Modeling climate change impacts on crop water demand, middle Awash River basin, case study of Berehet woreda

Climate change mainly affects crops via impacting evapotranspiration. This study quantifies climate change impacts on evapotranspiration, crop water requirement, and irrigation water demand. Seventeen GCMs from the MarkSim-GCM were used for RCP 4.5 and 8.5 scenarios for future projection. A soil sample was collected from 15 points from the maize production area. Based on USDA soil textural classification, the soil is classified as silt loam (higher class), clay loam (middle class), and clay loam (lower class). The crop growing season onset and offset were determined using the Markov chain model and compared with the farmer’s indigenous experience. The main rainy season (Kiremt) starts during the 1st meteorological decade of June for baseline period and 2nd decade to 3rd decade of June for both RCP 4.5 and RCP 8.5 of near (2020s) and mid (2050s) future period. The offset date is in the range of 270 (base period), RCP 4.5 (278, 284), and RCP 8.5 (281, 274) DOY for baseline, near, and mid future. The rainfall and temperature change show an increasing pattern from the base period under both scenarios. Furthermore, the reference evapotranspiration (ETo) estimating model was developed using multiple variable regression and used for a future period in this study. In the base period, ETo increases from 33.4 mm/dec in the 1st decade of July to the peak value of 52.1 mm/dec in the 3rd decade of May. Under RCP8 .5, the 2nd decade of August ETO is minimal (44.3 mm/dec), while in 1st decade of April ETO was maximum (75.3 mm/dec) and raise from 44.3 mm/dec in the 2nd decade of August to the peak value of 75.3 mm/dec in the 1st decade of April. Under RCP 4.5, ETO raises from 33 mm/dec in the 1st decade of Dec to the peak value of 48 mm/dec in the 3rd decade of May. ETo shows an increasing trend from the base period under both scenarios. During the base period, a maize variety with a growing period of 110 days required 403.2 mm depth of water, while 67 mm is required as supplementary irrigation. Crop water and irrigation requirements of the maize variety with a growing period of 110 days are predicted to be 436.1 and 445.1 mm water during the 2020 and 2050 s for RCP 4.5, while 101.8 to 63.7 mm depth of water as supplementary irrigation respectively and 441.3 and 447.3 mm of water during 2020 and 2050 s of the future period for RCP 8.5, while 142.9 to 134.0 mm required as supplementary irrigation for both periods of RCP 8.5 scenarios. Crop water need will increase by 8.16 and 10.39% for RCP 4.5 and by 9.45 and 10.94% for RCP 8.5 of the 2020 and 2050 s respectively. In this study, a new ETO model is developed using a multiple variable linear regression model and its degree of the fitting is statistically tested and Kc is adjusted for the local climate, and hence, can be used in future irrigation and related studies. Generally, decision-makers, farmers, Irrigation engineers, and other stakeholders can use the results of this study in irrigation design, monitoring, scheduling, and other related activities. This is an Open Access article distributed under the terms of the Creative Commons Attribution Licence (CC BY 4.0), which permits copying, adaptation and redistribution, provided the original work is properly cited (http://creativecommons.org/licenses/by/4.0/). aponline.com/wpt/article-pdf/16/3/864/908008/wpt0160864.pdf Water Practice & Technology Vol 16 No 3 865 doi: 10.2166/wpt.2021.033 Downloaded from http://iw by guest on 14 August 2021


INTRODUCTION
Global food security is mainly being challenged by climate unpredictability in the world. Climate change refers to the increase in earth temperature due to the release of greenhouse gases into the earth's atmosphere (IPCC 2007). It remains a challenge for scholars to quantify its local impact due to the global scale of its impact. The climate change impact on crops can be impressive, due to fluctuations in the amount of CO 2 available for photosynthesis. Additionally, climatic factors such as temperature, precipitation, moisture, and pressure influence the plants' growth, either alone or in assistance with other factors (Cutforth et al. 2007).
Climate change leads to water scarcity and worsens desertification (Saad et al. 2011;OECD 2013). It also affects crop evapotranspiration and thus the irrigation water requirement (Osborne et al. 2000;Quiroga & Iglesias 2009). Crop evapotranspiration plays a key role in the designation and management of crop irrigation schedules (Djaman et al. 2018). Therefore, determining the irrigation water requirement of crops is very crucial for optimal irrigation scheduling. One of the most widely used means to determine crop water use is demand-based judgment (Ko et al. 2009;Ghamarnia et al. 2013). This approach uses the estimated ET and a crop-specific coefficient (Kc) to approximate the crop water use (Allen et al. 1998).
Globally, the population inhabiting dry lands exceeds two billion, which constitutes approximately 40% of the world's population (White & Nackoney 2003). In dryland regions, cereals are the mainly grown crops on which life depends (LADA 2008). Whereas, agricultural productivity in such areas is vitally dependent on water availability during the crop production season (Wang et al. 2016). Severe droughts and significant losses of yield in the arid and semi-arid zones are due to the rising temperature (Andreadis & Letten Maier 2006;Yadeta et al. 2020a). Similarly, in the middle Awash River basin of Ethiopia, the impacts of climate change are worsening crop production via increasing evapotranspiration losses (Yadeta et al. 2020b).
Thus, to bring sustainable food security in the area, drylands need to be managed precisely (UNEP 2000). To do so, promising measurements and predictions have to be accessible to safeguard water resources and agricultural sectors in drylands (Gan 2000). Ethiopia in general and the middle Awash basin, in particular, are susceptible to the impacts of climate change and variability (Tessema et al. 2020;Yadeta et al. 2020a). The higher temperature resulting from climate change will induce higher evapotranspiration (Yadeta et al. 2020b), which in turn affects the hydrological systems and agriculture. Investigation of climate change impacts on several sectors, particularly agriculture, is very core to the decision-makers; however, it is not well done yet in most developing countries like Ethiopia. Particularly in the middle Awash River basin, even though the impacts of climate change and variability are very devastating in the area, the study of climate change impacts on crops, soil moisture, and irrigation work through water stress is not yet investigated. Thus, estimating crop water and irrigation requirements for a proposed cropping pattern is an essential part of the planning and design of an irrigation system and it is important to convey the policy for water resources' optimal allocation along with decision-making in irrigation systems' operation and management.
Moreover, understanding the possible impacts of climate change is incredibly imperative in developing both adaptation strategies and actions to reduce climate change risks. Regrettably, the inadequacy in the information about the climate change impacts on crops reduces the ability of policymakers to adjust their plans to cope with the future. In line with this, adaptation to climate change has received more attention compared with mitigation. Parry et al. (1998) indicated that adaptation is more intricate than mitigation, emission sources are relatively few, but the array of adaptation is enormous, yet to ignore adaptation is both impractical and dangerous.
Adaptation refers to efforts to reduce the system's vulnerabilities to climate change impacts. According to IPCC (2007), adaptation is concerned with responses to both the negative and positive effects of climate change. A wide range of responses can be implemented by policy decisions at the regional or national level. These adjustments are adaptation strategies (Carter 1996).
At the farm level, agricultural adaptation to climate change depends on the technological potential, such as different varieties of crops, irrigation technologies, changing sowing dates, and changing irrigation schedules. But, in the study area, such adaptation strategies are not practiced yet. On the other hand, the ability of farmers to notice climate change and carry out any necessary actions will be reflected in achieving higher crop water productivity. Assessment of climate variability impact on agriculture at the local level has an enormous advantage in Ethiopia and crop water use also needs to be accurately predicted by correctly predicting evapotranspiration and the extraction of soil water by plant roots (Richter & Semenov 2005). Therefore, this study models the impacts of climate change evapotranspiration, crop water requirement, and irrigation water demand in the middle Awash River basin of Ethiopia.
The study is structured as follows. After this introduction, the following section presents the response types to observed meteorological and future scenario weather generations considered in the present assessment. As physical data (soil sample and agronomic) is determined and available, the emphasis is placed on the methods to integrate this information into a global soil and crop water modeling framework. ETo and season onset and offset were determined using the Markov chain and multiple variable linear regression model respectively. The subsequent section compares the aggregated yield of ETo, season onset and offset and crop water demand under climate changes.
The main drivers of changes in crop water demand are also explored through a decomposition analysis and ETo is modeling for both scenarios. The significance of the results is then discussed. The final section concludes and the limitations of the current study are set out.

Description of the study area
In the Kesem sub-basin of the middle Awash River basin, Berehet is located in the range of 39°59 0 E to 8°55 0 N in the Eastern part of Ethiopia and its area coverage is about 997 km 2 (Figure 1). It is surrounded by mountains and plateaus in its northern direction and is at a distance of 268 km from the Ethiopian capital city Addis Ababa. In administrative terms, the woreda is bordered on the south by the Germama River, which separates it from Menjarna Shenkora, to the west by Hagere Mariamna Kesem, in the north by Asagirt, and with the Afar Region to the east. The climate system of the area is described as semi-arid to sub-humid in the north and northwest; but the north and northeast, which covers the majority of the area, falls in the semi-arid climate, hence it receives a mean annual rainfall of 995 and 534 mm. The rural economy of the people in the Berehet woreda is based on both agricultural production and livestock rearing.

Primary data collection
Field survey and farmers experience A reconnaissance survey was conducted to visualize the nature of possible variations on the topography and soil of the study area to identify sampling locations (points) to ease the collection of soil  samples just for the sake of describing the soil and to scientifically compile and relate farmer's experience with the existing study's results.

Soil sampling and analysis
Soil sampling was undertaken for the Berehet woreda of the maize production area in the middle Awash basin. Thus, a total of 15 sampling points covering all selected areas of maize production land types were used. During survey work, maize-producing areas were pre-defined and the locations were collected. Based on the complexity of topography and heterogeneity of the soil type for each sampling point, 5 to 10 composite subsamples were taken from three classes by making a zigzag shape. A soil auger was used for collecting disturbed soil samples and then composited. Soil samples were taken at three depths (0-30, 30-60, and 60-90 cm). The soil auger and other sampling tools were cleaned before taking the next sample to lessen the cross-sample contamination among samples. After processing (drying, grinding, and sieving), the soil was analyzed for soil physicochemical properties following the standard procedure compiled by Sahlemedin & Taye (2000). The analyses were conducted at Werer Agricultural Research Center soil laboratory.

Determination of soil physical properties
Soil physical parameters like soil texture, bulk density (P d ), field capacity (FC), permanent wilting point (PWP), available water holding capacity (AWHC), and water infiltration rate were determined using appropriate procedures and methods amassed by Sahlemedin & Taye (2000).
The soil texture of the field was determined in the laboratory using the pipette method (Carter & Gregorich 1993). This is based on the direct sampling of the density of the solution. Soil bulk density was determined from an undisturbed soil sample taken using a core sampler of known volume (100 cm 3 ) that was driven into the soil of desired depth and calculated as the ratio of the oven-dry weight of soil to a known cylinder core sampler volume. Since bulk density varies considerably spatially, the measurements were taken at three different soil depths of the soil profile and 15 samples from the selected area of the district during the wet (maize production period) season. Mathematically, it is expressed as: where, BD ¼ bulk density, g/cm 3 ; Wd ¼ weight of oven-dry soil, g; Vr ¼ volume of ring, cm 3 .
Soil infiltration rates were determined at three sample locations (1 subclass Â 1 replication/sample), with one sample from each class. The measurement at each sample site was done in one replication using a double-ring infiltrometer.

Agronomic data
Crop data, which consist of the Kc values, stage days, root depth, and depletion fraction of the crop, were taken from FAO Irrigation and Drainage (FAO 2012). Information on maize varieties used by local farmers and planting date (onset date) was obtained during survey work from the local farmers by informal interview.
Observed meteorological data and future scenario weather generation Thirty years of observed meteorological data of the Shola Gebeya weather station were collected from the Ethiopian National Meteorological Agency. For future period climate projection, MarkSim_GCM was used, which requires only geographical location (latitude and longitude) to downscale and generate daily future weather data for a given site at the locality. MarkSim_GCM operates with the aid of 17 climate models. Therefore, the ensemble of the 17 GCMs Atmosphere-Ocean climate models have been used for RCP 4.5 and RCP 8.5 emission scenarios for two-time slices of the future period 2020 (2014-2043) and 2050 (2044-2073). MarkSim_GCM was accessed via http://gismap. ciat.cgiar.org/.

Data preprocessing
To make the weather datasets acquiescent to further analyses, the missing values were patched using the first-order Markov chain model with the aid of INSTAT plus V 3.37 (Stern et al. 2006) while the consistency and homogeneity of rainfall were checked by the double mass curve technique (Subramanya 2008) and using XLSTAT 2019 software by Standard Normal Homogeneity test method respectively. Finally, the projected data processes were evaluated using the standard deviation (SD) and mean absolute error (MAE), where in the latter is a quantity used to measure how close simulated forecasts were to the observed data (Willmott & Kenji 2005).

Data analysis
Determination of onset and offset date of the maize growing season In the current study, the start and end of the rainy season were determined scientifically using the Markov chain model and compared with the farmer's indigenous experiences. Accordingly, the onset of the rainy season is defined as the first occasion from the first of June that records 20 mm of rainfall amount or more over 3 days, and will not be followed by a period of more than 9 successive dry days in the next 30 days (Stern et al. 2003). The situations of having no dry spells of above 10 days after the start of the rainy season eliminate the possibility of a false start of the season. A period of 30 days is the average length for the initial growth stage of most crops (Allen et al. 2005). The end of the season is computed using first-order Markov chain modeling by considering maximum daily evapotranspiration of 5 mm and soil available water holding capacity of 100 mm. Given the above definitions, Instat statistical tool (Version 3.37) was used.

Modeling and estimation of reference evapotranspiration
Over time, several models have been developed and used for the estimation of evapotranspiration in different parts of the world. All the models have their weaknesses and strength based on the climatic conditions of the region they developed. Some of the methods use temperature data only while others use solar radiation and sunshine data only. Among all the models developed, the Penman-Monteith FAO 56 (PMF 56) is considered the standard method (Allen et al. 1998). This method is the most consistent estimator of evapotranspiration among all the climate-based empirical methods.
However, it is parameter rich requiring solar radiation, the sunshine duration for estimating net radiation; maximum and minimum temperature, psychrometric or relative humidity data for estimating the vapor pressure shortfall, and wind speed. But, collecting these parameters is very challenging due to their rare existence in many weather stations particularly in developing countries like Ethiopia. Therefore, in this study estimation of evapotranspiration followed two procedures. For the baseline period, Penman-Monteith FAO 56 (PMF 56) was used as follows: where, ETo ¼ Reference evapotranspiration(mm/day); Δ ¼ Slope of the saturated vapor pressure curve (kPa°C -1 ); R n ¼ Net radiation (MJ m -2 day -1 ); G ¼ Soil heat flux density (MJ m -2 day -1 ); T m ¼ Mean air temperature (°C) at 2.0 m; U 2 ¼ Average wind speed at 2.0 m height (m s -1 ); e s ¼ Saturation vapor pressure (kPa) at temperature Tm; e a ¼ Actual vapor pressure (kPa); (e s À e a ) is the vapor pressure deficit (kPa); and γ ¼ Psychrometric constant (kPa°C -1 ).
This method was used with the aid of the CROPWAT software model. However, for the future period, an empirical model was developed based on the historical climate data using multiple linear regressions with the aid of SPSS software, and used for the future reference evapotranspiration estimation. In this case, first, the climate parameters (maximum and minimum temperature, relative humidity, wind speed, solar radiation, and sunshine hours) and the ETO that is estimated using standard FAO 56 Penman-Monteith are prepared for the model development on monthly basis. Secondly, the climate parameters are considered as independent variables, and the ETO is estimated using FAO 56 Penman-Monteith as a dependent variable.
Then the climate parameters data of the study area were tested for the fittingness of a multiple linear regression model. The relation between ETO and the climate parameters was obtained and compared with a multiple linear regression model for ETO developed using the least-squares method, whose linearity was checked by residual analysis. For a multiple linear regression model, the dependent variable y is assumed to be a function of k independent variables x 1 , x 2 , x 3 … x k . The general form of the equation is computed as follows: where b 0 , b 1 , …, and b k are fitting constants; y i , x 1 , i, …, x k , I represent the i th observations of each of the variables y, x 1 , …, x k , respectively; e i is a random error term representing the remaining effects on y of variables not explicitly included in the model. For simple regression models, e i can be assumed to be an uncorrelated variable with zero means. The further most common technique for estimating the values of b 0 , b 1 … and b k is to employ the least-squares criterion with the minimum sum of squares of error terms (S); that is to find b 0 , b 1 , … and b k to minimize: Hence, b 0 , b 1 … and b k must satisfy the following: Since, ei ¼ yi observedyi calculated, the above equation becomes: This is because MarkSim_GCM gives only rainfall and temperature data. Hence, in the future period climate scenarios, only the influence of temperature (Tmax and Tmin) were considered while other weather parameters (solar radiation data or sunshine duration, relative humidity data, and wind speed) were considered from the baseline period data.

Adjustment of crop data
According to WARC (2016) and experiences of local farmers, the dominated and recommended maize varieties in the middle Awash basin is Melkassa Hybrid two (MB2). The crop data taken from (FAO56) were adjusted to the local condition of the study area. Depletion fraction was affected by ET O (Smith et al. 2006) as shown below: where: P adjadjusted depletion fraction, P tabtabulated depletion fraction. The K c value highly depends on relative humidity and wind speed at the mid-stage of crop growth. Hence, when the value of relative humidity is high (RH .80%) and the wind speed is low (u , 2 m/ sec) the k c should be reduced by 0.05 and its values should be improved by 0.05 if the relative humidity is low (RH ,50%) and the wind speed is high (u . 5 m/sec). The intervals out of the above situation were adjusted as: where: K c adjadjusted crop coefficient, K c (tab)tabulated crop coefficient, U 2wind speed, hthe height of the crop, RH minminimum relative humidity.

Estimation of crop and irrigation water demand
Estimating the crop water and irrigation requirements for a proposed cropping pattern is an essential part of the planning and design of an irrigation system and important in formulating the policy for optimal allocation of water resources as well as in decision-making in the day-to-day operation and management of irrigation systems. Therefore, Crop water requirement (CWR) was estimated as: where: CWR ¼ Crop water requirement, mm/day; K c adj ¼ Adjusted crop coefficient (adjusted using Equation (10) above); ETO ¼ evapotranspiration, mm/day (estimated using FAO 56 for base period Equation (2) and using the developed empirical model for the future period).
To estimate crop and irrigation water requirements, it is essential to estimate the effective rainfall over the cultivated area. Thus, effective rainfall (P eff ) was estimated using the USDA S.C (1985) method as: where, P eff ¼ Effective precipitation; P month ¼ mean monthly precipitation. Irrigation requirement (IRn) is the water that must be supplied through the irrigation system to ensure that the crop receives its full crop water requirement. Therefore, Irrigation water requirement (IRn) was computed using: where:

Rainfall and temperature change
The analysis showed that there was an increment in rainfall and temperature in the district. Rainfall show the likely increase within the range of þ5.7 to þ9.51% and þ3.45 to þ6.43% for both RCP 4.5 and RCP 8.5 scenarios respectively ( Figure 2). This result implies that wet condition are likely the prevailing weather of the future in the district (Kim & Yu 2012;Weller & Cai 2013). This finding is in harmony with the results of (Kim et al. 2008;IPCC 2013;Gebremeskel & Kebede 2017;Osima 2018;Yadeta et al. 2020aYadeta et al. , 2020bTessema et al. 2020). The minimum temperature was projected to increase by 1.04°C to þ3.02°C and þ0.03°C to 5.13°C under both scenarios for the 2020 and 2050 s and consistent with the result of (IPCC 2013; Tekleab et al. 2013;Osima 2018;Yadeta et al. 2020aYadeta et al. , 2020b. Also, the maximum temperature was expected to increase in the range of þ0.95°C to þ1.98°C and þ1.38°C to þ2.83°C for the 2020 and 2050 s of both scenarios. The change in minimum temperature was faster and greater than the maximum temperature. Such change is common globally (Paeth et al. 2005;Gebrehiwot & van der Veen 2013;Tekleab et al. 2013;Osima 2018) which indicates warming nights have occurred in recent times. The occurrence of high-temperature possesses occurrence of heavy rainfall, the reason is increasing temperature creates active hydrological cycle (IPCC 2013). Likewise, increasing temperature causes high evapotranspiration and, then crop and irrigation water requirement (Yadeta et al. 2020b).
Onset, offset, and length of the growing period of maize The main rainy season (Kiremt) starts during the 1st meteorological decade of June for the baseline period and 2nd decade to 3rd decade of June for both RCP 4.5 and RCP 8.5 of near (the 2020s) and mid (the 2050s) future period.
The onset dates lower and upper quartile falls between 152 to 167 DOY (day of the year) for the base period and 156 to 184 DOY for the 2020 and 2050 s for both scenarios (Table 1). This implies that the chance of getting an onset date on 167 and 184 DOY is 75% and can expect the situation at 152, 156, 151, and 161 DOY for both periods (Table 1). The earliest date of onset date was 131, 136,149, and 150 DOY while the latest date was 181 (base period), RCP 4.5 (186,196) and RCP 8.5 (209,192) and the optimal planting date was 156 (base period), RCP 4.5 (161, 171), RCP 8.5 (168, 173) for the base period, the 2020s and 2050s.
Late onset shortens the available length of the crop growing period and the potential to satisfy the crop water requirement (Green 1966). However, the baseline and future variability of onset date showed less variability compared to LGP but highly variable than cessation date, and showed less standard deviation compared to LGP but higher than cessation. The higher standard deviation of the onset date indicates that patterns could not be easily understood and consequently, decisions  relating to crop planting and related activities must be made with a high level of caution. The result is similar to the study undertaken by Abiy et al. (2014), which stated that informed decision-making in crop planting is the essential activity in agricultural planning more importantly when aligned with characteristics of onset, offset, and LGP of the rainy season. The offset date is in the range of 270 (base period), RCP 4.5 (278, 284), and RCP 8.5 (281, 274) DOY for baseline, near, and mid future periods respectively, as shown in Table 1. The upper quartile, lower quartile, minimum and maximum for offset date during the base period indicate that for the chance of getting 75% of the time, the end date will occur at 270 to 284 DOY. The LGP for maize production in the main rainy season ranged from 93 to 165 rainfall days for the baseline and future period respectively. The mean LGP of the area ranges from 113 to 118 rainfall days. This study agrees with Yadeta et al. (2020a).

Soil characteristics analysis
The results for the composition of clay, silt, and sand percentages are shown in Table 2. Thus, as per the USDA soil textural classification, the soil was classified as silt loam (higher class), clay loam (middle class), and clay loam (lower class) soil.
Soil bulk density of the area showed variation with the land class (Table 3) for all soil textures. It varied between 1.41 to 1.47 gm cm À3 and generally, the lower class soil has slightly lower bulk density than the middle and higher class, with an average bulk density of 1.42 gm cm À3 for clay loam texture. From higher to lower class, the soil bulk density decreases. As bulk density increases, soil pore space gets smaller, tending to increase soil compaction. The smaller the soil compaction, the greater the moisture content at field capacity and permanent wilting point in the selected area, and the reverse was true for higher soil compaction. The average water content at field capacity and permanent wilting point of the soil were determined to be 30.83 and 9.17%, respectively, for silt loam and 41.8 to 24.74 for clay loam. The moisture content at field capacity varied with depth between 31.7 to 30.9% and 37.28 to 41.56% on a mass basis for silt loam and clay loam, respectively. The top (0-30 cm) has a larger average water content of field capacity while the subsurface 30-90 cm has a lower value of field capacity in all textures.
The permanent wilting point moisture content showed variation with depth, as shown in Table 3. Total available water (TAW), which is the depth of water that a crop can extract from its root zone, is directly related to variation in field capacity and permanent wilting point. The total average available soil moisture for silt loam texture was 21.71 cm/cm and 14.47 to 15.37 cm/cm for clay loam. The measurement of infiltration rate at each sample site ranges between 10-15 mm hr À1 for silt loam and 5-7 mm/hr for clay loam soil using a double-ring infiltrometer. Hence, the average value of soil infiltration rate in the selected area of the study area was 12.0 and 6.0 mm hr À1 for silt clay and clay loam, which is analogous with WARC (2016).

Reference crop evapotranspiration (ET O ) under current climate
Using the decadal averaged daily ET O, reference evapotranspiration of the Shola Gebeya station is calculated by using the Penman-Monteith method, as shown in Table 4. It is observed that the annual reference crop evapotranspiration was estimated at 1,587.75 mm per year, which is equal to 43.5 mm per 10 days. The mean annual rainfall (1,114.12 mm per year) was lower than the reference crop evapotranspiration by 473.6 mm per year.
Maximum ETO occurred in the month of March, which is 49.4 mm/dec, and the minimum occurred in the month of December, with a mean of 29.2 mm/dec. Moreover, in the decade, maximum ETO was 52.10 mm, equivalent to 5.21 mm per day, and happened in the 3rd decade of May and the minimum value occurred during the 2nd decade of July which was estimated at 29.20 mm per decade. This implies that ET O will be high during the belg seasons for the baseline period. This is due to high extreme temperature, wind and solar radiation, and low relative humidity. Therefore, the results imply that the enhancement of rainfall couldn't be a guarantee to reduce the rate of evapotranspiration. This is possibly due to the change in temperatures. In this regard, it was confirmed that climate change would have a severe consequence even in better rainfall distributions. Therefore, using this season for maize production would affect the yield in terms of water stress in the study area.
As shown in the model, Sunshine hour is the greatest contributor (at the rate of 0.324 unit), the second positively influencing variable is wind speed (0.294 unit), the third positively influencing variable is solar radiation (0.251 unit) followed by Tmax (0.088 unit) and Tmin (0.008 unit) ( Table 5). Except for the relative humidity, which negatively influences by À 0.016 unit, other climate parameters had a positive effect on ETO. Positively influencing means occurred with increasing weather parameters, there could be an increase of ETO and vice versa for the negatively influencing variables. In agreement, Yadeta et al. (2020b) found that except for relative humidity, the remaining weather parameters have a direct relationship with ETO. Generally, the weather parameters used in the modeling and the specification formed were sufficient, implying that this model can be successfully used in estimating the ETO of the area, and another place having similar weather conditions with the study area.
Analysis of variance (ANOVA) and regression model fitting for the predictors 94.8% of ETO variation shown has been caused by the joint influence of local weather parameters. Statistically, a realistic R 2 value was observed by the variance inflation factor and multiple regression model, which could be a sign of there being no multi-co-linearity problem among the selected predictor variables, as shown in Table 6. Validation results confirmed that the model with the used weather variables can effectively estimate the ETO of the study area, and areas with similar climatic conditions, with great performance. This result is also similar to Yadeta et al. (2020b).

Future reference crop evapotranspiration (ET O )
The current study found that there is an expectation of high values of ET O in future scenarios following the higher temperature. The ET O in the baseline period, the 2020s and 2050s by scenarios are presented in Figure 3. Thus, ET O in the base period varies in the range of 33.4 to 52.1 mm/dec. It increases roughly from 33.4 mm/dec in the 1st decade of July to the peak value of about 52.1 mm/ dec in the 3rd decade of May. The highest ET O in March can be explained by the hot (before the afternoon time) and windy weather conditions of this month.
In the RCP 8.5 scenarios, minimum and maximum ET O was predicted to be in the range of 44.3 to 75.3 mm/dec. In the 2nd decade of August, ET O was minimal (44.3 mm/dec) while in the 1st decade of April ET O was maximum (75.3 mm/dec). It increases roughly from about 44.3 mm/dec in the 2nd decade of August to the peak value of about 75.3 mm/dec in the 1st decade of April. In the case of RCP4.5 scenarios, ET O varies in the range of 33 to 48 mm/dec. The ET O increases roughly from approximately 33 mm/dec in the 1st decade of Dec to the peak value of about 48 mm/dec in the 3rd decade of May. The projected ET O change between RCP 4.5 and RCP8.5 is significant (Figure 3).
Comparison between the base period and the scenarios show that the peak value ET O increases from 33 to 48 mm/dec for RCP 4.5 and from 44.3 to 75.3 mm/dec for RCP 8.5. The yearly ten-day average ET O was 40.88 mm/dec in the base period, which was predicted to be 41.57 mm/dec for RCP 4.5 and 58.44 mm/dec for RCP 8.5 scenarios. The percentile change in ET O was found as   À0.04, 1.02% for RCP 4.5 of the 2020s and 2050s and 21.24, 24.29% change in ETO for RCP 8.5 of the 2020s and 2050s respectively. The result is similar to the study undertaken by Rao et al. (2011). The mean decadal change in ET O for the two scenarios is presented by the period in Figures 4 and 5. These figures reveal that ET O will be high during the Belg and kiremt seasons of the year. This is possibly due to the change in extreme temperatures. In this regard, it was confirmed that climate change would have a severe consequence even in better rainfall distributions (Yadeta et al. 2020a). Kiremt season will be characterized by the lower rate of reference evapotranspiration in both 2020s and 2050s for the two scenarios in respect of belg season.

Effective rainfall under the influence of variable climate scenarios
As per the USDA S.C (1985) method, the effective rainfall was calculated for each growing period and stage of maize as shown below on a monthly basis for the baseline period (Table 7).
Like that of the baseline period, the effective rainfall of the future period was calculated via the USDA S.C (1985) method, for each growing period and stage of maize as shown below on a monthly basis (Table 8).

Adjusting crop characteristics based on the observed climatic conditions
The suggested values of k c for maize growth by FAO-56 guidelines are 0.15 for initial, 1.5 for midseason, and 0.5 for late-season. However, during the baseline period, the relative humidity is between  50 and 80% and wind speed is greater than 2 m/s in the months of June, July, August, and September. Hence, the k c value was adjusted as per Equations (14) for mid-season, as shown in Table 9.
During the initial stage for annual crops, evapotranspiration is mostly in the form of evaporation. Therefore, precise estimates for K c ini were considered the frequency with which the soil surface is wetted during the initial period. Where the soil is frequently wet from rain, the evaporation from  Rec. rainrecorded rainfall; Eff. Raineffective rainfall. the soil surface can be considerable and K c ini is large. On the other hand, when the soil surface is dry, evaporation is restricted and the K c ini are small (Table 9). K c mid is less affected by wetting frequency than is K c ini , as vegetation during this period is generally near full ground cover so the effects of surface evaporation on K c are lesser. For frequent rain of crops, the K c mid of less than 1.0, the value can be replaced by approximately 1.1-1.3 to account for the combined effects of continuously wet soil (FAO 2011). Therefore, both the soil surface and vegetation are dry and the value for the K c end was relatively small. Regarding depletion fraction, the suggested depletion fraction by FAO was 0.55% for ET O ≈ 5. But the average ET O during the maize growing period in the Berehet woreda was 4.06 mm/day, which is less than the suggested one. Hence, the depletion fraction during the maize production period needs adjustment using Equation (9). As per the equation, the adjusted value of depletion fraction in percentage was adjusted to 0.59%.

Maize crop evapotranspiration (ETc) of the baseline period
Often rainfall is vital but not adequate to cover the water requirement of the crops (Smith et al. 2006). Crop production in the dry season is only possible with irrigation, while it might be possible in the rainy season but unreliable because of prolonged dry spells and drought; yields will be less than optimal production. When rainfall is not enough to cover the water demands of crops, irrigation water has to supplement the rainwater in such a way that the rain and irrigation water together satisfies the water needs of crops.
It is essential to know the water requirement of a crop, which is the total quantity of water required from its sowing time up to harvest. Different crops may have different water requirements at different places in the same country, depending upon the climate, type of soil, method of cultivation, and effective rain. At the same time, water supplies available for irrigation will become more variable and will decline because of climate variability and change. Climate alteration will affect agriculture by boosting water demand, off-putting crop productivity, and dropping water availability in areas where irrigation is most needed or has a comparative advantage.
Thus, once climate change impacts are appraised, it is important to analyze what measures should be taken to adapt to the potential consequences of climate variability related to irrigation. One possibility is to expand irrigation with locally available water sources. Where rain-fed cropping systems are displaced to the margins, the delivery of irrigation plays a strategic role in either stabilizing the production of grains or in supporting a low danger, high-value production system with a strong commercial focus. Therefore, the water needs of maize crops during the baseline period were done for clay loam soil textures since it covers more than 70% of the selected area. Table 10 shows summaries of crop water and irrigation needs of maize in the study area. A maize variety with a growing period of 110 days to maturity would require 403.2 mm depth of water, while 67 mm would be required as supplementary irrigation depth.
Implication of climate change on maize water needs under future period As per the baseline period, maize water needs for the future period under RCP 4.5 and RCP 8.5 scenarios need input data like ET O , soil data, crop data, and effective rainfall for computation of maize water needs. Even though it is recommended to estimate future soil data, its value varies between pointed intervals (FAO 2011). Therefore, soil data of the baseline period were used for the future one, and the above determined ET O , crop data and effective rainfall were used. Accordingly, the crop water and irrigation requirements of a maize variety with a growing period of 110 days to maturity were predicted to be 436.1 and 445.1 mm depth of water during the 2020s and 2050s of the future period for RCP 4.5, while 101.8 to 63.7 mm depth of water would be required as supplementary irrigation respectively. Whereas, 441.3 and 447.3 mm depth of water was required during the 2020s and 2050s of the future period for RCP8.5, while 142.9 to 134.0 mm would be required as supplementary irrigation for both periods of RCP 8.5 scenarios (Table 11).
These results reveal that the average rate of CWR is increased approximately by 8.16 and 10.39% for RCP 4.5 and by 9.45 and 10.94% for RCP 8.5 scenarios of the 2020s and 2050s respectively. The result is similar to the study undertaken by Rao et al. (2011). According to Rao et al. (2011), the crop water requirement of maize for the future period of 2025 and 2050 ranges between 404 to 447 mm in semihumid to semi-arid agro-ecology from the base period of the 1990s. Also, it is significant to note that projections of water demands of semi-humid to arid for the future period, which is worked out by the IWMI (International Water Management Institute), said that even with the lower estimates projected by the IWMI, there will be a substantial future increase in irrigation water requirements (Sharma 2006).

CONCLUSION
This study quantifies climate change impacts on crop and irrigation water demand in the middle Awash River basin. The main rainy season (Kiremt) starts at 156 DOY for the baseline period and 161 to 171 DOY for RCP 4.5 of the 2020s and 2050s and 168 and 173 DOY for RCP 8.5 of the 2020s and 2050s of a future period. It ceases in the range of 274 to 286 DOY for the baseline and future periods and has an LPG of between 113 to 118 rainfall days. In this season, the rain will likely increase by about 1.8% by the 2020s and 20% by the 2050s for RCP 4.5 and 6% by the 2020s, and 21.73 by the 2050s for RCP 8.5 scenarios.
ETO is in the range of 33.4 to 52.1 mm per decade in the base periods, which is predicted to be in the range of 44.1 to 75.3, and 33 to 77.3 mm per decade for RCP 4.5 and RCP 8.5 respectively for the 2020s and 2050s. Overall, there is 0.04, 1.02% for RCP 4.5 of the 2020s and 2050s, and 21.2, 24.3% change in ETO for RCP 8.5 of the 2020s and 2050s from the base period. CWR will be 436.1, 445.1 mm for RCP 4.5 and 441.3, 447.3 mm for RCP 8.5 and IR ranges between 63.7 to 101.8 mm for RCP 4.5 and 142.9 to 134 mm for RCP 8.5 of the 2020s and 2050s. CWR will increase by 5.1 and 9.5% for RCP 4.5 and by 6.55 and 10.3% for RCP 8.5 of the 2020s and 2050s from the base period. Increment in CWR can cause an increase in stress on the water resource. In this study, a new ETO model is developed using a multiple variable linear regression model and its degree of fitting is statistically tested and Kc is adjusted for the local climate; hence, it can be used in future irrigation and related studies. Generally, decision-makers, farmers, irrigation engineers, and other stakeholders can use the results of this study in irrigation design, monitoring, scheduling, and other related activities. Further studies on climate modeling that integrate soil-water-atmosphere, socio-economic and institutional aspects of a climate system under different emission scenarios by using multiple crop simulation models should be conducted to assess the potential impact of future climate change on crop production and design adaptation strategies for development policy for the future.

ACKNOWLEDGEMENTS
Special thanks are due to the Ethiopian National Meteorological Agency for providing us with the meteorological data. Also, we would like to acknowledge the Werer Agricultural Research Centre soil laboratory for analyzing the physicochemical properties of soil.