دوماه نامه

نوع مقاله : مقالات پژوهشی

نویسندگان

دانشگاه تبریز

چکیده

مطالعه تغییرات ناگهانی تبخیر- تعرق پتانسیل (ET0) در مدیریت منابع آب از اهمیت زیادی برخوردار است. در این پژوهش، تغییرات ناگهانی ET0 در دو مقیاس ماهانه و سالانه در شمال‌غرب ایران مورد بررسی قرار گرفت. از داده‌های 36 ایستگاه هواشناسی همدید (2015-1980) استفاده گردید. میزان ET0 در هر ماه و ایستگاه با روش فائو- پنمن مانتیث (FAO-PM56) برآورد گردید. برای آزمون تغییر ناگهانی در سری‌های ET0 و تشخیص تاریخ دقیق تغییر از روش پتیت استفاده شد. نتایج نشان داد که تغییر ناگهانی معنی‌دار در سری‌های زمانی ET0 برای اکثر ایستگاه‌ها در سطح 5 درصد تجربه شده است. در مقیاس ماهانه و سالانه بترتیب 72/59 درصد و 55/80 درصد ایستگاه‌ها جهش رو به بالا داشتند. در ایستگاه سرارود کرمانشاه در اکثر ماه‌ها، ET0 جهش رو به بالا را تجربه کرده، طوری‌که در مقیاس ماهانه، بیشترین اختلاف میانگین ET0 در دو زیر دوره قبل و بعد از سال تغییر در سپتامبر به‌اندازه 75/47 میلی‌متر در ماه (معادل 35 درصد) مشاهده شد. در مقیاس سالانه، اغلب ایستگاه‌ها تغییرات پرشی را در بین سال‌های 1995 تا 1998 تجربه کرده‌اند. بیشترین پرش در ET0 سالانه مربوط به سرارود کرمانشاه بود که در آن میانگین مقادیر ET0 در دو زیر دوره (قبل و بعد از سال تغییر) به‌ترتیب، 1438 و 1673 (میلی‌متر در سال) به‌دست آمد که اختلاف آن معادل 235 میلی‌متر (معادل 16 درصد) بود که به‌صورت افزایش در ET0 سالانه در زیر دوره اخیر، نسبت به زیر دوره قبلی تجربه شده است. مدیریت خردمندانه آب قابل دسترس در منطقه مورد مطالعه برای ادامه فعالیت‌های کشاورزی و مرتبط با آب حیاتی می‌باشد.

کلیدواژه‌ها

عنوان مقاله [English]

Impact of Climate Change on Sudden Changes in Potential Evapotranspiration Time Series (Case Study: NW of Iran)

نویسندگان [English]

  • yaghoub dinpazhoh
  • Masoumeh Foroughi

چکیده [English]

Introduction: Evapotranspiration is one of the key elements of hydrological cycle. This parameter plays a crucial role in different water related studies such as agricultural water management, environmental energy budget, water balance of watersheds, water reservoirs and water conveyance structures (such as channels, dams, barriers and so on). Increasing greenhouse gases has led to increased atmosphere temperature. Such changes in air temperature and other atmospheric parameters caused some natural hazards in many regions. One of the important parameter impacted by climate change is potential evapotranspiration. Different studies conducted in the recent decade to detect the monotonic trends and abrupt changes in meteorological parameters. Most of them are on trend analysis of meteorological and hydrological parameters. In the recent years, monotonic trend analysis of reference crop evapotranspiration (ET0) has interested many investigators around the globe. Many investigators attempted to find the possible reasons of trends in ET0. In many cases, this is accomplished by sensitivity analysis of ET0 to different meteorological parameters. Other investigators attempted to model ET0 using the hydrologic time series modeling. Detection of sudden change point in different time series including ET0 is very important in changing climate. However, in spite of tremendous studies on monotonic trend analysis, it seems that no serious work has been conducted to detect abrupt changes in ET0 in Iran, especially in west and northwest of Iran. This region has fertile soils and produce an important portion of cereal yields of Iran, thus providing water to agricultural section is crucial under climate change. Therefore, the main objectives of this study were i) estimation of ET0 values in the selected stations in west and northwest of Iran using the FAO-Penman Monteith method, and ii) detection of significant change points in ET0 time series using the nonparametric Pettit test.
Materials and Methods: The 32 synoptic stations were selected in this area for analysis. Data needed for this study were gathered from IRIMO. Meteorological parameters were daily records of maximum air temperature, minimum air temperature, sunshine hour duration, wind speed, and relative humidity. The ET0 values were estimated using FAO-56 Penman-Monteith model. In order to detect the significant change point the non-parametric, Pettitt test was used. Both monthly and annual time scales were used in analysis. The null hypothesis of test is there is no sudden change point in the time series. We calculated the p-values for time series under test and compared it with significance level (5%). If the calculated p-value was less than the significance level (0.05), then the null hypothesis is rejected, and the alternate hypothesis (i.e. there is a significant sudden change point in the time series) will be accepted.
Results and Discussion: The results showed that around 60% of the monthly time series had significant sudden change points. For instance, Urmia showed significant abrupt changes in ET0 for all months. Specifically, more than 86 and 78 % of the stations experienced sudden change in ET0 in March and August, respectively. The strongest abrupt change observed at Maragheh, in which the difference in monthly ET0 before and after the change point date reached to about 45 mm. It is worth to mention that all detected sudden changes had upward direction. In annual time scale, more than 80 % of the stations showed significant abrupt changes in ET0. Among all stations, Sararoud- Kermanshah showed a large difference in mean annual ET0 for the subseries of before and after the change point date which was approximately 235 mm. In annual scale, all sites (except Sahand and Parsabad) experienced upward ET0 abrupt changes. In order to inspect the reason this change, we plotted different meteorological parameters time series. The results indicated that the wind speed showed negative trends (except for two stations) leading to ET0 increase. Furthermore, it was found that almost all stations exhibited increasing trends in air temperature. These changes caused an increase in ET0. The most prominent abrupt change date in ET0 time series was found for the years from 1995 to 1998. For example, in February, April, May, and June, monthly ET0 time series suddenly increased in 1998, which were statistically significant (p < 0.05). Following the year of 1998, some other monthly ET0 series showed abrupt change point in 1995 (p < 0.05).
Conclusions: The sudden change in ET0 was confirmed in west and northwest of Iran. According to the results, ET0 time series (in monthly or annual time scales) exhibited upward sudden changes. Such changes in ET0 time series ring the alarms and decision makers should be, therefore, cautious in management of water resources.

کلیدواژه‌ها [English]

  • Climate change
  • Fao-56-PM-Montith
  • Pettitt Test
  • West and northwest of Iran
1- Ahmadi F., Nazeri Tahroudi M., Mirabbasi R., Khalili K., and Jhajharia D. 2017.Spatiotemporal trend and abrupt change analysis of temperature in Iran. Meteorological Applications.
2- Bandyopadhyay A., Bhadra A., Raghuwanshi N.S., and Singh R. 2009. Temporal trends in estimates of reference evapotranspiration over India. Journal of Hydrologic Engineering, 14(5): 508-515.
3- Bassiouni M., and Oki D.S. 2012. Trends and shifts in streamflow in Hawai‘i, 1913–2008. Hydrological Processes.
4- Bers A.V., Momo F., Schloss I.R., and Abele D. 2013.Analysis of trends and sudden changes in long-term environmental data from King George Island (Antarctica): relationships between global climatic oscillations and local system response. Climate Change, 116: 789-803.
5- Dinpashoh Y., Jhajharia D., Fakheri-Fard A., Singh V.P., and Kahya E. 2011. Trends in reference crop evapotranspiration over Iran. Journal of Hydrology, 399: 422 – 433.
6- Ghasemi A.R. 2015.Changes and trends in maximum, minimum and mean temperature series in Iran. Atmospheric Science Letters, 16: 366-372.
7- Hadi S.J., and Tombul M. 2018.Long-term spatiotemporal trend analysis of precipitation and temperature over Turkey.Meteorological Applications.
8- Huo Z., Dai X., Feng S., Kang S., and Huang G. 2013. Effect of climate change on reference evapotranspiration and aridity index in arid region of China. Journal of Hydrology, 492: 24–34.
9- Jhajharia D., Dinpashoh Y., Kahya E., Singh V.P, and Fakheri-Fard A. 2012. Trends in reference evapotranspiration in the humid region of northeast India. Hydrological Processes, 26: 421- 435.
10- Jiang C., Nie Z., Mu X., Wang F., and Liu W. 2016.Potential evapotranspiration change and its attribution in the Qinling Mountains and surrounding area, China, during 1960–2012. Journal of Water and Climate Change, 7(3): 526-541.
11- Karabörk M.C., Kahya E., and Kömuşcu Ü. Analysis of Turkish precipitation data: homogeneity and the Southern Oscillation forcings on frequency distributions. Hydrological Processes, 21: 3203-3210.
12- Khosravi H., Sajedi-Hosseini F., Nasrollahi M., and Gharechaei H.R. 2017.Trend analysis and detection of precipitation fluctuations in arid and semi-arid regions. Desert 22(1): 77-84.
13- Kiely G. 1999. Climate change in Ireland from precipitation and streamflows observations. Advances in Water Resources, 23:141–151.
14- Kiely G., Albertson J.D., and Parlange M.B. 1998. Recent trends indiurnal variationofprecipitation at Valencia on the west coast of Ireland. Journal of Hydrology, 207: 270–279.
15- Kundzewicz Z.W., and Robson A.J. 2004.Change detection in hydrological records - a review of the methodology. Hydrological Sciences Journal, 49(1): 7-19.
16- Li Q., Wei X., Zhang M., Liu W., Giles-Hansen K., and Wang Y. 2018. The cumulative effects of forest disturbance and climate variability on streamflow components in a large forest-dominated watershed.Journal of Hydrology, (Accepted).
17- Liu L., Xu Z.X., and Huang J.X. 2012. Spatio-temporal variation and abrupt changes for major climate variables in the Taihu Basin, China. Stochastic Environmental Research and Risk Assessment, 26: 777–791.
18- Liu X., and Zhang D. 2013. Trend analysis of reference evapotranspiration in Northwest China: The roles of changing wind speed and surface air temperature. Hydrological Processes, 27: 3941-3948.
19- Lv M.Q., Chen J.L., Mirza Z.A., Chen C.D., Wen Z.F., Jiang Y., Ma M.H., and Wu S.J. 2016. Spatial distribution and temporal variation of reference evapotranspiration in the Three Gorges Reservoir area during 1960–2013. International Journal of Climatology, 36: 4497–4511.
20- Ma X., Zhang L., Mc Vicar T., Chille B., and Gao P. 2007. Analysis of the impact of conservation measures on stream flow regime in catchments of the Loess Plateau, China. Hydrological Processes, 21: 2124–2134.
21- Memarian H., Balasundram S., Talib J., Sood A., and Abbaspour K. 2012. Trend analysis of water discharge and sediment load during the past three decades of development in the Langat basin, Malaysia. Hydrological Sciences Journal, 57(6): 1207-1222.
22- Nazeri Tahroudi M., Ahmadi F., and Khalili K. 2017. Evaluation the Trend and Trend Chang Point of Urmia Lake Basin Precipitation. Journal of Water and Soil, 31(2): 664-659. (In Farsi with English Extended Abstract)
23- Nouri M., Homaee M., and Bannayan M. 2017. Quantitative trend, sensitivity and contribution analyses of reference evapotranspiration in some arid environments under climate change. Water Resources Management, 31: 2207–2224.
24- Pandey B.K., and Khare D. 2018. Identification of trend in long term precipitation and reference evapotranspiration over Narmada river basin (India). Global and Planetary Change, 161: 172-182.
25- Pettitt A.N. 1979. A non-parametric approach to the change point problem.Applied Statistics, 28: 126-135.
26- Pingale S.M., Khare D., Jat M.K., and Adamowski J. 2016, Trend analysis of climatic variables in an arid and semi-arid region of the Ajmer District, Rajasthan, India. Journal of Water and Land Development, 28: 3–18.
27- Piticar A., Mihaila D., Lazurca L., Bistricean P., Putuntica A., and Briciu A. 2016. Spatiotemporal distribution of reference evapotranspiration in the Republic of Moldova. Theoretical and Applied Climatology, 124(3-4):1133-1144.
28- Shi Z., Xu L., Yang X., Guo H., Dong L., Song A., Zhang X., and Shan N. 2017. Trends in reference evapotranspiration and its attribution over the past 50 years in the Loess Plateau, China: implications for ecological projects and agricultural production. Stochastic Environmental Research and Risk Assessment, 31:257–273.
29- Stefanescu V., Stefan S., and Georgescu F. 2014. Spatial distribution of heavy precipitation events in Romania between 1980 and 2009. Meteorological Applications, 21(3): 684-694.
30- Tabari H., Marofi S., Aeini A., Hosseinzadeh P., and Mohammadi K. 2010. Trend analysis of reference evapotranspiration in the western half of Iran.Agricultural and Forest Meteorology, 151:128-136.
31- Zhang D., Liu X., and Hong H. 2013. Assessing the effect of climate change on reference evapotranspiration in China.Stochastic Environmental Research and Risk Assessment, 27(8): 1871-1881.
CAPTCHA Image