A Trend Analysis of Area Suffering from Climate Changes in Iran During: 1960-2004

Document Type : Research Article

Authors

University of Isfahan

Abstract

1. Introduction
As strongly accepted among climatologists, climate change is a result of human activities. There is disagreement about how to define climate change, because of tremendous difference of climate changes in scale, intensity and occurrence time in various regions. Recently there have been several observation analyses involving daily and extreme daily temperature trend and variability in regional and global scale. Analyses In global scale (Caesar & Alexander, 2005; Alexander et al., 2006; Brown, 2008) show an increasing trend in the lower end of the maximum and minimum temperature distributions with regional differences. For instance, in south America, analyses showed a general warming trend in the region (Aguialar et al., 2005) also analysis results indicate no consistent change in the indices based on daily maximum temperature while significant trends were found in the indices based on daily minimum temperature (Vincent et al., 2005). Therefore in this paper, using gridded daily temperature data (Mean, maximum, minimum), we have analyzed the trend of the area which is affected by climate warming in Iran.

2. Study Area
Iran is a country located on North latitude to, East longitude, to, on subtropical region. The minimum and maximum of Iran's temperature is and .respectively.

3. Material and methods
Analyzing extreme indices, we used the temperature data from Asfezari’s national gridded database which dates from 23.5.1961 to 31.12.2004.
The temperature database, were collected from 664 climate and synoptic stations using Kriging interpolation method. In this database a matrix of 7187×1599 is defined for each climatic variable in which rows represent spatial cells and columns represent time (per day). The coordinate system of the database is Lambort conformal conic and the dimensions of each grid is 15×15 sq. meter.
1. In this research, warming is defined as the ratio of temperature rise in the long-term regional average. Since in this study gridded data were used, long-term average of each grid is considered as the regional norm. 2. In the second step the number of the grids with a higher amount than the long-term average in the same grid and the same day was recorded and the area percentage of each grid was calculated.
3. Finally the output trend of the second step was calculated.

4. Results and Discussion
In this study, spatial behavior of temperature analyzed using minimum, maximum and mean temperatures that each represents a different structure of a region’s climate. The minimum temperature results from the output of the solar radiation and daytime temperature results from the input of solar radiation. On the other hand, green gases such as vapor and carbon dioxide are the basic effective elements in a balance of the output of the solar radiation, whereas the balance of the input of solar radiation depends on atmosphere radiation characteristics such as atmospheric transparency.
Therefore, the minimum and maximum temperatures are affected by different factors and may have different trends. The mean temperature of each region can be the representation of the changing structure and provides features of temperature behavior, according to time and location and gives a background of the region. Therefore, due to temperature rise in the current century, and due to development of the regions with rising temperature and also temperature importance as a basic element in climate system, it is important to know in what velocity the temperature is rising and what areas it affects in each period. The results show the areas that their minimum temperature increase are more than the areas that their maximum temperature increases. The time series of AI also shows the mean of this index increases in more than 50 percent of Iran in recent years.
Therefore, sorting temperature rising value and AI increasing trend adds to the importance of the subject. The 54% increase of AI is an alarm for ecosystems and natural resources in a country like Iran whose climate structure adds to its sensitivity. According to previous studies (Masoodian, Loarie et al 2009) such changes affect mountain areas less and therefore future programmers should pay special attention to such areas.

3. Conclusion
The results show the areas that their minimum temperature increases are more than the areas that their maximum temperature increases. The time series of AI also shows the mean of this index increases in more than 50 percent of Iran in recent years. Minimum and maximum temperatures play a decisive role in different features of man’s life, such as agriculture, social and fundamental issues and are considered as irritable thresholds for all man’s activity which is a reason why it is of such importance to governors and programmers. In studies performed on climate changes, it is obvious that plant and animal habitats are affected more than that of humans. According to studies, it seems that Iran’s climate is tending towards a warmer climate with less precipitation. In studies performed on climate change, it is obvious that plant and animal habitats are affected more than that of humans. The 54% increase of AI is an alarm for ecosystems and natural resources in a country like Iran whose climate structure adds to its sensitivity. Moreover, an important feature of management against climate change is to mark vast, vulnerable areas such as arid and semi-arid regions and deserts, which constitute an extensive part of Iran. Due to the high sensitivity of such areas, protection of their ecosystem is of great importance.

Keywords


رعیت‌پیشه، فاطمه(1393)، واکاوی وردش‌های آب‌وهوایی ایران در دهه‌های اخیر، پایان نامه‌ی دکتری، دانشگاه اصفهان، استاد راهنما دکتر سید ابوالفصل مسعودیان.
عساکره، حسین، (1387)،کاربرد روش کریجینگ در میانیابی بارش مطالعه موردی: میانیابی بارش 26/12/1376 ایران زمین، جغرافیا و توسعه، 25-42.
عساکره، حسین، (1386)، تغییر اقلیم، انتشارات دانشگاه زنجان.
عساکره، حسین، (1390)، مبانی آب‌وهوا شناسی آماری، زنجان، انتشارات دانشگاه زنجان.
مسعودیان، سید ابوالفضل، (1390) آب و هوای ایران، مشهد، انتشارات شریعه‌‌‌ی توس.
مسعودیان، سید ابوالفضل، (1383) واکاوی روند دمای ایران در نیم سده‌‌‌ی اخیر، پژوهش‌های جغرافیایی و توسعه، شماره‌ی3، 106-89.
Aguilar, E., Peterson, T. C., Obando, P. R., Frutos, R., Retana, J. A., Solera, M, … & Mayorga, R. (2005). Changes in precipitation and temperature extremes in Central America and northern South America, 1961–2003. Journal of Geophysical Research: Atmospheres, 110(D23).
Alexander, L. V., Zhang, X., Peterson, T. C., Caesar, J., Gleason, B., Klein Tank, A. M. G., & Vazquez‐Aguirre, J. L. (2006). Global observed changes in daily climate extremes of temperature and precipitation. Journal of Geophysical Research: Atmospheres (1984–2012), 111(D5).
Bonsal, B. R., Zhang, X., Vincent, L. A., & Hogg, W. D. (2001). Characteristics of daily and extreme temperatures over Canada. Journal of Climate, 14(9), 1959-1976.
Caesar, J., Alexander, L., & Vose, R. (2006). Large‐scale changes in observed daily maximum and minimum temperatures: Creation and analysis of a new gridded data set. Journal of Geophysical Research: Atmospheres 111 (D5), 1-10.
Dunlop, M., & Brown, P. (2008). Implications of climate change for Australia's national reserve system: a preliminary assessment, Report to the Department of Climate Change, Canberra
.
Easterling, D. R., Meehl, G. A., Parmesan, C., Changnon, S. A., Karl, T. R., & Mearns, L. O. (2000). Climate extremes: Observations, modeling, and impacts. Science, 289(5487), 2068-2074.
Folland, C. K., & Co authors, (2001). Observed climate variability and change. In: Climate change 2001: The scientific basis. Contribution of working group I to the third assessment report of the intergovernmental panel on climate change (pp. 99–181). , Cambridge: Cambridge University Press.
Jones, P. D., Briffa, K. R., Osborn, T. J., Lough, J. M., Van Ommen, T. D., Vinther, B. M., ... & Xoplaki, E. (2009). High-resolution paleoclimatology of the last millennium: a review of current status and future prospects. The Holocene, 19(1), 3-49.
Kharin, V. V., & Zwiers, F. W. (2005). Estimating extremes in transient climate change simulations. Journal of Climate, 18(8), 1156-1173.
Klein Tank, A. M. G., & Können, G. P. (2003). Trends in indices of daily temperature and precipitation extremes in Europe, 1946-99, Journal of Climate, 16(22), 3665-3680.
Klein Tank, A. M. G., Wijngaard, J. B., Können, G. P., Böhm, R., Demaree, G., Gocheva, A., ... & Petrovic, P. (2002). Daily dataset of 20th‐century surface air temperature and precipitation series for the European climate assessment. International Journal of Climatology, 22(12), 1441-1453.
Kostopoulou, E., & Jones, P. D. (2005). Assessment of climate extremes in the Eastern Mediterranean. Meteorology and Atmospheric Physics, 89(1-4), 69-85.
Loarie, S. R., Duffy, P. B., Hamilton, H., Asner, G. P., Field, C. B., & Ackerly, D. D. (2009). The velocity of climate change. Nature, 462(7276), 1052-1055.
Meehl, G. A., Zwiers, F., Evans, J., Knutson, T., Mearns, L., & Whetton, P. (2000). Trends in extreme weather and climate events: Issues related to modelingextremes in projections of future climate change. Bulletin of the American Meteorological Society, 81(3), 427-436.
Pearson, R. G. (2006). Climate change and the migration capacity of species. Trends in Ecology & Evolution, 21(3), 111-113.
Rayatpisheh, F. (2015). The analysis of climate variability over Iran in recent decades. Unpublished doctoral dissertation, University of Isfahan, Isfahan, IRAN. [(in Persian]
Robeson, S. M. (2004). Trends in time‐varying percentiles of daily minimum and maximum temperature over North America. Geophysical Research Letters, 31, 1-4.
Solomon, S., Qin, D., Manning, M., Chen, Z., Marquis, M., Averyt, K. B., & Miller, H. L. (2007). IPCC, 2007: summary for policymakers. Climate Change, 93-129.
Tank, A. M. G. K., & Konnen, G. P. (2003). Trends in indices of daily temperature and precipitation, Extremes in Europe, 1946–99. J. Clim. 16, 3665–3680.
Tebaldi, C., Hay Hoe, K., Arblaster, J. M., & Meehl, G. A. (2006). Going to the extremes. Climatic Change, 79(3-4), 185-211.
Vincent, L. A., Aguilar, E., Saindou, M., Hassane, A. F., Jumaux, G., Roy, D., & Montfraix, B. (2011). Observed trends in indices of daily and extreme temperature and precipitation for the countries of the western Indian Ocean, 1961–2008. Journal of Geophysical Research: Atmospheres (1984–2012), 116(D10).
Vincent, L. A., et al. (2005). Observed trends in indices of daily temperature extremes in South America 1960– 2000. J. Clime, 18, 5011 –5023.
Williams, J. W., Jackson, S. T., & Kutzbach, J. E. (2007). Projected distributions of novel and disappearing climates by 2100 AD. Proceedings of the National Academy of Sciences, 104(14), 5738-5742.
Yue, S., & Hashino, M. (2003). Temperature trends in Japan: 1900–1996. Theoretical and Applied Climatology, 75(1-2), 15-27.
Zhang, X., Aguilar, E., Sensoy, S., Melkonyan, H., Tagiyeva, U., Ahmed, N., & Wallis, T. (2005). Trends in Middle East climate extreme indices from 1950 to 2003. Journal of Geophysical Research: Atmospheres 110(D22).
Zhang, X., Vincent, L. A., Hogg, W. D., & Niitsoo, A. (2000). Temperature and precipitation trends in Canada during the 20th century. Atmosphere-Ocean, 38(3), 395-429.
CAPTCHA Image