НУУРЫН ХОТГОРЫН ГАРАЛ ҮҮСЭЛ БА ХАГАРЛЫН ХАМААРАЛ: БАРУУН МОНГОЛЫН ЗАРИМ НУУРУУДЫН ЖИШЭЭН ДЭЭР
Keywords:
Баруун Монгол, Нуурын хотгор, Морфометрийн шинжилгээ, ХагаралAbstract
The appearances of the lake depression, area of the lakes, and its geographical location have changed over time due to some influences. Lake depressions are an intracontinental basins formed by endogenous or exogenous processes. An area and volume of lake depression may have changed by dynamic processes, if depression is exogenic in origin. Some lake depressions are related with faults. Faults in Mongolia have been well studied, but study of lake depressions along faults and development is poorly. This study presents a results on the lakes along faults and their development, including the Bayan Lakes in the Uvs and Zavkhan provinces, respectively, and Ulaagchiny Khar Lake. We highlight that we revealed to make a new genetic classification of lakes in the western Mongolia and to identify a changes of water regime, and of lake area and volume, based on study results.
Downloads
References
Bayasgalan, A., Jackson, J., Ritz, J.F. and Carretier, S., 1999. Forebergs’, flower structures, and the development of large intra-continental strike-slip faults: the Gurvan Bogd fault system in Mongolia. Journal of Structural Geology, 21(10), 1285-1302.
Boyce, J. I., Pozza, M. R., Morris, W. A., Eyles, N., & Doughty, M., 2002. High-resolution magnetic and seismic imaging of basement faults in western Lake Ontario and Lake Simcoe, Canada. –In 15th EEGS Symposium on the Application of Geophysics to Engineering and Environmental Problems, European Association of Geoscientists & Engineers. 191-194
Canty, M. J., 2014. Image analysis, classification and change detection in remote sensing: with algorithms for ENVI/ IDL and Python. Crc Press. 244-349
Carretier, S., Ritz, J.F., Jackson, J. and Bayasgalan, A., 2002. Morphological dating of cumulative reverse fault scarps: examples from the Gurvan Bogd fault system, Mongolia. Geophysical Journal International, 148(2), 256-277.
Cunningham, D., 2005. Active intracontinental transpressional mountain building in the Mongolian Altai: defining a new class of orogen. Earth and Planetary Science Letters, 240(2), 436-444.
Cunningham, D., 2013. Mountain building processes in intracontinental oblique deformation belts: Lessons from the Gobi Corridor, Central Asia. Journal of Structural Geology, 46, 255-282.
Cunningham, D., Davies, S. and Badarch, G., 2003. Crustal architecture and active growth of the Sutai Range, western Mongolia: a major intracontinental, intraplate restraining bend. Journal of Geodynamics, 36(1-2), 169-191.
Cunningham, D., Dijkstra, A., Howard, J., Quarles, A. and Badarch, G., 2003. Active intraplate strike-slip faulting and transpressional uplift in the Mongolian Altai. Geological Society, London, Special Publications, 210(1), 65-87.
Enkhbold, A., Khukhuudei, U., Kusky, T., Tsermaa, B., & Doljin, D., 2021. Depression morphology of Bayan Lake, Zavkhan province, Western Mongolia: implications for the origin of lake depression in Mongolia. Physical Geography, 1-26.
Filosofov, V. P., 1967. The value of the map of potential relief energy for geomorphological and Neotectonic studies. Methods geomorphological. Novosibirsk: Science. Sib. Department. 193-198.
Florinsky, I. V., 1996. Quantitative topographic method of fault morphology recognition. Geomorphology, 16(2), 103- 119.
Gilvear, D., & Bryant, R., 2016. Analysis of remotely sensed data for fluvial geomorphology and river science. Tools in fluvial geomorphology, 103-132.
Grunert, J., Lehmkuhl, F., & Walther, M., 2000. Paleoclimatic evolution of the Uvs Nuur basin and adjacent areas (Western Mongolia). Quaternary International, 65, 171-192.
http://geomag.org/models/wdmam.html (accessed on 10 April 2019).
http://www.getech.com/contact/ (accessed on 19 April 2019).
Jensen, J. R., 1996. Introductory digital image processing: a remote sensing perspective (No. Ed. 2). Prentice-Hall Inc.. 233-239
Karatas, A., & Boulton, S., 2019. Morphometric characteristics of alluvial fans in Southern Turkey: implications for fault activity in the Anatolia, Arabia, Africa Triple Junction Region. 7(3): 9-29
Klein, M., 2001. Binnendünen im nördlichen Zentralasien: Uws Nuur Becken, Nordwestliche Mongolei. Geograph. Inst. d. Johannes Gutenberg-Univ. 55-63
Kovach, V. P., Kozakov, I. K., Salnikova, E. B., Yarmolyuk, V. V., Kozlovsky, A. M., & Terent’eva, L. B., 2013. Crustal growth stages in the Songino Block of the Early Caledonian superterrane in Central Asia: II. Geochemical and Nd-isotope data. Petrology, 21(5), 409-426.
Kozakov, I. K., Sal’nikova, E. B., Yarmolyuk, V. V., Kovach, V. P., Kozlovskii, A. M., Anisimova, I. V., ... & Erdenezhargal, C., 2013. Crustal growth stages in the Songino block of the Early Caledonian superterrane in Central Asia: I. Geological and geochronological data. Petrology, 21(3), 203-220.
Lamb, M.A., Hanson, A.D., Graham, S.A., Badarch, G. and Webb, L.E., 1999. Left-lateral sense offset of upper Proterozoic to Paleozoic features across the Gobi Onon, Tost, and Zuunbayan faults in southern Mongolia and implications for other Central Asian faults. Earth and Planetary Science Letters, 173(3), 183-194.
Launay, M., & Guerif, M., 2005. Assimilating remote sensing data into a crop model to improve predictive performance for spatial applications. Agriculture, ecosystems & environment, 111(1-4), 321-339.
Lehmkuhl, F., Grunert, J., Hülle, D., Batkhishig, O., & Stauch, G., 2018. Paleolakes in the Gobi region of southern Mongolia. Quaternary Science Reviews, 179, 1-23.
Mark, D. M., 1975. Computer analysis of topography: a comparison of terrain storage methods. Geografiska Annaler: Series A, Physical Geography, 57(3-4), 179-188.
Mats, V. D., 1993. The structure and development of the Baikal rift depression. Earth-Science Reviews, 34(2), 81-118.
Naumann, S., & Walther, M., 2000. Mid- Holocene lake-level fluctuations of Bayan Nuur (North–west Mongolia). Marburger Geographische Schriften, 135, 15-27.
Nixon, M., & Aguado, A., 2019. Feature extraction and image processing for computer vision. Academic Press. 344- 356.
Phillips, J. D., 2000. Locating magnetic contacts: a comparison of the horizontal gradient, analytic signal, and local wavenumber methods. In SEG Technical Program Expanded Abstracts, Society of Exploration Geophysicists. 402-405
Salem, A., Williams, S., Fairhead, D., Smith, R., & Ravat, D., 2008. Interpretation of magnetic data using tilt-angle derivatives. Geophysics, 73(1), L1-L10. 155-164
Sevastyanov, D. V., Shuvalov, V. F., & Neustrueva, I. Y., 1994. Limnology and Paleolimnology of Mongolia. St. Petersburg (in Russian), 59-94.
Shamir, G., 2006. The active structure of the Dead Sea Depression. Special Papers- Geological Society of America, 401, 15- 27.
Shinneman, A. L., Almendinger, J. E., Umbanhowar, C. E., Edlund, M. B., & Nergui, S., 2009. Paleolimnologic evidence for recent eutrophication in the Valley of the Great Lakes (Mongolia). Ecosystems, 12(6), 944-960.
Studinger, M., Karner, G. D., Bell, R. E., Levin, V., Raymond, C. A., & Tikku, A. A., 2003. Geophysical models for the tectonic framework of the Lake Vostok region, East Antarctica. Earth and Planetary Science Letters, 216(4), 663-677.
Theilen-Willige, B., Aher, S. P., Gawali, P. B., & Venkata, L. B., 2016. Seismic hazard analysis along Koyna Dam area, western Maharashtra, India: A contribution of remote sensing and GIS. Geosciences, 6(2), 20.
USGS Global Visualization Viewer. Available online: https://glovis.usgs.gov (accessed on 17 April 2020).
Walker, R.T., Nissen, E., Molor, E. and Bayasgalan, A., 2007. Reinterpretation of the active faulting in central Mongolia. Geology, 35(8), 759-762.
Walther, M., 2010. Paleo-Environmental Changes in the Uvs Nuur Basin (Northwest-Mongolia). 267-279
Yang, X., Li, W., & Qin, Z., 2015. Calculation of reverse-fault-related parameters using topographic profiles and fault bedding. Geodesy and Geodynamics, 6(2), 106-112.
Yarmolyuk, V. V., Kozlovsky, A. M., & Lebedev, V. I., 2017. Neoproterozoic magmatic complexes of the Songino block (Mongolia): A problem of formation and correlation of Precambrian terranes in the Central-Asian Orogenic Belt. Petrology, 25(4), 365-395.
Амарсайхан, Д., Ганзориг, М., 2010. Зайнаас Тандан Судлал болон Дүрс Мэдээнд Тоон Боловсруулалт Хийх Зарчмууд, Улаанбаатар хот, 55-61.
Баасан, Т., 2003. Монгол орны элс. Улаанбаатар хот, 65-66
Батчулуун, Е., 2020. Монгол орны физик газарзүй. Улаанбаатар хот, 20-28, 86- 144, 240-248.
Благонравов, В.А., Хасин, Р.А., Борзаковский, Ю.А., 1973. Геология МНР. Мoсква. Недра. 34-58
Болд, Я., 1987. Геоморфологийн үндэс ба судалгаа, Улаанбаатар хот, Улсын Хэвлэлийн газар, 94-96
Бямба, Ж (ер.ред.)., 2012. Геотектоник, Улаанбаатар хот, 122-123
Бямба, Ж., 2009. Литосферийн Плит Тектоник, Монголын Геологи ба Ашигт Малтмал. IV боть, Улаанбаатар хот, 126-128
Жадамбаа, Н., Бямба, Ж (ер.ред.)., 2009. Гидрогеологи, Монголын Геологи ба Ашигт Малтмал. VIII боть, Улаанбаатар хот, 215-216
Селиванов, Е. И., 1972. Неотектоника и геоморфология Монгольской народной республики. Недра. ис. 231-244.
Төмөр. С., Төмөртогоо. О (ред)., 2016. УУХҮЯ, АМГТ-ны газар, Магма Майнс ХХК-ы Яруу (M-47-XXXI)-гийн сери, геологийн хэвтээ 1:200000 масштабтай геологийн зураглалын материал
Цэгмид, Ш., 1969. Монгол орны физик газарзүй. Улаанбаатар хот, Улсын Хэвлэлийн газар, 23-78, 125-127, 185- 203.
Цэрэнсодном, Ж., 1971. Монгол орны нуур, Улаанбаатар хот, 7-17, 19-28, 51- 54.
Цэрэнсодном, Ж., 2000. Монгол орны нуурын каталог (цэс), Улаанбаатар хот, Шувуун Саарал хэвлэлийн үйлдвэр, 55- 67, 88-109, 134-156.
Downloads
Published
How to Cite
Issue
Section
License
Copyright (c) 2022 Геологийн асуудлууд
This work is licensed under a Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International License.
