• 한국제4기학회지
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• 제18권2호통권23호
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• pp.1-2
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• 2004

The Ilkwang Fault is NNE-striking, elongated 40 Km between Ulsan and Haendae-ku, Busan in southeastem part of the Korean Peninsula(Kim, D.H. et al., 1989; Kim, J.S. et al., 2003). This paper is mainly concemed about the ages of the fault activities especially in the Quatemary, infered from classification of geomorphic surface and trench excavation for the construction of Singori nuclear power plant. The geomorphi surfaces are classified into the Beach and the Alluvial plain, the 10 m a.s.l. Marine terrace, the 20 m a.s.l. Marine terrace, the Reworked surface of 45 m a.s.l. Marine terrace and the Low relief erosional surface, from lower to higher altitude. The Beach and the Alluvial plain are elongated to the Holocene terrace(ist terrace, choi, 2003). The 10 m a.s.l. Marine terrace is correlated to 2nd terrace (MIS 5em 125 Ka. y. B.P., Choi, 1998). The 45 m a.s.l. Marine terace is correlated to the Lower marine terrace (MIS 7,220 Ka. y. B.P., Choi, 2003 or MIS 9,320 y. B.P.) to the Gwanganri terrace(Penultimate interglacial age, 200-200 Ka. Y. B.P., Oh, 1981). The Low relief erosional surface is distributed coastal side, the Reworked surface of 45 m a.s.l. Marine terrace inland side by the Ilkwang Fault Line as the boundary line. But the former is above 10 m higher in relative height than the latter. The 20 m a.s.l. Marine terrace on the elongation line of the Ilkwang Fault reveals no dislocation. A site was trenched on the straight contract line with $N30^{\circ}$ E-striking between the 10 m a.s.l. Marine terrace and the 20 m a.s.l. Marine terrace. Fault line or dislocation was not observable in the trench excavation. Accordingly, the straight contact line is inferred as the ancient shoreline of the 10 m a.s.l. Marine terrace. The Ages of the Fault activities are inferred after the formation of the Ichonri Formation - before the formation of the 45 m a.s.l. Marine terrace (220 Ka. y. B.P. or 320 Ka. y. B.P.). The Low relief erosional surface was an island above the sea-level during the formation of the 45 m a.s.l. Marine terrace in the paleogeography.

• 한국지형학회지
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• 제25권4호
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• pp.63-75
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• 2018

The lower marine terrace 1 and 2 surfaces distributed between Ulsan and Pohang coast in the southeastern coast of the Korean penninsula have been correlated with MIS 5e and 5a (or 5c) by amino acid dates, 14C dates, wide-spread tephra correlation and pollen analysis respectively. In this study, to test the reliability of the OSL method for the estimation of the numerical burial age of marine sediment deposits, we analyzed the samples from the marine terraces which have been known as typical marine terraces formed during MIS 5e and MIS 5a in the above-mentioned coast. The burial ages of the marine deposit of the lower marine terrace 1 and 2, with paleoshoreline altitudes of 18m to 19m and 10m to 11m respectively, both showed about the same age of 60 ka BP. The lower marine terraces 1 and 2, however, were divided into two terrace surfaces by a clear terrace cliff. Besides, the OSL dates of the lower and upper parts of the lower marine terrace 2 of the Bonggil coast showed the reversed burial ages. In the lower marine terrace 1 of the Sanhari coast, almost the same burial ages were derived from both the lower part (marine rounded gravel layer) and the upper part (terrestrial angular gravel layer) of the terrace deposit. Therefore, at the present time, judging from only the OSL dates measured in this study, it could be argued that the OSL method is not the best for the estimation of forming periods of the lower marine terraces 1 and 2 and their classification.

• 한국제4기학회지
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• 제17권2호
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• pp.15-15
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• 2003

In South Korea, marine terraces have been well developed along the eastern coastal zone, and previous researches on the marine terraces have also been focused on to this coastal zone. The marine terraces of the eastern coast of South Korea had been classified into three terrace groups, that is, the higher, middle, and lower surface ones, according to the heights of marine terraces by previous studies(Oh, 1981 ;Chang, 1987 ;Yoon et. al, 1999, 2003 ; Hwang and Yoon, 1996 etc.). Recently, however, it tends to classify the marine terraces based on the concept of geomorphic surface units(Lee, 1987 ; Kim, 1990 ; Choi, S. 2003; Choi S. et. al 2003a,b, etc). For example, it was proposed that the marine terrace surfaces of Eupcheon coast of the southeastern coastal area of Korea could be classified into 16 geomorphic surfaces, i.e., Eupcheon 1terrace(former shoreline height of 160m), 2(153m), 3(140m), 4(130m), 5(124m), 6(115m), 7(100m), 8(92m), 9(82m), 10(71m), 11(62m), 12(53m), 13(43m), 14(35m), 15(18m) and 16(10m) surfaces, in descending order, according to the former shoreline heights(Choi, S, 2003 ; Choi, S. et. al, 2003a,b). Among these terraces, Eupcheon 1, 2, 4, 5 and 7 surfaces had not been reported in previous works. Among the above mentioned marine terraces, Eupcheon 15 terrace, the most widely and continuously distributed marine terrace have been identified as marine terrace of the Last Interglacial culmination period(oxygen isotope stage 5e) which was based on amino acid dates(124∼125ka BP) and geomorphological features such as red soil, pollen analysis, fossil cryogenic structures and crossing terrace concept. Eupoheon 15 terrace surfaces have also been proposed as the key surface for the identification and correlation of the so-called '5e' marine terrace in the eastern coast of South Korea. This terrace was reconfirmed as the Last Interglacial culmination period, which was based on the identification of Ata tephra, one of the wide-spread marker tephra which indicates the Last Interglacial culmination period in Japan by Sasaki et. al(2002). It was thought that marine terraces of the eastern coast of South Korea had been formed by the steady-state uplifting during the Quaternary glacio-eustatic sea level changes(Choi, 1997). The uprift rate of 10cm/1,000years had been proposed in the eastern coast of South Korea based on the former shoreline altitude(18m) of the above Eupcheon 15 terrace. Therefore, it can be estimated that Eupcheon 1 terrace had been formed in the early Pleistocene from the above uprift rate. The OSL dating for the samples of Eupcheon 7, 9, 13, 15 and 16 terraces and identification of marker tephra in the terrace deposits are in progress. It is expected that more elaborate chronology on themarine terraces of the eastern coast of South Korea could be established by these absolute dates and marker-tephra.

• 대한지리학회지
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• 제30권2호
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• pp.103-119
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• 1995

제4기 후기에 있어서도 지반의 지속적인 융기가 진행되고 있는 것으로 보이는 한국 의 동해안에 있어서는, 어느 한 간빙기 해성면의 동정이 이루어질 경우, 이 지형면을 시간기 준면으로 한 제4기 해성면 전체의 대비와 편년도 가능하다고 생각된다. 한국의 동해안에 있 어서 시간기준면으로 이용 될 수 있는 지형면은, 단구면과 퇴적물의 특징이 가장 잘 보존되 어 있을 것으로 보이는 최종간빙기의 해수면이라고 생각된다. 본고에서는 한반도의 중부 동 해안에 있어서 최종간빙기의 해수면을 확정하기 위한 작업의 일환으로, 단구면의 구정선고 도, 단구퇴적물의 특징, 그리고 고토양 및 화석 주빙하결빙구조 등을 지표로, 묵호-강릉해안 에 분포하는 저위해성단구의 대비와 상대편년을 시도하였다. 연구의 결과, 저위해성단구 I면 은 최종간빙기 극상기(산소 동위체 스테이지 5e), 그리고 II면은 최종간빙기의 중반(5c) 혹은 후기(5a)의 지형면으로 편년되었다. 이는 최종간빙기의 해성면을 I면 밖에 인정하지 않은 기 존의 연구결과와 다른 점으로서, 추후 이에 대한 상세한 검토가 요청된다. 저위해성단구 I면 과 II면의 구정선고도는 각각 18m, 10m이며, 이중에서도 저위해성단구 I면은 분포의 보편성 으로 보아 한국 동해안의 제4기 지사편집시 시간기준면으로서의 이용가치가 크다고 생각된 다.

• 한국지형학회지
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• 제26권4호
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• pp.81-96
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• 2019

The Yeongdeok 53m marine terrace (Y₅₃mT), Y₄₃mT, Y₃₃mT, Y₂₄mT, Y₁₉mT and Y₁₁mT distributed along the Yeongdeok coast, southeastern Korean Peninsula are well compared with the thalassostatic terraces of the high terrace 1 (ℓHT₁ ; 51m of the relative heights from the river floor), high terrace 2 (ℓHT₂ ; 43m), middle terrace 1 (ℓMT₁ ; 32m), middle terrace 2 (ℓMT₂ ; 25m), lower terrace 1 (ℓLT₁ ; 18m) and lower terrace 2 (ℓLT₂ ; 10m) respectively, developed along the lower reaches of the Chucksan-cheon and Obo-cheon rivers, judging from the comparison of paleosols (red soils) between the above marine and thalassostatic terraces. Using the Y₁₉mT of the MIS 5e as the key surface, we propose that the terraces of the Y₅₃mT and ℓHT₁, Y₄₃mT and ℓHT₂, T₃₃mT and ℓMT₁, Y₂₄mT and ℓMT₂, Y₁₉mT and ℓLT₁, and Y₁₁mT and ℓLT₂ have been formed at the MIS 11, 9, 7e and 7a (or 7a), 5e and 5a respectively. The red soils have been developed at the Y₁₉mT and ℓLT₁ and above them, but not on the Y₁₁mT and ℓLT₂ surfaces.

• 한국지형학회지
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• 제23권2호
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• pp.47-59
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• 2016

The formation age and depositional environment of the marine terrace I of the estimated paleoshoreline altitude of 18m in Sanhari of Ulsan coast, southeastern Korea were investigated on the basis of examination of lithofacies and stratigraphy of terrace deposits. Marine deposits of the terrace is composed of rounded boulders(70cm in diameter) and rounded pebbles(1.0cm in diameter) which overlay them. The above rounded boulders which lie on the paleo-shore platform are considered to have been formed by wave abrasion in the same period that the paleo-shore platform was developed. The rounded pebbles which lie on the rounded boulder layer are considered to have been deposited in gravel beach and berm environment, judging from the laminae developed in this layer. The paleo-shore platform and marine rounded gravel layer of the terrace are assumed to have been formed in the large transgression period of the Last Interglacial culmination stage(MIS 5e), judging from the comparision of the formation age of 125ka B.P. of Juckcheon terrace I in the adjacent Pohang coast which was dated by amino acid dating. The terrestrial deposit of this terrace was largely composed of angular and subangular gravel mixed with marine rounded pebble which has been carried away mainly from the deposit of previous marine terraces and redeposited in this terrace. The lowest peat layer of terrastrial deposit was considered to have been deposited during the period from the late MIS 5e which is the estimated finishing time of deposition of the above marine gravels to the early stage of following regression period(MIS 5d) in which the sea level was still high. The sediments of angular and subangular gravel deposit which lie on this peat layer were assumed to have been deposited during the period from the early stage of the first regression period(MIS 5d) of the Last Interglacial to the Last Glacial. The lower part of the angular gravel layer is composed of the deposits of the fluvial and colluvial sediments, whereas most of the upper and middle part of the layer is mainly composed of angular gravels of colluvial sediments formed in the cold environment.

• 한국지형학회지
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• 제23권2호
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• pp.95-108
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• 2016

Several flights of marine terraces were developed along the Eastern coast of Korea (Gangneung-Donghae). Various dating techniques have been applied to determine the age of these terraces, with a view to better understand the regional uplift history. In this study, we compare the major element compositions of the terrace deposits and modern beach sediments to estimate the relative formation age of these terraces. We observed a discernible difference in major element geochemistry between modern beach sediments and various elevated terrace deposit (i.e. palaeobeach sediments). In general, weathering properties of marine terrace sediments are expected to be affected by the formation ages of terraces, and here, we confirm that the chemical composition are indicative of the relative age of the terraces in this region.

• 한국지형학회지
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• 제26권4호
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• pp.67-79
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• 2019

This study documents the level of paleo-shoreline and the timing of formation of the lowest marine terrace (1st terrace) distributed in Dadaepo, Busan, South Korea. In the study area, the elevation of paleo-shoreline of the 1st terrace is clearly identified as 5 meters above mean high tide based on the elevation of wave-cut platforms and the elevation of boundary between marine and terrestial sediments. This is well consistent with the fact that are found along the Southern coast of the Korean Peninsula including Daepo-dong, Sacheon-si. The timing of formation of the 1st terrace in Dadaepo is confirmed to have been deposited around 70,000~80,000 years BP (MIS 5a) according to OSL and IRSL dating ages. However, because the formation age of the 1st terrace in Sacheon-si Daepo-dong (Southerm coast) and Pohang-si Umok-ri (Eastern coast) previously identified as about 90,000~100,000 years BP (MIS 5c), further discussion of what is needed. Possibly, it can be interpreted that the sub-interglacial (MIS 5a and 5c) sea-level records during the last interglacial period are likely to be selective on land depending on regions.

• 대한지리학회지
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• 제41권3호
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• pp.346-360
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• 2006

본 연구는 우리나라 해안단구의 형성과정을 종합적으로 해석하기 위해, 연구가 거의 드문 남해안의 중앙부에 위치한 광양만 일대 해안을 대상으로, 해안단구의 분포, 퇴적층의 층서 및 퇴적물의 이화학적 특성을 밝히고, OSL 절대연대 자료를 기초로 해안단구의 형성시기를 추정하였다. 해안단구 퇴적물을 포함하여 광양만에 분포하는 다양한 지형 구성물질의 이화학적 특성을 분석한 결과, 지형 사이의 뚜렷한 차이가 나타나지 않았는데, 이는 광양만의 지형적 폐쇄성에 기인한 구성물질의 재순환 및 혼합의 결과로 판단된다. 광양만 일대 해안에는 규모가 작은 3단 이거 해안단구면이 발견된다. 고도가 가장 낮은 1면은 해발고도 $10{\sim}13m$에 분포하며, OSL 연대측정 및 퇴적물의 특성으로 보아, MIS 5a 시기에 형성된 것으로 판단된다. 광양만 일대의 융기율은 0.141m/ka로 계산되며, 이를 적용하면, 해안단구 2면(18-22m)은 MIS 5e, 3면($27{\sim}32m$)은 MIS 7시기의 후반에 형성된 것으로 추정된다. 따라서 신생대 플라이스토세 후반 우리나라 동해안과 남해안에서 지반 융기 및 해안단구의 발달 과정은 거의 유사했던 것으로 판단된다.

• 한국제4기학회지
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• 제18권1호통권22호
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• pp.21-30
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• 2004

일광단층은 NNE-SSW 방향으로 한반도 남동부의 울산에서 부산 해운대까지 연장되며 그 길이는 40 Km이다. 본 연구는 신고리 원자력발전소 1,2호기 건설과 관련된 일관단층석의 제4기 활동 여부를 판단하기 위해서, 지형면 분류와 트렌치 조사로 일광단층의 활동시기를 추정한 것이다. 일광역 부근의 해안에서 산록까지는 모래해안 및 충적면, 10m 해성단구면(MIS 5a), 20 m 해상단면(MIS 5e), 45m 해성단구면(MIS 7 or 9)의 변형면, 소기복침식면의 5개 지형면으로 분류된다. 일광단층선을 경계로 기반침식면은 해안 쪽에 분포하는데도 불구하고 내률 쪽의 45m 해성구면의 변형면 보다 비고가 10m 이상 높다. 그러나 동일한 단층선이 지나고 있는 20m 해성단구면은 변위를 나타내지 않는다. 10m 해성단구면과 20 m 해성단구면이 직선적으로 접하는 지대를 트렌치 조사하였으나 단층선이나 퇴적층의 변위를 관찰할 수 없어, 이 지대는 10m 해성단구면의 옛 해안선[구정선(구汀線)]으로 추정한다. 이에 45m 해성단구면 형성기의 고지리(古地理)로는 소기복침식면은 당시의 해수면 보다 높은 '섬' 이였을 것이며, 일광단층은 이천리층 형성 이후-45m 해성단구면 형성기(22만년 내지 32만년 전) 이전에 이루어졌을 것으로 판단한다.