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Przegląd Geograficzny T. 90 z. 1 (2018)
The purpose of the work detailed here was to reveal the diurnal variability characterising values for air temperature and vapour pressure in Poland. To this end, reference was made to meteorological data – concerning air temperature (°C) and water vapour pressure (hPa) – derived from eight observation terms over the period 1991-2000, and from the Polish cities of Koszalin, Białystok, Poznań, Warsaw, Wrocław and Rzeszów. These data were used to calculate average diurnal values for each of these meteorological elements, with graphs constructed to show the averaged daily courses for air temperature and water vapour pressure, as well as the course of averaged diurnal extreme values and amplitudes in regard to both elements, together with the hours associated with them. All analyses were carried out for consecutive ten-day periods of the year. Because of the uneven changes in the variables throughout the daytime, extreme values for air temperature and water vapour pressure were approximated using an asymmetric function. The diurnal courses to thermal and humidity conditions in the Polish cities under study are found to be characterised by a certain variability, both temporally and spatially. In particular, there are significantly fewer instances of stable weather conditions during the summer season, than in winter. The hours of occurrence of air temperature minima depend on the season. In winter they occur much later, about 5-6 a.m., while in the warm half of the year they are noted at approximately 2 a.m. Diurnal maxima for air temperature appear around the same time of day, usually at about 1 p.m. year-round. Analysis of the spatial structure characterising variability in diurnal air temperature showed SE Poland (Rzeszów) to be the warmest region in summer during daytime hours. Summer nights are hottest in the south-west (Wrocław) and middle part of Poland (Warsaw). In winter, the privileged stations in respect of thermal conditions are Wrocław and Koszalin, during daytime hours and at night respectively. The diurnal course sees water vapour pressure rise during the hours of daytime, and decrease at night. In turn, annual variability is characterised by significant summer increases and winter decreases. In the summer, the diurnal courses for water vapour pressure are characterised by the presence of two minima and two maxima per day. The first diurnal minimum is usually recorded in the morning, between 2 a.m. and 6 a.m., albeit slightly later in winter, while the second, appearing in the warm season, is observed between 12 a.m. and 4 p.m. In the case of the diurnal maximum, the first, is more seasonally dependent than the minimum, in that it occurs between noon and 4 p.m. in winter, most often around 8 a.m. A second one is noted between 4 and 8 p.m. The spatial range of occurrence of different values for water vapour pressure points to a rise in the western part of the country in the cool half of the year, while south-eastern Poland is more privileged in this regard in the summer.
1. Araźny A., Smukała K., 2011, Ocena bodźcowości warunków termiczno-wilgotnościowych w Polsce w przekroju południkowym w okresie 1976–2005, Annales Unversitatis Mariae Curie-Skłodowska, 66, 2, Lublin, s. 77–90.
2. Ballester F., Michelozzi P., Iniguez C., 2003, Weather, climate and public health, Journal of Epidemiology and Community Health, 57, s. 759–760. https://doi.org/10.1136/jech.57.10.759
3. Baranowski D., 2005, Dobowe amplitudy temperatury powietrza w Polsce i ich zależność od typów cyrkulacji atmosferycznej, Słupskie Prace Geograficzne, 2, Słupsk, s. 171–180.
4. Błażejczyk K., Kozłowska-Szczęsna T., 2010, Wpływ środowiska atmosferycznego na społeczeństwo, jako przedmiot badań biometeorologii społecznej, Przegląd Geograficzny, 82, 1, s. 5–48.
5. Błażejczyk K., Kunert A., 2011, Bioklimatyczne uwarunkowania rekreacji i turystyki w Polsce, Monografie, 13, IGiPZ PAN, Warszawa.
6. Błażejczyk K., Matzarakis A., 2007, Assessment of bioclimatic differentiation of Poland based on the human heat balance, Geographia Polonica, 8, 1, s. 63–82.
7. Brenner T., Lee D., 2014, Weather Conditions and Economic Growth – Is Productivity Hampered by Climate Change?, Working Papers on Innovation and Space, 6.
8. Diaz J., Garcia R., Velazquez de Castro F., Hernandez E., Lopez C., Otero A., 2002, Effects of extremely hot days on people older than 65 years in Sewille (Spain) from 1986–1997, International Journal of Biometeorology, 46, 1, s. 145–149.
9. Donaldson G.C., Keatinge W.R., 2002, Excess winter mortality: Influenza or cold stress? Observational Study, British Medical Journal, 324, s. 89–90. https://doi.org/10.1136/bmj.324.7329.89
10. Freitas C.R., 2003, Tourism climatology: Evaluating environmental information for decision making and business planning in the recreation and tourism sector, International Journal of Biometeorology, 48, s. 45–54. https://doi.org/10.1007/s00484-003-0177-z
11. Freitas C.R., 2005, The climate-tourism relationship and its relevance to climate change impact assessment, [w:] C.M. Hall, J. Higham (red.), Tourism, Recreation and Climate Change: International Perspectives, Channelview Press, UK, s. 29–43.
12. Gómez M., 2005, Weather, Climate and Tourism. A Geographical Perspective, Annals of Tourism Research, 32, 3, s. 571–591. https://doi.org/10.1016/j.annals.2004.08.004
13. Kaczorowska Z., 1986, Pogoda i klimat, Wydawnictwa Szkolne i Pedagogiczne, Warszawa.
14. Kaszewski B., M., Siwek K., 1998, Cechy przebiegu dobowego temperatury powietrza w centrum i na peryferiach Lublina, Acta Universitatis Lodziensis, Folia Geograpcica Physica, 3, Łódź, s. 213–220.
15. Kejna M., Araźny A., Maszewski R., Przybylak R., Uscka-Kowalkowska J., Vizi Z., 2009, Daily minimum and maximum air temperature in Poland in the years 1951–2005, Bulletin of Geography – Physical Geography Series, 2, s. 35–56.
16. Kozłowska-Szczęsna T., Błażejczyk K., Krawczyk B., 1997, Bioklimatologia człowieka, Monografie, 1, IGiPZ PAN, Warszawa.
17. Kozłowska-Szczęsna T., Błażejczyk K., Krawczyk B., Limanówka D., 2002, Bioklimat uzdrowisk polskich i możliwości jego wykorzystania w lecznictwie, Monografie, 3, IGiPZ PAN, Warszawa.
18. Kozłowska-Szczęsna T., Krawczyk B., Kuchcik M., 2004, Wpływ środowiska atmosferycznego na zdrowie i samopoczucie człowieka, Monografie, 4, IGiPZ PAN, Warszawa.
19. Lei S., Daniels J. L., Bian Z., 2010, Improved soil temperature modelling, Environmental Earth Sciences, 62, 6, s. 1123–1130. https://doi.org/10.1007/s12665-010-0600-9
20. Leszczyński B., 1973, Badania nad wpływem prężności pary wodnej i temperatury powierza ze szczególnym uwzględnieniem wpływu dni parnych, gorących i upalnych na ciśnienie tętnicze krwi, Problemy Uzdrowiskowe, 5, 71, s. 181–184.
21. Limanówka D., Biernacik D., Czernecki B., Farat R., Filipiak J., Kasprowicz T., Pyrc R., Urban G., Wójcik R., 2012, Zmiany i zmienność klimatu od połowy XX wieku, [w:] J. Wibig, E. Jakusik (red.), Warunki klimatyczne i oceanograficzne w Polsce i na Bałtyku Południowym. Spodziewane zmiany i wytyczne do opracowania strategii adaptacyjnych w gospodarce krajowej, IMGW-PIB, Warszawa, s. 7–33.
22. Maras I., Schmidt T., Paas B., Ziefle M., Schneider C., 2016, The impact of human-biometeorological factors on perceived thermal comfort in urban public places, Meteorologische Zeitschrift, 25, 4, s. 407–420. https://doi.org/10.1127/metz/2016/0705
23. Matzarakis A., Freitas C.R., Scott D. (red.), 2007, Developments in Tourism Climatology, Commission on Climate, Tourism and Recreation International Society of Biometeorology, Freiburg.
24. Okoniewska M., 2016, Dobowy przebieg zachmurzenia w Polsce w kolejnych dekadach roku (na przykładzie lat 1990–2000), Journal of Education, Health and Sport, 6, 10, s. 730–740.
25. Okoniewska M., 2016, Zmienność dobowa i sezonowa warunków biotermicznych w Polsce w świetle wybranych wskaźników, Wydawnictwo Uniwersytetu Kazimierza Wielkiego, Bydgoszcz.
26. Roguski W., Łabędzki L., Kasperska-Wołowicz W., 2004, Dobowa zmienność temperatury i wilgotności powietrza na wysokości 2,0 i 0,5 m w siedlisku wilgotnym w dolinie Noteci i siedlisku suchym w Bydgoszczy, Woda – Środowisko – Obszary Wiejskie, 4, 2a (11), IMUZ, Bydgoszcz, s. 137–156.
27. Rojek M., Rojek M.S., 2004, Modelowanie dobowej zmienności temperatury gleby i powietrza przy pomocy funkcji wielomianowych, Acta Agrophysica, 3, 2, s. 367–373.
28. Smith K., 1993, The influence of weather and climate on recreation and tourism, Weather, 48, s. 398–404. https://doi.org/10.1002/j.1477-8696.1993.tb05828.x
29. Szmyd J., Milewski P., 2015, Daily amplitude of air temperature in Poland and Bulgaria – a comparative study, Europa XXI, 29, s. 85–94. https://doi.org/10.7163/Eu21.2015.29.6
30. Więcław M., 2011, Dobowy przebieg temperatury powietrza w Bydgoszczy w czasie wiosennych i jesiennych przymrozków w zależności od rodzaju masy powietrza, Prace i Studia Geograficzne UW, 47, s. 425–431.
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oai:rcin.org.pl:65844 ; 0033-2143 (print) ; 2300-8466 (on-line) ; 10.7163/PrzG.2018.1.3
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Institute of Geography and Spatial Organization of the Polish Academy of Sciences
Programme Innovative Economy, 2010-2014, Priority Axis 2. R&D infrastructure ; European Union. European Regional Development Fund
Mar 25, 2021
Jun 28, 2018
10992
https://rcin.org.pl./publication/84759
Kozłowska-Szczęsna, Teresa (1931– ) Limanówka, Danuta Niedźwiedź, Tadeusz (1942– ) Ustrnul, Zbigniew Paczos, Stanisław
Szmyd, Jakub Milewski, Paweł
Wójcik, Robert Miętus, Mirosław
Banach, Anna Kozakiewicz, Anna Kozakiewicz, Michał Liro, Anna
Kuchcik, Magdalena
Matuszko, Dorota Bartoszek, Krzysztof Soroka, Jakub