Temat: ice temperature - Katalog OPAC zbiorów

Skocz do pozycji: 1.

Tytuł:: Trends and fluctuations of river ice regimes in the Prypiat Basin, within Ukraine
Autorzy:: Gorbachova, Liudmyla
Afteniuk, Oleksandr
Khrystiuk, Borys
Lobodzinskyi, Oleksandr
Powiązania:: https://bibliotekanauki.pl/articles/2201937.pdf
Data publikacji:: 2023
Wydawca:: Instytut Meteorologii i Gospodarki Wodnej - Państwowy Instytut Badawczy
Tematy:: ice phenomena
air temperature
Prypiat River
homogeneity
stationarity
cyclic fluctuations
tendencies
Opis:: Information about the formation, destruction, and duration of river ice regimes is especially important for hydropower, shipping, fisheries, etc. Research into modern trends in river ice regimes and their spatial and temporal fluctuations is essential, especially in a changing climate. This study examines the trends and fluctuations of air temperature and ice regimes based on series of observations in the Prypiat River basin within Ukraine. Air temperature data from 17 meteorological stations and ice data from 29 water gauges were analyzed. A complex analytical approach involving statistical and graphical methods was employed. The Mann-Kendall statistical test, mass curve, residual mass curve, and combined graphs were used in the study. In the Prypiat River basin within Ukraine, observations of mean monthly air temperature, ice occurrence, freeze-up, and their duration are homogeneous (quasi-homogeneous) and stationary (quasi-stationary). The quasi-homogeneous and quasi-stationary characteristics are explained by the presence in the observation series of only increasing and decreasing phases of long-term cyclical fluctuations, which are incomplete. The trends of air temperature and ice regime correspond strongly, indicating the defining role of air temperature in the formation of ice occurrence and freeze-up. Since the end of the 1990s, the warming phase of air temperature in the autumn-winter period determines the appearance of ice and freeze-up later in the year. In March, the warming trend in air temperature, which began after 1988, determines the freezeup, break-up, and disappearance of ice earlier in the year. Thus, the duration of ice and freeze-up on the rivers has decreased.
Źródło:: Meteorology Hydrology and Water Management. Research and Operational Applications; 2023, 11, 1; 1--14
2299-3835
2353-5652
Pojawia się w:: Meteorology Hydrology and Water Management. Research and Operational Applications
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 2.

Tytuł:: Climatic change on King George Island in the years 1948–2011
Autorzy:: Kejna, Marek
Araźny, Andrzej
Sobota, Ireneusz
Powiązania:: https://bibliotekanauki.pl/articles/2051395.pdf
Data publikacji:: 2013
Wydawca:: Polska Akademia Nauk. Czytelnia Czasopism PAN
Tematy:: Antarctic
South Shetland Islands
climate
air temperature
air pressure
pre−cipitation
sea surface temperature
sea−ice
Źródło:: Polish Polar Research; 2013, 2; 213-235
0138-0338
2081-8262
Pojawia się w:: Polish Polar Research
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 3.

Tytuł:: Pronounced anomalies of air, water, ice conditions in the Barents and Kara Seas, and the Sea of Azov
Autorzy:: Matishov, G.G.
Dzhenyuk, S.L.
Moiseev, D.V.
Zhichkin, A.P.
Powiązania:: https://bibliotekanauki.pl/articles/49104.pdf
Data publikacji:: 2014
Wydawca:: Polska Akademia Nauk. Instytut Oceanologii PAN
Tematy:: climate
water temperature
anomaly
air temperature
sea ice
Barents Sea
Kara Sea
Azov Sea
hydrographic condition
winter condition
Źródło:: Oceanologia; 2014, 56, 3
0078-3234
Pojawia się w:: Oceanologia
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 4.

Tytuł:: Analiza struktury i czasu trwania zjawisk lodowych na Warcie na tle warunków termicznych w okresie 1991-2010
The analysis of the structure and duration of ice phenomena on the Warta river in relation to thermic conditions in the years 1991–2010
Autorzy:: Graf, R.
Łukaszewicz, J.
Jawgiel, K.
Powiązania:: https://bibliotekanauki.pl/articles/338625.pdf
Data publikacji:: 2018
Wydawca:: Instytut Technologiczno-Przyrodniczy
Tematy:: pokrywa lodowa
rzeka Warta
temperatura powietrza
termika wód
zjawiska lodowe
air temperature
ice cover
ice phenomena
Warta River
water thermal conditions
Opis:: W artykule przedstawiono wyniki analizy struktury i czasu trwania zjawisk lodowych na Warcie w latach 1991–2010. Przebieg zjawisk lodowych został opisany na tle zmian temperatury powietrza i wody oraz wskaźnika Oscylacji Północnoatlantyckiej (NAO). Określono formy zjawisk lodowych występujących na Warcie w poszczególnych cyklach jej zlodzenia. Zinterpretowano również zmienność temperatury wody w okresie zimowym i jej wpływ na liczbę dni ze zjawiskami lodowymi. W analizie zjawisk lodowych uwzględniono: charakter odcinka rzeki, na którym prowadzono obserwacje oraz stopień antropopresji, wyrażający się przekształceniem koryta rzecznego, wpływem urbanizacji w strefach większych ośrodków miejskich oraz oddziaływaniem zbiornika Jeziorsko. Na podstawie przeprowadzonych badań wyznaczono ogólną tendencję w zmienności zjawisk lodowych występujących na rzece, a także określono przyczyny zróżnicowania struktury zjawisk w ujęciu regionalnym. Stwierdzono związek pomiędzy przebiegiem i częstością zjawisk lodowych a warunkami termicznymi i fazami NAO.
The article presents the results of the analysis of the structure and duration of ice phenomena on the Warta River. The course of ice phenomena has been described against the background of air and water temperature, and North Atlantic oscillation (NAO) changes including. The forms of ice phenomena, exist on the Warta River in particular cycles of its icing, were determined. The variability of the water temperature in winter and its impact on the number of days with ice phenomena on the river has been taken into consideration. The analysis of ice phenomena has taken into account the nature of the section of the river on which observations were made, the scale of anthropopressure affecting the transformation of the riverbed, the impact of urbanization in the zones of larger urban centers and the influence of the Jeziorsko Reservoir. On the basis of the conducted research, a general tendency was determined for the variability of ice phenomena occurring on the river. Reasons for the differentiation of the structure of ice phenomena on a regional basis were determined. The results show in detail the connection between the course and frequency of ice phenomena and other hand thermal conditions and NAO phases.
Źródło:: Woda-Środowisko-Obszary Wiejskie; 2018, 18, 4; 5-28
1642-8145
Pojawia się w:: Woda-Środowisko-Obszary Wiejskie
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 5.

Tytuł:: New coupled atmosphere-ocean-ice system COSMO-CLM/NEMO: assessing air temperature sensitivity over the North and Baltic Seas
Autorzy:: Van Pham, T.
Brauch, J.
Dieterich, C.
Frueh, B.
Ahrens, B.
Powiązania:: https://bibliotekanauki.pl/articles/48930.pdf
Data publikacji:: 2014
Wydawca:: Polska Akademia Nauk. Instytut Oceanologii PAN
Tematy:: coupled atmosphere-ocean-ice system
temperature sensitivity
air temperature
Baltic Sea
North Sea
regional climate modelling
COSMO-CLM model
Źródło:: Oceanologia; 2014, 56, 2
0078-3234
Pojawia się w:: Oceanologia
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 6.

Tytuł:: Zmiany pokrywy lodów morskich Arktyki na przełomie XX i XXI wieku i ich związek z cyrkulacją atmosferyczną
Changes in the sea ice cover in the Arctic at the turn of the 20th and 21st centuries and their correlation with the atmospheric circulation
Autorzy:: Marsz, A. A.
Powiązania:: https://bibliotekanauki.pl/articles/260733.pdf
Data publikacji:: 2008
Wydawca:: Stowarzyszenie Klimatologów Polskich
Tematy:: Arktyka
cyrkulacja atmosferyczna
dipol arktyczny
lody morskie
dryf lodów
temperatura powietrza
Arctic
atmospheric circulation
Arctic Dipole
sea ice
drifting ice
air temperature
Opis:: W pracy dokonano analizy wpływu cyrkulacji atmosferycznej na obserwowane w ostatnich latach XX i pierwszych latach XXI wieku zmiany powierzchni lodów morskich w Arktyce oraz zmian temperatury powietrza w sektorze wschodniosyberyjskim i pacyficznym Arktyki. Wprowadzono nowy wskaźnik charakteryzu-jący cyrkulację atmosferyczną w basenie Morza Arktycznego – zmodyfikowany dipol arktyczny (zDA), będący miesięczną różnicą ciśnienia między rejonem Morza Beauforta a rejonem Tajmyru. Występowanie dodatnich faz zDA porządkuje i przyspiesza dryf lodów z mórz Wschodniosyberyjskiego, Czukockiego i zachodniej części Morza Beauforta oraz centralnych części Morza Arktycznego w kierunku Cieśniny Frama. Po roku 1999 gwałtownie wzrosła częstość występowania ekstremalnie dodatnich faz zDA, wydłużył się również czas ich występowania. W latach 1979-2007 zmiany charakteru cyrkulacji atmosferycznej opisanej przez zDA objaśniają ~42% zmienności rocz-nej powierzchni lodów w Arktyce i 46% zmienności powierzchni zlodzonej we wrześniu, czyli miesiącu, w którym zaznacza się minimum rozwoju lodów morskich. We wschodnich sektorach Arktyki działanie zDA pociąga za sobą wzrost częstości i intensywności adwekcji z południa, co powoduje również wzrost temperatury powietrza. Oszacowano, że gwałtowny wzrost wartości zDA, jaki nastąpił w roku 2007 wymusił, wraz ze zmniejszeniem się powierzchni lodów morskich, wzrost temperatury powietrza na stacjach wybrzeża Morza Czukockiego o ~1.3°C, na Morzu Beauforta o ~1.5°C. Taki stan wskazuje, że obecnie obserwowany gwałtowny spadek powierzchni lodów morskich w Arktyce nie stanowi rezultatu działania efektu cieplarnianego, lecz wzrost temperatury powietrza i spadek powierzchni lodów stanowi rezultat zachodzących zmian w cyrkulacji atmosferycznej nad Arktyką.
The observed, at the turn of the 20th and 21st centuries, rapid decrease both in sea ice extent and its area in the Arctic raise a question regarding the real spectrum of reasons influencing this process. A number of works indicate that the increase in the air temperature in the Arctic resulting from the greenhouse effect, is not responsible for the decrease in sea ice cover but the reduction of the ice cover is one of the main causes of the increase in temperature. The aim of this article is to analyse the influence of atmospheric circulation on the process of reduction of the sea ice cover area in the Arctic in the same period. The break of the so far observed correlations between the AO and air temperature (see Overland and Wang 2005, Graversen 2006, Maslanik et al. 2007) indicates that the reason for the decrease in sea ice area should be searched in the activity of other circulation patterns than AO. Starting with the Wu, Wang and Walsh notion of the Arctic Dipole and carrying out simulation of the directions and rate of the drifting ice, a conclusion can be drawn that a simple index being a modification of the ‘Arctic Dipole’ formulated by Wu et al. 2006 (notation zDA) can be used to describe the maximum effectiveness of the transport of ice from the Arctic and the ‘cleaning’ of the Pacific Arctic from ice (the East Siberian, Chukcha and Beaufort seas). This index can be calculated as a standardised difference between SLP between the Beaufort Sea centre and the Tajmyr centre (see Fig. 4). The presence of strong positive phases of zDA (see Fig. 5) is followed by a rapid increase in the export of ice from the Arctic and results in the decrease in the amount of many-year ice in the structure of the Arctic sea ice cover. The ice is then moved away from the coast of east Siberia and Alaska and equally fast moves along the great circle, along the Transarctic Current reaching the Fram Strait at the end. The presence of strong negative phase of zDA (see Fig. 5B) and the neutral phase (see Fig. 5C) creates favourable conditions for the increase in many-year ice in the sea ice cover and restricts the export of ice from the Arctic. In the period between 1949-2007 a gradual increase in time with the extreme positive phases of zDA (zDA . 1 .n) is observed, and the especially strong increase in the frequency of occurrence of extremely positive phases of zDA is noted in the years of the 21st century (see Fig. 6 and 7). The coefficient of correlation between sea ice extent in the Arctic in August and the number of months in a year with anomalously positive phases of zDA is equal –0.62 (p < 0.001, n = 27; 1979-2007). The same correlation with the annual ice area in the Arctic equals (–0.50, p < 0.008). The analysis of correlation of monthly differences in pressure (non-standardized) between the centre of the Beaufort Sea and the centre of the Tajmyr (notation DP) and the ice area in the Arctic indicates that statistically significant correlations occur if the periods they are averaged for, are longer (see Table 1). The condition is that the averaged period DP started earlier than the averaged sea ice area. The analysis of regression shows that in order to obtain a good model describing minimal (September) or mean annual sea ice extent in the Arctic the DP values from March, when the sea ice extent is the largest, should be taken into consideration as one of the independent variables. This gives explanation of the situation that for longer reduction of sea ice area during the summer season, atmospheric circulation favourable for ice export must appear with great advance (equations [1] and [2]). Changes in DP in the years 1979-2007 explain 42% of variances of mean annual sea ice area and 46% of minimal variances (September) in ice area in the Arctic. As the changes in sea ice area are controlled by the auto-regression process, the occurrence of the increased frequency of extremely positive zDA phases in the following years starting from 1988 (see Fig. 7), especially intensive in the years 2003, 2005 and 2007 resulted in the extreme record of minima of sea ice area, not noted before. The atmospheric circulation described with zDA index forces the flow of air from the south to the Beaufort, Chukcha, East Siberian and Laptev seas (see Fig. 5A and Fig. 14). This direction of advection should lead to the increase in surface air temperature (SAT) over the coasts of the above mentioned sea areas. Strong increases in annual SAT can be observed at the stations located on the coasts of the above mentioned seas. The monthly distribution of SAT values indicates especially strong increases in the months from the end of summer and autumn (see Fig. 10-12). The analysis of correlations between DP and monthly SAT at the stations located in that part of the Arctic (see Table 2) indicates the presence of generally weak correlations between the monthly values of DP and SAT. During winter season at the stations located in the western part of the analysed region (Laptev Sea: Kotielyj Island, Mys Shalaurov) the correlations are negative which means that with the increase in differences of pressure between the region of the Beauforf Sea and the region of the Tajmyr (increase zDA) SAT decreases there (in January these correlations are statistically significant). This state can be explained as resulting from advection of air cooled to a great extent over the Siberia. Positive correlations between SAT and DP can be observed at the remaining stations in December, January and February, i.e. in the period when the short wave radiation is scarce, almost null or null and the solid/fast ice reaches the coast line. There is no other explanation of this phenomenon then as the effect of advectional increase in temperature. Similar positive correlations between DP (and in this way also zDA) and the air temperature are observed over the entire analysed region in the summer months and at the beginning of autumn (July-September). At a number of stations in particular months these correlations are statistically not significant, reaching their maximum value at Vrangel Island (in August; r = +0.6; see Fig. 13). As the analysis indicates the summer and early autumn correlations are the direct effect of advection as well as indirect effect of zDA resulting in the area in the coastal waters free from ice. The increase in zDA is accompanied by the visible increase in SST in the summer and early autumn months, which consequently results in the increase in SAT in October. If the correlations between monthly temperature and DP are statistically significant then it is possible to carry out the analysis of regression. This analysis indicates that in the year 2007 in which zDA reached in the period from April to September extremely high values (see Fig.14), the increase in SAT which is influenced by atmospheric circulation, can be estimated as +0.9°C at Vrangel Island and +1.5°C in relation to mean many-year value at Barrow station. Thus, the influence of the atmospheric circulation defined by the zDA index in the Pacific sector of the Arctic indicates synergy – results both in the decrease in the sea ice area as well as in the increase in air temperature. Large restriction of sea ice area over summer season in these sea areas intensifies, in turn, the increase in SAT. The carried out analysis indicates that the observed changes in the area and age structure of the sea ice in the Arctic at the turn of the 20th and 21st centuries and during the first years of the 21st century are mainly connected with the activity of natural processes. The role of the greenhouse effect controlling the changes in sea ice cover of the Arctic, as the analysis shows, has been overestimated.
Źródło:: Problemy Klimatologii Polarnej; 2008, 18; 7-33
1234-0715
Pojawia się w:: Problemy Klimatologii Polarnej
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 7.

Tytuł:: Zmiany zlodzenia Morza Karskiego w latach 1979-2015. Podejście systemowe
Changes of sea ice extent on the Kara Sea in the years 1979-2015. System approach
Autorzy:: Styszyńska, A.
Marsz, A. A.
Powiązania:: https://bibliotekanauki.pl/articles/260907.pdf
Data publikacji:: 2016
Wydawca:: Stowarzyszenie Klimatologów Polskich
Tematy:: pokrywa lodowa
zmiany powierzchni lodów
THC
temperatura powietrza
temperatura wody powierzchniowej
Morze Karskie
Arktyka
Atlantyk Północny
ice cover
changes in sea-ice extent
air temperature
sea surface temperature
Kara Sea
Arctic
North Atlantic
Opis:: Praca omawia zmiany powierzchni lodów na Morzu Karskim i mechanizmy tych zmian. Scharakteryzowano przebieg zmian zlodzenia, ustalając momenty skokowego zmniejszenia się letniej powierzchni lodów. Rozpatrzono wpływ cyrkulacji atmosferycznej, zmian temperatury powietrza i zmian zasobów ciepła w wodach na zmiany zlodzonej tego morza. Analizy wykazały, że wszystkie zmienne opisujące zarówno stan zlodzenia jak i stan elementów klimatycznych są ze sobą wzajemnie powiązane przez różnego rodzaju sprzężenia zwrotne. W rezultacie tworzy się rekurentny system, w którym zmiany powierzchni lodów, wpływając na przebieg innych elementów systemu (temperaturę powietrza, temperaturę wody powierzchniowej) w znacznej części same sterują swoim rozwojem. Zmiennością całego tego systemu sterują zmiany intensywności cyrkulacji termohalinowej (THC) na Atlantyku Północnym, dostarczając do niego zmienne ilości energii (ciepła). Reakcja systemu zlodzenia Morza Karskiego na zmiany natężenia THC następuje z 6.letnim opóźnieniem.
The work discusses the changes in the ice extent on the Kara Sea in the years 1979-2015, i.e. in the period for which there are reliable satellite data. The analysis is based on the average monthly ice extent taken from the database AANII (RF, St. Peterburg). 95% of the variance of average annual ice extent explains the variability of the average of ice extent in ‘warm' season (July-October). Examination of features of auto-regressive course of changes in ice extent shows that the extent of the melting ice area between June and July (marked in the text RZ07-06) can reliably predict the ice extent on the Kara Sea in August, September, October and November as well as the average ice extent in a given year. Thus the changes in ice extent can be treated as a result of changes occurring within the system. Analysis of the relationship of changes in ice extent and variable RZ07-06 with the features of atmospheric circulation showed that only changes in atmospheric circulation in the Fram Strait (Dipole Fram Strait; variable DCF03-08) have a statistically significant impact on changes in ice extent on the Kara Sea and variable RZ07-06. The analysis shows no significant correlation with changes in ice extent or AO (Arctic Oscillation), or NAO (North Atlantic Oscillation). Variable RZ07-06 and variable DCF03-08 are strongly correlated and their changes follow the same pattern. Analysis of the relationship of changes in ice extent and variable RZ07-06 with changes in air temperature (the SAT) showed the presence of strong relationships. These correlations differ significantly depending on the region; they are much stronger with changes in air temperature in the north than in the south of the Kara Sea. Temperature of cold period (average temperature from November to April over the Kara Sea, marked 6ST11-04) has a significant effect on the thickness of the winter ice and in this way the thickness of ice in the next melting season becomes part of the "memory" (retention) of past temperature conditions. The thickness of the winter ice has an impact on the value of the variable RZ07-06 and on changes in ice extent during the next ‘warm’ season. As a result, 6ST11-04 explains 62% of the observed variance of the annual ice extent on the Kara Sea. SAT variability in the warm period over the Kara Sea (the average of the period July-October, marked 6ST07-10) explains 73% of the variance of annual ice extent. SAT variability of the N part of the Kara Sea (Ostrov Vize, Ostrov Golomjannyj), which explains 72-73% of the variance ice extent during this period, has particularly strong impact on changes in ice extent during warm period. These stations are located in the area where the transformed Atlantic Waters import heat to the Kara Sea. Analysis of the impact of changes in sea surface temperature (SST) variability on sea ice extent indicated that changes in SST are the strongest factor that has influence on ice extent. The variability of annual SST explains 82% of the variance of annual ice extent and 58% of the variance of the variable RZ07-06. Further analysis showed that the SAT period of warm and annual SAT on the Kara Sea are functions of the annual SST (water warmer than the air) but also ice extent. On the other hand, it turns out that the SST is in part a function of ice extent. All variables describing the ice extent and its changes as well as variables describing the nature of the elements of hydro-climatic conditions affecting the changes in ice extent (atmospheric circulation, SAT, SST) are strongly and highly significantly related (Table 9) and change in the same pattern. In this way, the existence of recursion system is detected where the changes in ice extent eventually have influence on ‘each other’ with some time shift. The occurrence of recursion in the system results in very strong autocorrelation in the course of inter-annual changes in ice extent. Despite the presence of recursion, factors most influencing change in ice extent, i.e. the variability in SST (83% of variance explanations) and variability in SAT were found by means of multiple regression analysis and analysis of variance. Their combined impact explains 89% of the variance of the annual ice extent on the Kara Sea and 85% of the variance of ice extent in the warm period. The same rhythm of changes suggests that the system is controlled by an external factor coming from outside the system. The analyses have shown that this factor is the variability in the intensity of the thermohaline circulation (referred to as THC) on the North Atlantic, characterized by a variable marked by DG3L acronym. Correlation between the THC signal and the ice extent and hydro-climatic variables are stretched over long periods of time (Table 10). The system responds to changes in the intensity of THC with a six-year delay, the source comes from the tropical North Atlantic. Variable amounts of heat (energy) supplied to the Arctic by ocean circulation change heat resources in the waters and in SST. This factor changes the ice extent and sizes of heat flux from the ocean to the atmosphere and the nature of the atmospheric circulation, as well as the value of the RZ07-06 variable, which determines the rate of ice melting during the ‘warm’ season. A six-year delay in response of the Kara Sea ice extent to the THC signal, compared to the known values of DG3L index to the year 2016, allows the approximate estimates of changes in ice extent of this sea by the year 2023. In the years 2017 to 2020 a further rapid decrease in ice extent will be observed during the ‘warm' period (July-October), in this period in the years 2020-2023 ice free conditions on the Kara Sea will prevail. Ice free navigation will continue from the last decade of June to the last decade of October in the years 2020-2023. Since the THC variability includes the longterm, 70-year component of periodicity, it allows to assume that by the year 2030 the conditions of navigation in the Kara Sea will be good, although winter ice cover will reappear.
Źródło:: Problemy Klimatologii Polarnej; 2016, 26; 109-156
1234-0715
Pojawia się w:: Problemy Klimatologii Polarnej
Dostawca treści:: Biblioteka Nauki

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Tytuł:: Przebieg i charakter zjawisk lodowych na wybranych odcinkach rzek przymorza o wysokim stopniu antropopresji na tle zmian klimatycznych zachodzących w strefie brzegowej Bałtyku
The course and the character of the ice phenomena in selected sections of Przymorze rivers with a high influence of anthropopressure in relation to the climate changes that occur in the coastal zone of the Baltic sea
Autorzy:: Lukaszewicz, J.T.
Powiązania:: https://bibliotekanauki.pl/articles/40537.pdf
Data publikacji:: 2017
Wydawca:: Szkoła Główna Gospodarstwa Wiejskiego w Warszawie. Wydawnictwo Szkoły Głównej Gospodarstwa Wiejskiego w Warszawie
Tematy:: przymorze
strefa przybrzezna
pobrzeze Baltyku
rzeki
przeplyw wody
zjawiska lodowe
zlodzenia wod
pokrywa lodowa
temperatura wody
temperatura powietrza
zmiany klimatyczne
coastal area
coastal zone
Baltic coastal zone
river
coastal river
water flow
ice phenomenon
ice cover
air temperature
water temperature
climate change
Źródło:: Acta Scientiarum Polonorum. Architectura; 2017, 16, 1
1644-0633
Pojawia się w:: Acta Scientiarum Polonorum. Architectura
Dostawca treści:: Biblioteka Nauki

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Skocz do pozycji: 9.

Tytuł:: Sekularne i ekstremalne procesy erozji wodnej gleb na Pojezierzu Drawskim
Secular and extreme soil erosion processes in the Drawskie Lakeland
Autorzy:: Majewski, Mikołaj
Powiązania:: https://bibliotekanauki.pl/articles/295194.pdf
Data publikacji:: 2020
Wydawca:: Stowarzyszenie Geomorfologów Polskich
Tematy:: gleba
erozja wodna
proces sekularny
proces ekstremalny
Pojezierze Drawskie
warunki meteorologiczne
rzeźba terenu
litologia
temperatura powietrza
opady atmosferyczne
klimat
pokrywa śnieżna
przemarznięcie gruntu
soil
water erosion
secular process
extreme process
Drawskie Lakeland
meteorological conditions
relief of the terrain
lithology
air temperature
precipitation
climate
ice sheets
Opis:: Soil erosion by water is one of the most important factors affecting contemporary landscape changes within the lowland geoecosystems in Central Europe. Soil erosion by water mainly depends on: rainfalls (especially its intensity and erosivity), length of slope and its inclination, type of cultivation and usage of land, anti-erosion treatments and susceptibility of soils to erosion. The aim of conducted research was to evaluate conditioning and magnitude of secular and extreme soil erosion processes in the Drawsko Lakeland with special considering of rainfall erosivity index (EI30). The main goal was realised through several research tasks. The first task involved examination of surface runoff and slope wash conditionings, course and quantity in the testing plot located within the Chwalimski Potok catchment. The second task was related to evaluate rainfall impact to soil erosion by water processes. It was realised by computation rainfall characteristics: intensity, kinetic energy and erosivity. In order to assess secular and extreme soil erosion impact to land relief changes, research were provided with additional details by conducting three field experiments with simulated rainfall. Stationary observation and quantitative researches of soil erosion (at testing plots) have been conducting within the Chwalimski Brook catchment for three hydrological years (2012–2014). The slope with the test area is located within the 1st order catchment being a subsystem of the Młynski Brook catchment and then followed by the upper Parsęta catchment. This area covers 4.8 hectares and is characterised by short slopes with small height variances up to 10 meters. Historically, the area was covered with agricultural crops, currently they cover about 10% of the area. The slope is covered with gleyic retisols and its average inclination is about 4 degrees with its south-east exposure. The measuring system of soil erosion covered 5 testing plots with different agricultural use (bare fallow, meadow, potatoes, spring and winter crops). Plots are 42 metres long and 4 metres width. In the bottom edge of each plot catchers with volume of 800 dm3 were installed. In this research, only data from black fallow were considered. Such tillage is recognised as a standard in soil erosion studies. Two experiments have been conducted in this testing plot. The third one has been conducted on slope located within an area of undulated morainic plateau in the Kłuda catchment. The slope is characterised by greater height variances than in Chwalimski Brook catchment. The slope, where the experiment has been conducted, is situated within local closed depression and is covered by sands underlain by boulder clay. Its average slope is about 10° with its southwest exposure. Although annual precipitation in the three-year measurement period was comparable with mean value from multi-year period (1987–2014), its intensity and erosivity were distinguishably lower. Such rainfall conditions are not favourable for extreme soil erosion by water processes, thus any relief forms from such geomorphological processes were not observed in the Drawsko Lakeland. Due to lack of that kind of forms, in 2013 and 2014, three field experiments were conducted. The main aim of experiments was to evaluate the impact of high intensity rainfall on soil surface. The first experiment consisted of 5, the second and the third of 4 rainfall simulations. The rainfall was created by using a purpose-built rain simulator, consisting of 3 and 6 sprinklers placed around the testing plot. Despite the slope inclination in the Kłuda catchment was 2.5 times steeper than Chwalimski Potok’s slope, surface runoff attained smaller volume, because of remarkably higher infiltration rate. In 2012–2014, surface runoff and soil loss has occurred 8 times each year. The maximal monthly surface runoff volume was registered in February 2012, and it equalled 10.1 dm3 m−2 and the maximal soil loss value was registered in May 2013 and equalled 3,198 kg ha−1. Annual runoff volumes were between 31.2 dm3 m−2 in 2012 and 38.8 dm3 m−2 in 2013, whereas annual soil loss values ranged from 740 kg ha−1 in 2012 to 5,700 kg ha−1 in 2013. Soil erosion values caused by simulated rainfall during field experiments were similar or significantly higher than annual values. Surface runoff was between 31.2 dm3 m−2 in the first experiment and 34.2 dm3 m−2 in the second one, whilst soil loss was between 4,632 kg ha−1 and 8,637 kg ha−1. The achieved experiment results have been compared with soil erosion rate achieved from stationary observations. The results show that runoff and soil loss considerably increase during rainfalls with high amount, intensity and erosivity. Furthermore, individual extreme erosive events may exceed annual (secular) soil erosion processes. Conducted stationary research indicates that annual soil erosion primarily depends on individual rainfall and erosive events, which considerably exceed mean values. In order to evaluate the soil susceptibility to erosion by water in the Drawsko Lakeland, high resolution potential and actual soil erosion risk maps were prepared. The qualitative assessment of soil erosion risk was based on geoinformation technologies. The model considers following conditions affecting the size of soil erosion: slope steepness and aspect, topographic factor LS (unit upslope contributing area), lithology, rainfall erosivity (Modified Fournier Index calculated from monthly and annual precipitation data) and land use and land cover from Corine Land Cover 2006. To prepare the map of potential soil erosion risk, land use from Corine Land Cover was not considered. Thematic maps have been reclassified into a 4-degree division. The results of the soil erosion risk assessment in the Drawsko Lakeland reveal the fact that a majority of its area is characterized by moderate or low erosion risk levels. Areas with high erosion risk are mostly located in the northern part of the Lakeland. The achieved results from stationary observations and field experiments may indicate that the soil loss magnitude significantly increases during rainfall with higher intensity, greater totals and accumulated in time rainfall events. This may confirm the high potential of soil erosion by water processes of above- -average magnitude and intensity in the discharge of material from agricultural used slopes.
Źródło:: Landform Analysis; 2020, 39; 1-106
1429-799X
Pojawia się w:: Landform Analysis
Dostawca treści:: Biblioteka Nauki

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