into metasediments of unknown age, and Munjuri, and Hwangkanri, formations which were differentiated into Okcheon system unknown age by the previous workers, but are of reversed sequence. Myeongori and Bukrori formations of Okcheon System are regard by the author as part of Hwangkanri formation. Few other assumption of minor important taken by the previous workers as their positive evidences are carefully explained that they were misinterpreted.

• 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.

• 한국광물학회지
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• 제19권2호
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• pp.99-109
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• 2006

충남 금산 서북부 지역에 분포하는 화성암류에 대해 암석화학적 연구를 실시하였다. 이 지역에는 선캠브리아기의 흑운모편마암과 시대미상의 옥천층군, 그리고 이들을 관입 또는 분출한 중생대 쥬라기의 흑운모화강암 및 백악기의 화산암, 홍색장석화강암, 석영반암 등이 존재한다. 흑운모화강암은 연변부로 갈수록 점이적으로 우백질 암상을 나타내는데, 중심부로부터 연변부로 갈수록 $SiO_2,\;Na_2O,\;K_2O$의 성분은 증가하는데 비해 $Fe_2O_3,\;CaO,\;P_2O_5,\;MgO,\;TiO_2$ 성분은 감소하는 등 역누대구조를 나타낸다. 흑운모화강암과 석영반암은 비알칼리계열에 속하며, 우백질 흑운모화강암은 알칼리계열에 속한다. 또한 이들 화성암은 모두 I-type화성암에 속하며, 동시에 칼크-알칼리계열의 결정분화작용에 부합하는 양상을 나타낸다. 쥬라기의 흑운모화강암은 Eu의 부현상(negative anomaly)이 미약하여 마그마 분화초기의 특징을 나타내는 반면, 백악기의 석영반암은 부현상이 뚜렷하여 진화가 상당히 이루어졌음을 시사한다.

• 한국광물학회지
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• 제25권4호
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• pp.295-304
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• 2012

하동군 옥종면 월횡리에는 과거 개발하던 티탄철석 광산이 위치하며, 주변 지질은 선캄브리아기 지리산 편마암 복합체가 광범위하게 분포하고 이를 회장암이 관입하고 있다. 간극누적형 회장암체 내 티탄철 광체가 발달하고 있으며, Ti-광체 내 희토류원소를 포함하는 갈렴석이 맥상으로 발달하고 있다. 갈렴석의 CaO 함량은 11.02~12.81 wt%로 낮은 반면, ${\Sigma}R_2O_3$는 상대적으로 높은 17.21~21.58 wt% (R=Ce, La, Nd)의 범위를 보여준다. 갈렴석이 높은 방사능 이상치를 보여주는 이유는 갈렴석 내에 미립의 광물상으로 존재하는 토륨 광물인 톨라이트(thorite, $ThSiO_4$) 때문인 것으로 밝혀졌다. 톨라이트는 $3{\sim}6{\mu}m$ 크기의 입상으로 누대구조를 보여주며, 화학분석 결과 $ThO_2$는 65~72.78 wt%, $UO_2$는 5.49~12.78 wt%의 함량을 보였다. 이러한 광물학적 특성은 톨라이트를 함 REE 갈렴석을 찾는 방사능 탐사를 함에 있어 좋은 지시자로 이용할 수 있을 것으로 사료된다.

• 한국지하수토양환경학회지:지하수토양환경
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• 제15권6호
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• pp.9-16
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• 2010

Groundwater sampling was performed at 38 wells where they are located in the areas with high uranium and radon (marked as A and B, respectively) concentrations, which were based on the previous research results. In-situ parameters (temperature, pH, EC, Eh, DO) and natural radionuclides (uranium and radon) were analyzed to figure out the characteristics of groundwater environments. In-situ data did not show any relations to natural radionuclide data, which could be caused by groundwater mixing, depths of wells, and geological settings, etc. But the highest radon well presented relatively low temperature value and the highest uranium well presented relatively low pH values The highest uranium concentration ranging $1.14{\sim}188.19{\mu}g/L$ showed in the area of A region consisted of Jurassic two-mica granite. The areas of Jurassic biotite granite and Cretaceous granite in the A region have the uranium concentrations ranging $0.10{\sim}49.78{\mu}g/L$ and $0.36{\sim}3.01{\mu}g/L$, respectively. The uranium values from between wells of community water systems (CWSs) penetrating fractured bed-rock aquifers and personal boreholes settled in shallow aquifers near the wells of CWSs show big differences. It implies that the groundwaters of the two areas have evolved from different water-rock interaction paths that may caused by various types of wells having different aquifers. High radon activities in the area of B region composed of Precambrian gneiss showed ranging from 6,770 to 64,688 pCi/L. Even though the wells are located in the same geological settings, their rodon concentration presented different according to depth and distance.

• 한국광물학회지
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• 제26권4호
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• pp.285-297
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• 2013

하동군 북천면 직전리 일대에는 선캄브리아기 간극누적형 회장암체 내 티탄철석 광상이 발달하고 있다. 정밀 지질조사를 통한 노두 자료와 7개 공의 시추탐사 자료를 바탕으로 GOCAD S/W를 사용하여 티타늄의 자원량을 평가하였다. 티탄철석 광체의 지하 부존상태 및 규모를 예측하기 위해 3차원 모델링을 수행한 결과 5개 맥상 광체가 남북방향으로 발달하였으며, 지구통계학적 기법을 활용하여 평균품위 및 자원량을 산출한 결과 Ti 평균 품위 2.98 wt%, 티탄철석 광량 7,494,303톤 (Ti 223,330톤)이 산정되었다. 이번 연구에 수행된 3차원 모델링을 하동지역 회장암 내 티탄광상 전체에 적용함으로써 티타늄 광체의 3차원적 형태와 자원량 평가에 활용할 수 있을 것이다.

• 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.