• Journal of Species Research
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• 제6권1호
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• pp.59-67
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• 2017

Southwest Primorye is located in the southern most part of the Russian Far East. The flora of this area is one of the most thoroughly studied and contains 1,530 species of vascular plants, belonging to 622 genera and 154 families, representing 55.6% of the flora of the Primorsky Territory. The flora native to Southwest Primorye encompasses 1,356 species from 547 genera and 148 families. Adventitious plants are represented by 174 species from 127 genera and 37 families. Among other areas of the Russian Far East, only Southwest Primorye has flora in common with the Korean Peninsula, which contains plant species in the subtropical and tropical latitudes: Mitrasacme indica Wight, Halosciastrum melanotilingia [Boissieu] M. Pimen. et V. Tichomirov, Streptolirion volubile Edgew., Lipocarpha microcephala [R. Br.] Kunth, Pueraria lobata [Willd.] Ohwi, Belamcanda chinensis [L.] DC., Zoysia japonica Steud., Deinostema violacea [Maxim.] Yamazaki and Parthenocissus tricuspidata [Siebold et Zucc.] Planch. Most of the flora is represented by the species restricted to Southwest Primorye (seven endemic species) or the Korean Peninsula (seven hemiendemic species). A total of 50.2% of the 10 largest families are nemoral (preboreal) floras, located in the transitional zone of the boreal and nemoral floras. In terms of the structure of the ranked taxonomic spectrum of the largest families, the flora of Southwest Primorye is more similar to that of Northeast China with influence of the Korean flora.

• Journal of Ginseng Research
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• 제28권1호
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• pp.60-66
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• 2004

“The Regional complex long-term program of restoration (reintroduction) of Primoryes ginseng population up to 2005” elaborated by Primorye governor administration, Regional Committee of Natural Resources and Russian Academy of Sciences operates in Russian Primorye. The Institute of Biology and Soil Science (IBSS) provides the scientific implementation of the program including the genetic analysis of extant ginseng populations, plant reproduction and off-spring identification. According to our investigations, the genetic resource of P. ginseng in Primorye is represented by three populations of wild-growing ginseng and a few pritate plantations. The results obtained by RAPD allowed concluding that the resource is dispersed among the wild and cultivated ginseng sub-populations in such a way that each of sub-populations studied has to be represented as a stock material to maintain species genetic variability. The allozyme analyses also showed that the small sub-populations of wild ginseng are characterized by unique genetic diversity and, therefore, they all need to be represented in reintroduction centers. Additionally the allozyme analysis discovered that the Blue Mountain and Khasan populations possess the most genetic diversity. So, at least one more reproductive ginseng unit has to be created besides two already existing reintroduction centers representing the Sikhote-Alin and the Blue Mountain populations.

• 고려인삼학회:학술대회논문집
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• 고려인삼학회 2002년도 학술대회지
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• pp.509-521
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• 2002

'The Regional complex long-term program of restoration (reintroduction) of Primoryes ginseng population up to 2005' elaborated by Primorye governor administration, Regional Committee of Natural Resources and Russian Academy of Sciences operates in Russian Primorye. The Institute of Biology and Soil Science (IBSS) provides the scientific implementation of this program including the genetic analysis of extant ginseng populations, plant reproduction and offspring identification. According to our investigations, the genetic resource of P. ginseng in Primorye is represented by three populations of wild-growing ginseng and a few private plantations. The results obtained by RAPD allowed concluding that this resource is dispersed among the wild and cultivated ginseng sub-populations in such a way that each of sub-populations studied has to be represented in living plant collection as a stock material to maintain species genetic variability. The allozyme analyses also showed that the small sub-populations of natural ginseng are characterized by unique genetic diversity and, therefore, they all need to be represented in reintroduction centers. Additionally the allozyme analysis discovered that the Blue Mountain and Khasan populations possess the most genetic diversity. So, at least one more reproductive ginseng unit has to be created besides two already existing reintroduction centers representing the Sikhote-Alin and the Blue Mountain populations.

• Ocean and Polar Research
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• 제23권1호
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• pp.35-49
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• 2001

An ichthyofauna analysis of the East Sea using quantitative investigation procedures for latitudinal variations of the species richness and clustering of the species list is presented to illustrate the application of the adopted geographical scaling (less than 1:10,000,000) which provides a principal opportunity for common benthic and pelagic biogeographical zonation. The distribution of both pelagic and benthic marine fish biota at a scale of biosphere (or its major sections) was highly influenced by spatial nonuniformity of hydrological structure associated with the various water circulations and frontal zones. Following zoogeographical zonations were established for the East Sea: Osaka, East Korea, Primorye, North Primorye, Northern East Sea, Uetsu, Tsugaru, Soya and West Sakhalin.

• 한국제4기학회지
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• 제16권2호
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• pp.39-56
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• 2002

The results of geoarchaeological studies of the prehistoric cultural complexes on the Russian Far East (Primorye, or Maritime Province; the Amur River basin; and Sakhalin Island) are presented. Upper Palaeolithic sites are dated to ca. 40,000-10,500 B.P. They existed during the mild climate of the Chernoruchie interstadial (ca. 40,000-21,000 B.P.); during harsh climate at the Last Glacial Maximum, ca. 20,000-18,000 B.P., in several places on the Russian Far East (Primorye, Amur River basin, and Sakhalin); and during climatic amelioration in the Late Glacial time, ca. 16,000-10,500 B.P. The earliest Neolithic sites, represented by Osipovka and Gromatukha cultures, existed at ca. 13,000-10,000 B.P. in the environment of coniferous forests with admixture of broadleaved taxa. Since ca. 8000 B.P., Neolithic cultures appeared in all of the Russian Far East. They existed until ca. 3000 B.P., first during the Holocene Climatic Optimum, ca. 8000-5000 B.P., in the environment of coniferous-broadleaved forests, and later, at ca. 5000-3000 B.P., in the environment of birch-oak and coniferous forests.

• 한국지구과학회:학술대회논문집
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• 한국지구과학회 2010년도 춘계학술발표회 논문집
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• pp.134-134
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• 2010

Sea ices at the Tatarskiy Straitin the East/Japan Sea appear from November to April. Cold and fresh water, melted from the sea ices, may contain nutrients which are indispensable to spring bloom of phytoplankton and may provide a preferable condition to the spring bloom through changes in vertical structure of water column and stratification. Relation between the spring bloom along the Primorye coast and sea ices in the Tatarskiy Strait were investigated using multi-satellite multi-sensor data; ten-year SeaWiFS chlorophyll-a concentration data and PAR data, sea surface temperatures from NOAA/AVHRR, sea ice concentration and near-surface wind speed data from DMSP/SSMI, near-surface wind vectors from QuikSCAT, and others. We provided evidences of southwestward flowing cold water masses from sea ice and its relation of chlorophyll-a concentration. This study showed that year-to-year variations of chlorophyll-a concentration in spring were positively correlated with those of sea ice concentrations at the Tatarskiy Strait.

• Ocean and Polar Research
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• 제31권1호
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• pp.133-156
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• 2009

We have named the sea surrounded by the Korean Peninsula, Primorye of Russia, and Japanese Islands as the East Sea. Historically this region has been variously named the East Sea, Chosun Sea, and, more recently, Japan Sea and Sea of Japan. Since the scientific research papers can play important roles on the naming the sea, the status of naming the East Sea in international scientific journals was investigated. Among 472 papers in 46 international journals that we assessed, Japan Sea (or Sea of Japan) was used in 322 papers (68.2%), East Sea was used in 21 papers (4.4%), and parallel usage of East Sea and Japan Sea accounted for 27.3% (129 papers). In all scientific papers before the early 1980s, East Sea was not used. Since the first parallel usage of East Sea and Japan Sea in 1985, these designations has been increasingly used. After 2004, the parallel usage has replaced the single designation of Japan Sea.

• Journal of Species Research
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• 제2권1호
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• pp.91-98
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• 2013

An investigation of the karyotypes of two species of the genus Brachymystax (B. lenok and B. tumensis) has been done for the Russia Primorye rivers running to the East Sea basin, and others belonging to Amur basin. Based on the analysis of two species chromosome characteristics, combined with original and literary data, four cytotypes have been described. One of these cytotypes (Cytotype I: 2n=90, NF=110-118) was the most common. This common cytotype belongs to B. tumensis from the rivers of the East Sea basin and B. lenok from the rivers of the Amur basin, i.e. extends to the zones of allopatry. In the rivers of the Amur river basin, in the zone of the sympatric habitat of two species, each taxon has karyotypes with different chromosome numbers, B. tumensis (2n=92) and B. lenok (2n=90). Because of the ability to determine a number of the chromosome arms for these two species, additional cytotype have been identified for B. tumensis: Cytotype II with 2n=92, NF=110-124 in the rivers basins of the Yellow sea and Amur river and for B. lenok three cytotypes: Cytotype I: 2n=90, NF=110 in the Amur river basin; Cytotype III with 2n=90, NF=106-126 in the Amur river basin and Cytotypes IV with 2n=92, NF=102 in the Baikal lake.

• 한국해양학회지
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• 제28권1호
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• pp.1-16
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• 1993

해수면의 계절적인 변동성을 조사하기 위하여 한국의 황해, 남해 및 동해안의 조위 관측점과 러시아, 일본의 동해에 연한 총 48개 관측점의 월평균해수면 자료를 분석 하였다. 해수면의 강한 계절적인 변화는 한국 서안의 군산(42.1 cm)과 대한 해협, 그리고 Primorye 지역의 남부 가까이(30-33 cm)에서 기록되었으며, 비교적 약한 변화는 사할린 남서해안에서 발견되었다. 남서 사할린을 제외한 전 연구지역에서 계절적인 해 수면 변동 양상이 거의 같다. 즉 여름과 가을에 상승하고 겨울과 봄에 감소하는 양상 이다. 이들 해수면자료의 스펙트럼 분석의 결과로 계절적인 진동이 해수면의 변위 중 에 가장 우세하며 연구해역의 함부에서는 전체 에너지의 80%에 달하고 북부에서도 50-70%에 달했다. 또, 대부분의 관측점에서 연주기 성분이 현저히 우세하며, 반년주기 성분도 명백히 나타났으나 그 이상의 고주파 성분은 단지 몇몇 관측점에서만 보일 정도이었다. 최소자승법을 사용하여 계산한 년수기 성분(A1)의 최대 진촉은 한국의 서안에서 20-21cm에 달하였다. 발년주기 성분은 사할린섬의 남단과 남서 해안에서 최대치 3-4cm인 것으로 밝혀졌다. 이지역의 년주기 해수면 변동폭은 여타지역보다 훨씬 작아서 전 에너지 수지에 대한 계절적 변도의 상대적 크기는 단지 35-40%에 지나지 않으며, 년수기와 발년주기의 진폭비(계절변동 계수 R=A1+A2)는 0.9-1.2로서 같은 크기임을 알수 있다. 이와 같은 해수면 자료의 분석과 Tomizawa et al.(1984)의 연구결과를 근거로하여 본 연구해역을 10개의 해역으로 나눌수 있다. 즉 황해와 한국의 남해 서부해안을 Y1과 Y2해역으로 동해를E1에서 E8까지 8개의 해역으로 나눌수 있다.

• 한국인구학
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• 제23권2호
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• pp.39-77
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• 2000

본 논문에서는 1860년대에서 1930년대까지 비농업직을 중심으로 하여 러시아 극동지역의 한인 이주민의 직업에 관하여 고찰한다. 먼저 이주민의 직업선택과 노동시장에서의 위치에 관한 이론들 즉 문화이론, 분절노동시종이론, 인적자본론 및 인종적 특수시장이론 등을 살펴보고 이들 이론이 러시아 극동지역 이주한인의 직업들 중 농업을 제외한 여러 가지 직종에 어떻게 적용되는지를 검토한다. 이러한 과정을 통해서 기존 이론들에서는 이주민의 직업에 관한 공급적 측면과 수요적 측면을 모두 분리하여 고찰하고 있다는 한계성을 지적한다. 이러한 한계성을 극복하기 위하여 본 논문에서는 러시아 극동지역 한인 이주민의 사례를 들어 이주민의 직업에 관한 두 가지 측면을 모두 통합해야 할 필요성을 설명하고 이를 위해 공급적·수요적 측면을 모두 고려할 수 있는 통합적 모델을 제시한 후 이러한 모델에 따라 러시아 극동지역 한인이주민의 직업에 영향을 키친 요인들을 광업, 어업, 자영업종, 서비스직종, 기타 단순 노무직 등으로 나누어 고찰한다. 마지막으로 이주의 통합적 모형에서 공급적 측면에 포함되는 것으로서는 한인의 농업중심적 성격, 이민직전의 조선에서의 사회경제적 모순 및 한인의 자급자족적 성격 등과 수요적 측면에서는 러시아의 이민정책과 러시아 극동의 다양한 지역적 상황이 고려되어야 함을 지적하였다.