Abstract
Reference evapotranspiration (ET0) is considered a key parameter for evaluating the climatic changes as well as spatial and temporal patterns of parameters influencing the eco-hydrological processes. The analysis of trend variations of this index can be used to determine appropriate strategies in planning and management of water resources. In this paper, the trend variations of monthly and annual ET0 in Urmia Lake basin, located in the northwest of Iran, have been analyzed using data from 14 synoptic stations in the study area. Regarding the significant effect of autocorrelation coefficients with different lags on trend variations of ET0, this paper has resorted to modified Mann–Kendall test via eliminating the significance effect of autocorrelation coefficients with different lags to analyze the trend variations. Furthermore, Theil–Sen estimator has been used to determine the slope of trend line of ET0. The results indicated an increasing trend in ET0 values at all the studied stations. Having used the modified Mann–Kendall test, the values of significant increasing (positive) trend, which were estimated using common Mann–Kendall test, dramatically decreased. As such, the values of only 7 stations have been significant at 95 % level. The results confirmed the need for eliminating the significance effect of autocorrelation coefficients with different lags to determine and evaluate the trend of hydrological variables.
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1 Introduction
Climate changes that occur due to anthropogenic emissions of greenhouse gases are considered as one of the important environmental concerns in the twenty-first century. The average temperature of the earth has increased up to 0.6 °C over the last 100 years, and 1998 was the warmest year hitherto (Tabari et al. 2012). Generally speaking, many processes in the biosphere have been influenced in some way by climate changes. Furthermore, the negative impact of climate changes on the environment and water resources is a felt concern (Abdul Aziz and Burn 2006). One of the major challenges of recent hydrological modeling activities is devoted to assess the impacts of climate changes on the water cycle (Bormann 2011). Broadly speaking, climate changes have dramatic impacts on hydrological parameters, including runoff, evapotranspiration, soil moisture, and groundwater (Goyal 2004).
Reference evapotranspiration (ET0) is considered a key parameter for evaluating the climatic changes as well as spatial and temporal patterns of parameters influencing the eco-hydrological processes. Similarly, the analysis of trend variations of this index can be used to determine appropriate strategies in planning and management of water resources (Shadmani et al. 2011). Climatic observations of many stations report that temperature has increased in the last decades (IPCC 2007). However, changes in the components of hydrological cycles, such as ET0, show diverse increasing and decreasing patterns (i.e., Chattopadhyay and Hulme 1997; Thomas 2000; Chen et al. 2006; Gao et al. 2006; Xu et al. 2006; Zhang et al. 2007, 2009; Donohue et al. 2010; Li et al. 2010; Liu et al. 2010). Regarding limited water resources, it is very important to understand and analyze this phenomenon, particularly in arid and semi-arid regions such as Urmia Lake basin, located in northwest of Iran. Thus, investigating and evaluating the impact of climate changes on evapotranspiration parameters can be effective in order to reduce the potential damages.
Many parametric and non-parametric methods have been used for detecting significant trends throughout meteorological and hydrological time series (Zhang et al. 2006; Chen et al. 2007). Although parametric methods are more powerful than non-parametric ones in terms of determining the trend of variables, the latter categories are independent and follow normally distributed data. Accordingly, parametric methods are less applicable. Meanwhile, non-parametric methods require independent data, can tolerate outliers, and are not sensitive to the type of statistical data distribution (Hamed and Rao 1998; Yue and Wang 2002; Chen et al. 2007). The Mann–Kendall (MK) and Spearman’s Rho tests are among the most known and common non-parametric tests used to determine the trends of hydrological variables. It has been indicated that these two tests have similar power in detecting the trends of hydrological time series data (Yue and Wang 2004; Novotny and Stefan 2007).
Recent studies conducted in the domain of climate changes have mainly focused on long-term variations of temperature and precipitation. Evapotranspiration, as the third important climatic factor to control energy and interchange the mass between the Earth’s ecosystem and the atmosphere, has received less attention (Chen et al. 2006). Palle and Butler (2001) reported a decreasing trend of sunny hours and an increasing trend of cloudy hours at 4 stations in Ireland. Garbrecht and Van Liew (2004) conducted a study in the Great Plains in the USA to analyze precipitation, streamflow, and ET0 trends. They concluded that increased amount of precipitation over the last two decades of the twentieth century has led to a disproportionate increase in streamflow and a lower relative increase in ET0. Xu et al. (2006) analyzed 150 meteorological stations in the Chang Jiang basin (Yangtze River). The results indicated that there was an annual decreasing trend in both ET0 and basin evaporation. They concluded that this decreasing trend was mainly caused by a significant decrease in the net total radiation and, to a lesser extent, a decrease in the wind speed in the basin. Dongsheng et al. (2007) made use of Mann–Kendall and Linear Regression methods and concluded that there were significant increases in annual temperature, average annual rainfall, annual potential ET0 and soil moisture at the northeastern regions of China from 1961 to 2004. Bandyopadhyay et al. (2009) estimated the ET0 at 133 selected stations in India using FAO-56 Penman-Monteith (FAO-56 PM) and Mann–Kendall methods. They found a significant decreasing trend in ET0 in the study areas which was mainly due to a significant increase in the relative humidity and decrease in the wind speed in the study areas. Tabari et al. (2011) evaluated the annual, seasonal and monthly trends in ET0 in the western region of Iran using Penman–Monteith, MK and Linear Regression methods. The results of Mann–Kendall test indicated that there was a positive annual trend in ET0 at 70 % of the stations. Furthermore, the results of Linear Regression method pointed out that there was a positive annual trend in ET0 at 75 % of the stations. Besides, it was found that although the majority of stations have had significant trends in ET0 in February, there have been some stations with significant trends in November. In another study, Tabari and Marofi (2011) made use of Mann–Kendall and linear regression methods to evaluate the temporal variations of basin evaporation at 12 stations in Hamedan province from 1982 to 2003. They concluded that there was a significant increasing trend in basin evaporation at 67 % of stations at 95 and 99 % confidence levels. Yin et al. (2010) studied the ET0 trend from 1961 to 2008 in China and confirmed that there was a decreasing trend in ET0. Conversely, Abtew et al. (2011) pointed out that South Florida has experienced an increasing ET0 trend. Jhajharia et al. (2011) estimated trend variations in ET0 at a wet climatic region located in the northern part of India using the Mann–Kendall test via eliminating the significance effect of lag-1 autocorrelation coefficient. The results indicated that annual and seasonal ET0 have significantly decreased at 6 selected stations. Tabari et al. (2012) evaluated the time series trends in ET0 in the west and southwest of Iran from 1966 to 2005 using Mann–Kendall and Spearman’s Rho tests via eliminating the significance effect of lag-1 autocorrelation coefficient. They indicated that the existence of autocorrelation coefficient in ET0 series increased the possibility and potency of Mann–Kendall and Spearman’s Rho tests to reject the null hypothesis on the existence of no trend in this domain. They also found that, compared to the Spearman rank method, Mann–Kendall test was more sensitive to the existence of autocorrelation. Having used stepwise regression, they concluded that wind speed has had the most effect on the significant increase in ET0.
The majority of studies conducted to evaluate the trend variations of ET0 have been based on the common non-parametric Mann–Kendall and/or Spearman’s Rho methods. Meanwhile, these studies have not gauged the impact of autocorrelation coefficients with different lags (i.e., in other hydrological time series: Guo and Xia 2014; Subash and Sikka 2014; Yao and Chen 2014). Only in limited studies, the first order (lag-1) auto correlation is considered, and the effect of that was eliminated in examination of time series trends (Tabari et al. 2012; Mondal et al. 2014; Palizdan et al. 2014; Sayemuzzaman et al. 2014). Actually, it seems that the autocorrelation with different lags has a significant effect on the trend variations of ET0 (Von Storch 1995; Yue and Wang 2002; Yue et al. 2003; Yue and Hashino 2003; Khaliq et al. 2009). Therefore, eliminating the impact of autocorrelation with different lags (i.e., 1, 2, … months) can be important for determining the temporal changes of ET0.
In this study, the monthly trend variations of ET0 in the northwest of Iran were analyzed using FAO-56 Penman–Monteith as well as the modified Mann–Kendall test (via eliminating the significance effect of autocorrelation coefficients with different lags). Besides, Theil–Sen Estimator has been used to determine the slope of trend line of ET0.
2 Materials and methods
2.1 Study area and used data
Regarding the environmental importance of the Urmia Lake, the monthly data of 14 synoptic stations, located in Urmia Lake basin (from 1986 to 2010), were used to analyze the trend of reference evapotranspiration. The geographical position and general information of these synoptic stations, located in the study area, have been provided in Fig. 1 and Table 1, respectively. Regarding the initial data analysis, the Double Mass method was used to evaluate the homogeneity of data (Bars 1990). The results confirmed the homogeneity of data with a correlation coefficient of 0.99. Furthermore, Run test was used to test the randomness of data (Adeloye and Montaseri 2002). The test results verified the hypothesis of data randomness.
2.2 FAO-56 Penman–Monteith method
The FAO-56 Penman–Monteith standard method (Eq. 1), which has been proposed by Allen et al. (1998), was used to estimate ET0:
Where, R n represents net radiation (MJ m-2 d-1), T represents the average air temperature (°C), U 2 represents wind speed at 2 m height (m s-1), Δ represents the slope of vapor pressure (kPa °C-1), G represents the soil heat flux density (MJ m−2 d−1), γ represents the psychometrics constant (kPa °C-1), and (es-ea) represents the vapor pressure deficit in kPa. It should be noted that this item is a function of relative humidity (%) and the average air temperature (°C).
2.3 Statistical trend analysis
2.3.1 Mann-Kendall test (MK1)
This test is one of the commonest methods used to determine the linearity or non-linearity of time series trends. This test was firstly proposed by Mann (1945) and was then developed by Kendall (1975). The Mann–Kendall test can be used to determine time series trends that do not follow normal distributions. Similarly, extreme values have negligible impacts on determining time series trends (Xu et al. 2003). The value of Mann–Kendall test for n data can be calculated from the following relations:
Where, x i and x j represent successive data in the i and j years, respectively, n represents the duration of statistical period, sgn (x j -x i ) represents the sign function, Var(S) represents the variance of S which has a zero mean for n ≥ 8 and follows the normal distribution, e i represents the number of ties for the ith value, g represents the number of tied data, and Z represents the test statistics. If the value of Z is less or greater than the value of Z for the standard normal distribution at 95 % confidence level, it means that there is a trend in time series data (Kampata et al. 2008). A positive value of Z indicates an increasing trend, and a negative value of Z indicates a decreasing trend.
2.3.2 The modified Mann-Kendall test (MK2)
The modified Mann–Kendall test was proposed by Hamed and Rao (1998) via considering the significance of all autocorrelation coefficients in time series. In this method, modified variance (Var(S)) is used for calculation of Z statistics of the common Mann–Kendall test.
Where, Var(S) is calculated via the Eq. (4), \( \left(\frac{n}{n^{*}}\right) \) represents the modified coefficient of autocorrelated data, r k represents the autocorrelation coefficient of k th, and \( \overline{x} \) represents the mean of time series. The significance of autocorrelation coefficient of k th at 95 % confidence level can be calculated by the following equation:
If the obtained r k obeys the above condition, the data will be independent at 95 % confidence level. Otherwise, the data are not independent and the effect of autocorrelation coefficient with different lags should be eliminated to determine the time series trend. Finally, the value of Var(S)* substituted Var(S) in Eq. (5) and the value of Z is calculated. If the value of Z is less or greater than the value of Z value of standard normal distribution at 95 % confidence level, it means that there is a trend in time series data.
2.3.3 Trend slope
The slope of trend line was estimated on the basis of investigations conducted by Theil (1950) and Sen (1968), as stated in the following equation:
Where, 1 < s < t < n, β represents the estimator of trend line, and x t represents the observed t th data. The positive value of β indicates an increasing trend and a negative value of β indicates a decreasing trend (Yue et al. 2003).
In this study, monthly and annual ET0 values were estimated based on PM method using CROPWAT Model in terms of four main parameters of relative humidity, sunny hours, and minimum and maximum air temperature. Then, the Mann–Kendall (MK1) and modified Mann–Kendall (MK2) tests were used to determine the significant trend variations of ET0 values in Urmia Lake basin. Before analyzing the trend, the significance effect of autocorrelation coefficients with different lags was checked. Accordingly, if the autocorrelation coefficient was not significant, the MK1 would be used and if the autocorrelation coefficient was significant, the MK2 would be used thereof. Besides, the Theil–Sen’s estimator was used for determining the slope of ET0 trend variations.
3 Results
3.1 Annual and monthly time series of ET0
Time series of annual and monthly ET0 for all the selected stations are presented as box plots in terms of maximum, 75, 50, 25 %, and minimum values (Figs. 2 and 3, respectively). As can be seen, the maximum and minimum estimated values belong to Sanandaj (955.4 mm) and Ahar (726.2 mm) stations, respectively. The minimum value of ET0 is 9.3 mm for January, and its maximum value is 159.65 mm for July.
3.2 Trend analysis of ET0
Table 2 depicts the results of trend variations of annual ET0 in Urmia Lake basin using the MK1 and MK2 test along with significant autocorrelation coefficients with related lags. Regarding the results of the MK1 test, there are increasing (positive) trends in all the selected stations, and all these trends, except in the Tabriz station, are significant at 95 % confident level. Similarly, the values of significant autocorrelation coefficients along with the related lag at 95 % confidence level have been presented in Table 2. Since the significance effect of autocorrelation coefficients has been eliminated, the values of trend have changed in accordance with the MK2. Although, there is an increasing (positive) trend in all the selected stations, their values have been decreased. Accordingly, these values are significant only in 7 stations at 95 % confidence level. This latter fact emphasizes on the dire need to pay attention to the dependence of data to autocorrelation coefficients with different lags to determine time series trend.
Furthermore, it has been found that the correlation coefficient between the standard deviation of annual time series in ET0 and the values of MK1 is 0.59. However, this value has increased for MK2 up to 0.67.
Regarding the results of MK2 for annual time series trend, it has been found that Maragheh station has had the maximum significant increasing trend value (2.77) and Tabriz station has had the minimum significant increasing trend value (1.06). The time series trend variations in ET0 for these stations are depicted in Fig. 4.
Figure 5 depicts the values of spatial trend variations for annual ET0 time series over the study region based on MK1 and MK2 tests. As can be seen, the increasing trend of ET0 in the south and southeast of the study area has been significant when MK1 test has been used. However, the significant increasing trend has been confined to some eastern regions when the significance effect of autocorrelation coefficients has been eliminated thereof.
Table 3 presents the values trend variations for monthly ET0 time series at different stations based on MK2. Regarding the values inserted in this table, the maximum value of MK2 is estimated for Maragheh station in October (3.53) and the minimum value of MK2 is estimated for Jolfa station in January (−1.21).
Regarding the Fig. 6 (box plot), it has been found that the values of MK2 have increasing trends in all months, and these increasing trends have been significant at majority of stations at 95 % confidence level in March, June, and October. Actually, there have been increasing trends at 99.1 % of all months, and only 8.9 % of months depict decreasing trends.
The values of slope of annual ET0 trend variations, based on Sen’s estimator, have been presented in Table 4. As can be seen, the slope of the trend line is positive for all the stations. Furthermore, the maximum and minimum values of slope are related to Sardasht (3.21 mm/year) and Tabriz (1.04 mm/year) stations, respectively. The correlation coefficient between the values of trend slope and standard deviation of annual ET0 time series is as 0.81.
Figure 7 depicts the box plot of trend slope of the monthly ET0 time series. As can be seen, the majority of months have a positive trend slope. The maximum and minimum values of trend slope are estimated for Saradasht station in June (0.661 mm/year) and Tabriz station in May (−0.138 mm/year), respectively.
4 Conclusions
This study evaluated the trend of annual and monthly ET0 time series using Mann–Kendall test via eliminating the significance effect of autocorrelation coefficients with different lags in Urmia Lake basin. Having used the modified Mann–Kendall test, the values of significant increasing (positive) trend, which were estimated by common Mann–Kendall test, dramatically decreased. Accordingly, these values dramatically decreased over the study area and the values of only 7 stations were significant at 95 % level. This latter fact emphasizes on dire need to pay attention to the dependence of data to autocorrelation coefficients with different lags as well as necessity to eliminate such an effect to determine and evaluate the trend of hydrological variables. The results of this research, which have been mainly based on the modified Mann–Kendall test, indicate that there has been an increasing trend in annual and monthly time scales. Generally speaking, the latter increasing trend in annual time scale has been found significant at 50 % of all the studied stations.
References
Abdul Aziz OI, Burn DH (2006) Trends and variability in the hydrological regime of the Mackenzie River Basin. J Hydrol 319:282–294
Abtew W, Obeysekera J, Iricanin N (2011) Pan evaporation and potential evapotranspiration trends in South Florida. Hydrol Process 25:958–969
Adeloye AJ, Montaseri M (2002) Preliminary streamflow data analyses prior to water resources planning study. Hydrol Sci J 47(5):679–692
Allen RG, Pereira LS, Raes D, Smith M (1998) Crop evapotranspiration: guidelines for computing crop water requirements. FAO Irrigation and Drainage Paper No. 56
Bandyopadhyay A, Bhadra A, Raghuwanshi NS, Singh R (2009) Temporal trends in estimates of reference evapotranspiration over India. J Hydrol Eng 14(5):508–515
Bars RL (1990) Hydrology: an introduction to hydrologic science. Addison-Wesley Publishing Co., New York
Bormann B (2011) Sensitivity analysis of 18 different potential evapotranspiration models to observed climatic change at German climate stations. Clim Chang 104(3–4):729–753
Chattopadhyay N, Hulme M (1997) Evaporation and potential evapotranspiration in India under conditions of recent and future climatic change. Agric For Meteorol 87(1):55–74
Chen SB, Liu YF, Thomas A (2006) Climatic change on the Tibetan plateau: potential evapotranspiration trends from 1961–2000. Clim Chang 76:291–319
Chen H, Guo S, Xu CY, Singh VP (2007) Historical temporal trends of hydro-climatic variables and runoff response to climate variability and their relevance in water resource management in the Hanjiang basin. J Hydrol 344:171–184
Dongsheng Z, Zheng D, Shaohong W, Zhengfang W (2007) Climate changes in northeastern China during last four decades. Chin Geogr Sci 17:317–324
Donohue RJ, McVicar TR, Roderick ML (2010) Assessing the ability of potential evaporation formulations to capture the dynamics in evaporative demand within a changing climate. J Hydrol 386:186–197
Gao G, Chen DL, Ren GY, Chen Y, Liao YM (2006) Spatial and temporal variations and controlling factors of potential evapotranspiration in China: 1956–2000. J Geogr Sci 16:3–12
Garbrecht J, Van Liew M (2004) Trends in precipitation, streamflow, and evapotranspiration in the Great Plains of the United States. J Hydrol Eng 9(5):360–367
Goyal RK (2004) Sensitivity of evapotranspiration to global warming: a case study of arid zone of Rajasthan (India). Agric Water Manag 69:1–11
Guo L, Xia Z (2014) Temperature and precipitation long-term trends and variations in the Ili-Balkhash Basin. Theor Appl Climatol 115:219–229
Hamed KH, Rao AR (1998) A modified Mann-Kendall trend test for autocorrelated data. J Hydrol 204:182–196
IPCC (2007) Climate change 2007—the physical science basis. Contribution of working group I to the fourth assessment report of the IPCC. Cambridge University Press
Jhajharia D, Dinpashoh Y, Kahya E, Singh VP, Fakheri-Fard A (2011) Trends in reference evapotranspiration in the humid region of northeast India. Hydrol Process 26(3):421–435
Kampata JM, Parida BP, Moalafhi DB (2008) Trend analysis of rainfall in the headstreams of the Zambezi River Basin in Zambia. Phys Chem Earth 33(8–13):621–625
Kendall MG (1975) Rank correlation measures. Charles Griffin Inc, London
Khaliq MN, Ouarda TBMJ, Gachon P (2009) Identification of temporal trends in annual and seasonal low flows occurring in Canadian rivers: the effect of short- and long-term persistence. J Hydrol 369:183–197
Li Y, Horton R, Ren T, Chen C (2010) Prediction of annual reference evapotranspiration using climatic data. Agric Water Manag 97(2):300–308
Liu Q, Yang Z, Cui B, Sun T (2010) The temporal trends of reference evapotranspiration and its sensitivity to key meteorological variables in the Yellow River Basin, China. Hydrol Process 24(15):2171–2181
Mann HB (1945) Non-parametric test against trend. Econometrica 13:245–259
Mondal A, Khare D, Kundu S (2014) Spatial and temporal analysis of rainfall and temperature trend of India. Theor Appl Climatol. doi:10.1007/s00704-014-1283-z
Novotny EV, Stefan HG (2007) Stream flow in Minnesota: indicator of climate change. J Hydrol 334:319–333
Palizdan N, Falamarzi Y, Huang YF, Lee ST, Ghazali AH (2014) Regional precipitation trend analysis at the Langat River Basin, Selangor, Malaysia. Theor Appl Climatol 117:589–606
Palle E, Butler CJ (2001) Sunshine records from Ireland: cloud factors and possible link to solar activity and cosmic rays. Int J Climatol 21:709–729
Sayemuzzaman M, Jha MK, Mekonnen A (2014) Spatio-temporal long-term (1950–2009) temperature trend analysis in North Carolina, United States. Theor Appl Climatol. doi:10.1007/s00704-014-1147-6
Sen PK (1968) Estimates of the regression coefficient based on Kendall’s tau. J Am Stat Assoc 63:1379–1389
Shadmani M, Marofi S, Roknian M (2011) Trend analysis in reference evapotranspiration using Mann-Kendall and Spearman’s Rho tests in arid regions of Iran. Water Resour Manag 26(1):211–224
Subash N, Sikka AK (2014) Trend analysis of rainfall and temperature and its relationship over India. Theor Appl Climatol 117:449–462
Tabari H, Marofi S (2011) Changes of pan evaporation in the West of Iran. Water Resour Manag 25(1):97–111
Tabari H, Marofi S, Aeini A, Hosseinzadeh Talaee P, Mohammadi K (2011) Trend analysis of reference evapotranspiration in the western half of Iran. Agric For Meteorol 151:128–136
Tabari H, Nikbakht J, Hosseinzadeh Talaee P (2012) Identification of trend in reference evapotranspiration series with serial dependence in Iran. Water Resour Manag 26:2219–2232
Theil H (1950) A rank invariant method of linear and polynomial regression analysis, Part 3. Proc K Ned Akad Wet 53:1397–1412
Thomas A (2000) Spatial and temporal characteristics of potential evapotranspiration trends over China. Int J Climatol 20:381–396
Von Storch H (1995) Misuses of statistical analysis in climate research, analysis of climate variability: applications of statistical techniques. Springer, Berlin
Xu ZX, Takeuchim K, Ishidaira H (2003) Monotonic trend and step changes in Japanese precipitation. J Hydrol 279:144–150
Xu C, Gong L, Jiang T, Chen D, Singh VP (2006) Analysis of spatial distribution and temporal trend of reference evapotranspiration and pan evaporation in Changjiang (Yangtze River) catchment. J Hydrol 327:81–93
Yao J, Chen Y (2014) Trend analysis of temperature and precipitation in the Syr Darya Basin in Central Asia. Theor Appl Climatol. doi:10.1007/s00704-014-1187-y
Yin Y, Wu S, Chen G, Dai E (2010) Attribution analyses of potential evapotranspiration changes in China since the 1960s. Theor Appl Climatol 101:19–28
Yue S, Hashino M (2003) Temperature trends in Japan: 1900–1996. Theor Appl Climatol 75:15–27
Yue S, Wang CY (2002) The influence of serial correlation on the Mann–Whitney test for detecting a shift in median. Adv Water Resour 25:325–333
Yue S, Wang CY (2004) The Mann–Kendall test modified by effective sample size to detect trend in serially correlated hydrological series. Water Resour Manag 18:201–218
Yue S, Pilon P, Phinney B (2003) Canadian streamflow trend detection: impacts of serial and cross-correlation. Hydrol Sci J 48(1):51–63
Zhang Q, Liu C, Xu CY, Xu YP, Jiang T (2006) Observed trends of water level and streamflow during past 100 years in the Yangtze River basin, China. J Hydrol 324:255–265
Zhang Y, Liu C, Tang Y, Yang Y (2007) Trends in pan evaporation and reference and actual evapotranspiration across the Tibetan Plateau. J Geophys Res. doi:10.1029/2006JD008161
Zhang X, Ren Y, Yin ZY, Lin Z, Zheng D (2009) Spatial and temporal variation patterns of reference evapotranspiration across the Qinghai-Tibetan Plateau during 1971–2004. J Geophys Res 114:D15105. doi:10.1029/2009JD011753
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Amirataee, B., Montaseri, M. & Sanikhani, H. The analysis of trend variations of reference evapotranspiration via eliminating the significance effect of all autocorrelation coefficients. Theor Appl Climatol 126, 131–139 (2016). https://doi.org/10.1007/s00704-015-1566-z
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DOI: https://doi.org/10.1007/s00704-015-1566-z