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1.
Vasil’chuk Yu. K. Vasil’chuk J. Yu. Alexeyev S. V. Budantseva N. A. Alexeyeva L. P. Vasil’chuk A. C. Kozyreva Ye. A. Svetlakov A. A. 《Doklady Earth Sciences》2019,489(2):1456-1460
Doklady Earth Sciences - This paper reports on the nature and history of the mineral-rich frost heave mounds—lithalsas—developed on the first terrace of the Sentsa River in Okinsky... 相似文献
2.
J. Yu. Vasil’chuk N. A. Budantseva Ju. N. Chizhova D. L. Golovanov A. N. Tkachenko Yu. K. Vasil’chuk 《Water Resources》2018,45(5):776-784
The results of studies of variations of δ18O values in river water in Crimea Peninsula in January–February 2015–2017 are given. The variation range of δ18О in river water over the three years of studies never exceeded 3‰. A tendency toward an increase in δ18О in the water of the Salgir, Kacha, Al’ma, Bel’bek, Biyuk-Karasu from their sources to mouths was identified and explained by a decrease in evaporation in the mouth areas of the rivers relative to their sources and upper reaches, and the inflow of isotopically light precipitation (rain and snow) into the rivers in their upper reaches. The values of δ18О in waters of the rivers with regulated stream were found to increase under the effect of the Simferopol Reservoir on the Salgir River and the Izobil’nenskoe Reservoir on the Ulu-Zen’ River. The values of δ18О in the upper reaches of the large rivers of Kacha and Bel’bek (the northwestern slope of the Crimean Mountains) vary from ?8.7 to ?9.7‰, except for the rivers of Al’ma (?7.7‰) and Kokozka (?10.2‰) because of the different shares of groundwater in the recharge of these rivers. 相似文献
3.
Vasil’chuk Yu. K. Makeev V. M. Maslakov A. A. Budantseva N. A. Vasil’chuk A. C. Chizhova Ju. N. 《Doklady Earth Sciences》2018,482(1):1216-1220
The aim of the work was to perform paleotemperature reconstructions for the Late Pleistocene and Holocene of Kotelny Island according to oxygen isotope analysis of syngenetic ice wedges. Variations of δ18O in the Late Pleistocene ice wedges formed on Kotelny Island are significant, exceeding 8‰ (from –30‰ to –22.9‰), while they are insignificant at –1.5‰ (from –23.1‰ to –21.6‰) for those in the Holocene. Reconstructions showed that the mean January temperature in the Late Pleistocene changed over 8 to 13°C. The mean annual temperature of frozen soils was about –19 or –20°C in the Late Pleistocene, and about –13 to –15°C in the Holocene, while the current temperature is about –14°C.
相似文献4.
A. P. Lisitzin Yu. K. Vasil’chuk V. P. Shevchenko N. A. Budantseva E. D. Krasnova A. N. Pantyulin A. S. Filippov Ju. N. Chizhova 《Doklady Earth Sciences》2013,449(2):406-412
This study aimed to analyze the oxygen isotope composition of water, ice, and snow in water bodies isolated from the White Sea and to identify the structural peculiarities of these pools during the winter period. The studies were performed during early spring in Kandalaksha Bay of the White Sea, in Velikaya Salma Strait and in Rugoserskaya Inlet. The studied water bodies differ in their degree of isolation from the sea. In particular, Ermolinskaya Inlet has normal water exchange with the sea; the Lake on Zelenyi Cape represents the first stage of isolation; i. e., it has permanent water exchange with the sea by the tide. Kislo-Sladkoe Lake receives sea water from time to time. Trekhtsvetnoe Lake is totally isolated from the sea and is a typical meromictic lake. Finally, Nizhnee Ershovskoe Lake exhibits some features of a saline water body. The oxygen isotope profile of the water column in Trekhtsvetnoe Lake allows defining three layers; this lake may be called typically meromictic. The oxygen isotope profile of the water column in Kislo-Sladkoe Lake is even from the surface to the bottom. The variability of δ18O is minor in Lake on Zelenyi Cape. A surface layer (0–1 m) exists in Nizhnee Ershovskoe Lake, and the oxygen isotope variability is well pronounced. Deeper, where the freshwater dominates, the values of ?18Îvary insignificantly disregarding the water depth and temperature. This fresh water lake is not affected by the seawater and is not stratified according to the isotope profile. It is found that applying the values of ?18Î and profiles of temperature and salinity may appear as an effective method in defining the water sources feeding the water bodies isolated from the sea environment. 相似文献
5.
Vasil’chuk Yu. K. Kurchatova A. N. Budantseva N. A. Rogov V. V. Chizhova Ju. N. 《Doklady Earth Sciences》2019,488(1):1137-1141
Doklady Earth Sciences - The vertical isotopic profile of the ice core of a Messoyakha-1 bulgunniakh (pingo)—was obtained. The pingo is situated at 68°30′32″ N,... 相似文献
6.
Doklady Earth Sciences - The main aim of this work is to study the oxygen isotope composition of Late Pleistocene syngenetic repeated ice wedges and to obtain a high-resolution isotope diagram... 相似文献
7.
Yu. K. Vasil’chuk A. C. Vasil’chuk N. A. Budantseva Ju. N. Chizhova W. Papesh Ye. Ye. Podborny L. D. Sulerzhitsky 《Doklady Earth Sciences》2009,429(1):1326-1332
The conditions and forming time of massive ice were specified (Bovanenkovo gas condensate field, Central Yamal). Here, massive
ice lies as stratums, laccoliths, stocks, and lenses. Three thousand boreholes 10–100 m in depth were analyzed. In 260 of
them massive ice was broached. The ice foot is situated from 1 to 57 m deep. The maximal thickness of ice broached with boreholes
came to 28.5 m; on average, it was about 8 m. The extension of massive ice is sometimes more than 2000 m, and its area is
quite often more than 10 km2. According to the radiocarbon method, loams of the third terrace, containing and overlapping ice deposits, were formed from
25 000 to 20 000 years ago or somewhat later. These strongly peat loams containing massive ice formed either in shallow sea
conditions or during periodical draining conditions of beaches or low laida, where organic matter appeared due to erosion
and deposition and accumulated during draining and overgrowing of drains. In more inclement conditions than at present, loam
deposits were frozen immediately, forming massive ice, which occupied the barely water-saturated layers. The oxygen isotope
composition (δ18O) of massive ice samples varied from −12.49‰ (here and further, relative to SMOW) to −22.95‰. The deuterium
concentration (δD) varied from −91.7 to −177.1‰. Deuterium kurtosis (d
exc) varied from 3.4 to 10.6‰. In one seam outcrop, the content of stable isotopes varied significantly. Here, at a depth of
0.2–0.8 m, the δ18O content varied by more than 10‰ (from −12.49 to −22.75), and the δD content, from −91.7 to −171.9‰. Such variations testify
about ice extraction upon freezing of water-saturated grounds in a closed system. According to palynological analysis of ice
stratums, numerous remains of unicellular green algae and diatoms were revealed. It is possible that this is evidence of the
existence of a fresh well, which was a source of water, feeding the layer. Most probably these were near-bottom silt waters
of a large lake or desalted bay, which were frozen syngenetically. This accentuates the new type of massive ice, syncriogenic
segregative ice, which probably formed 25 000–20 000 yr BP. 相似文献
8.
Yu. K. Vasil’chuk V. P. Shevchenko A. P. Lisitzin N. A. Budantseva S. N. Vorobiov S. N. Kirpotin I. V. Krizkov R. M. Manasypov O. S. Pokrovsky Ju. N. Chizhova 《Doklady Earth Sciences》2016,471(2):1284-1287
The purpose of this work is to study the variability of the isotope composition (δ18О, δD, d exc) of the snow cover on a long transect of Western Siberia from the southern taiga to the tundra. The study of the snow cover is of paleogeographic, paleogeocryological, and paleohydrological value. The snow cover of western Siberia was sampled on a broadly NS transzonal profile from the environs of Tomsk (southern taiga zone) to the eastern coast of the Gulf of Ob (tundra zone) from February 19 to March 4, 2014. Snow samples were collected at 31 sites. Most of the samples represented by fresh snow, i.e., snow that had fallen a day before the moment of sampling were collected in two areas. In the area of Yamburg, the snow specimens collected from the surface are most probably settled snow of different ages. The values of δ18О in the snow from Tomsk to Yamburg varied from–21.89 to–32.82‰, and the values of δD, from–163.3 to–261.2‰. The value of deuterium excess was in the range of 4.06–19.53‰. 相似文献
9.
Yu. K. Vasil’chuk N. L. Frolova E. D. Krasnova N. A. Budantseva A. C. Vasil’chuk L. V. Dobrydneva L. E. Efimova E. V. Terskaya Ju. N. Chizhova 《Water Resources》2016,43(5):828-838
The isotopic features of Lake Trekhtsvetnoe in the White Sea coast area were studied in 2012–2015 in both winter and summer. Lake Trekhtsvetnoe is a water body, separating from the sea, with constant vertical stratification throughout the observation period. Its isotopic, hydrophysical, and biological characteristics have been studied. By the isotopic profile of lake water body, three zones can be identified in the lake: (1) 0–1 m: mixolimnion zone with δ18O varying from–12 to–11.1‰; (2) 1.0–3.0 m: zone with transitional properties with δ18O varying from–11.1 to–5.5‰; (3) 3.0–7.6 m: monimolimnion zone with highest values of δ18O—from–5.5 to–4.7‰. 相似文献
10.
Yu. K. Vasil’chuk N. A. Budantseva A. C. Vasil’chuk A. A. Maslakov Ju. N. Chizhova 《Doklady Earth Sciences》2018,480(2):758-762
The isotope-oxygen composition of ice wedges, ground ice, ice of the intrusive-segregated seasonal mound, and segregated ice of Eastern Chukotka near Koolen Lake, the settlement of Lavrentiya on the Chul’kheveem River, the settlement of Lorino, and the city of Anadyr on the Onemen Bay coast was studied. The comparison of isotopic diagrams showed that the variations in δ18O of the Holocene ice wedges of Eastern Chukotka did not exceed 2‰, which indicates the insignificant variability of climatic winter conditions in the late Holocene. The long-term mean-January temperature values varied less than 3°C according to calculations from the equations of interrelation between air temperature and the isotopic composition of the wedges. 相似文献