Introduction
Land degradation in the form of soil erosion has significant on-site as well as off-site effects in Ethiopia. On site, it imposes an undesirable impact on agricultural production and undermines implementation and success of sustainable intensification (Adimassu et al., Reference Adimassu, Mekonnen, Yirga and Kessler2012; Gebrehiwot et al., Reference Gebrehiwot, Bewket and Gärdenä2013). Due to mismanagement, Ethiopia experiences the worst soil erosion problem in the world (Hengsdijk et al., Reference Hengsdijk, Meijerink and Mosugu2005). In the Blue Nile Basin, soil losses due to runoff vary from 1 to over 400 tons ha−1 yr−1 (Hurni, Reference Hurni1988; Mitiku et al., Reference Mitiku, Herweg and Stillhardt2006; Tebebu et al., Reference Tebebu, Abiy, Zegeye, Dahlke, Easton, Tilahun, Collick, Kidnau, Moges, Dadgari and Steenhuis2010). The empirical model also estimated that the average gross soil loss for the Blue Nile reached about 85 tons ha−1 yr−1 (Tamene and Le, Reference Tamene and Le2015). Different studies also reported that high soil loss occurs from cultivated land, ranging from 50 to 179 ton ha−1 yr−1 (Shiferaw and Holden, Reference Shiferaw and Holden1999; Adimassu et al., Reference Adimassu, Mekonnen, Yirga and Kessler2012). In addition, annual crop yield reduction of 1–2% is estimated due to soil erosion in Ethiopia (Hurni, Reference Hurni and Pimentel1993). Moreover, in Ethiopia approximately 17% of the potential agricultural gross domestic product in 1990 was lost because of soil degradation (EPA, 1997). The direct cost of soil loss due to mismanagement reaches at $106 million a year (Bojo and Cassells, Reference Bojo and Cassells1995). On the other hand, soil erosion also has tremendous off-site effects, specifically siltation of reservoirs, irrigation canals, flooding as well as deterioration of ecological services. It is estimated that the trans-boundary Rivers of Ethiopia alone carry about 1.3 billion tons of sediment each year (Birhane, Reference Birhane, McCornick, Kamara and Tadesse2003). Due to high soil erosion, it is also estimated that 95% of the Nile River sediment is coming from the Ethiopian highlands (Ahmed and Ismail, Reference Ahmed and Ismail2008). The water harvesting (WH) schemes developed for supplemental irrigation in Ethiopia have been compromised due to rapid siltation (Tamene and Vlek, Reference Tamene and Vlek2007). And so, the largest hydropower dam of Africa when completed (the Great Ethiopia Renaissance Dam) is expected to be suffering due to high siltation problem. The high soil erosion in the Ethiopian highlands also affects downstream hydraulic structures whereby siltation in Roseires Reservoir in the Blue Nile and Aswan High Dam in the main Nile has not only reduced a significant amount of reservoir capacity but also is a challenge requiring expensive irrigation canal maintenance (Ahmed and Ismail, Reference Ahmed and Ismail2008). On the other hand, land use land cover change has a considerable effect on stream flow (Bewket and Sterk, Reference Bewket and Sterk2005; Rientjes et al., Reference Rientjes, Haile, Kebede, Mannaerts, Habib and Steenhuis2011; Koch et al., Reference Koch, Griensven, Uhlenbrook, Tekleab, Teferi, Seppelt, Voinov, Lange and Bankamp2012; Tekleab et al., Reference Tekleab, Mohamed and Uhlenbrook2013). Other studies have also reported that it has an impact on sediment yield (Girmay et al., Reference Girmay, Singh, Nyssen and Borrosen2009; Setegn et al., Reference Setegn, Srinivasan, Dargahi and Melesse2009; Gebremicael et al., Reference Gebremicael, Mohamed, Betrie, Zaag and Teferi2013; Maeda et al., Reference Maeda, Formaggio and Shimabukuro2013; Spalevic et al., Reference Spalevic, Lakicevic, Radanovic, Billi, Barovic, Vujacic, Sestras and Khaledi Darvishan2017)
Considering the on- and off-site effects of soil erosion and the associated economic as well as environmental burdens, the government of Ethiopia designed a national program to tackle land degradation. Significant amount of soil and water conservation (SWC) work has been implemented as of 1975 (Shiferaw and Holden, Reference Shiferaw and Holden1999; Hurni, Reference Hurni2000c; Osman and Sauerborn, Reference Osman and Sauerborn2001; Taddese, Reference Taddese2001). After the 1984–85 drought, the massive re-afforestation and conservation campaign intensified until 1990 (Berry, Reference Berry2003). Currently, there are government claims that billions of trees have been planted, and millions of hectares of land conserved through the construction of terraces, deep trenches, percolation ponds, etc. across the different parts of the country.
Despite non-systematic and scattered, results of some studies showed the impacts of the various interventions. For instance, an impact assessment study in Anjeni watershed reported that land suitability of the watershed for crop production improved due to terracing (Alemu et al., Reference Alemu, Amare, Woldetsadik, Selassie, Wolfgramm and Hurni2013). Moreover, the average financial internal rate of return was 301% in Anjeni watershed due to productivity enhancement caused by improved SWC practices (Adgo et al., Reference Adgo, Teshome and Mati2013). Integrated catchment management is also efficient and effective at combating land degradation in Northern Ethiopia (Nyssen et al., Reference Nyssen, Clymans, Poesen, Vandecasteele, Haregeweyn, Naudts, Moeyersons, Haile and Deckers2009). Other studies (Descheemaeker et al., Reference Descheemaeker, Muys, Nyssen, Poesen, Raes, Haile and Deckers2006; Mekuria et al., Reference Mekuria, Veldkamp, Haile, Nyssen, Muys and Gebrehiwot2007; Yayneshet et al., Reference Yayneshet, Eik and Moe2009; Angassa and Oba, Reference Angassa and Oba2010) also showed the success of interventions such as enclosures in some parts of the country. Most of the studies aimed to assess the impacts of interventions focused on single practice and/or have not assessed impacts at different scales. This study attempted to evaluate the impacts of land use/cover types and SWC practices on soil loss and runoff at different scales. It is also attempted to evaluate the reduction efficiency of the interventions over years. The information generated in the study will both provide evidence on the performances of the various SWC practices and helps raise awareness of the local communities and government bodies and facilitate planning and targeting.
Materials and methods
Location and brief description of the study area
This study was conducted in a watershed located in the most eastern part of the Jemma river sub-basin of the Blue Nile River Basin in Ethiopia (Fig. 1). Administratively, the site is located in the Gudo Beret Kebele (village) of the Basona Worena district. Considering temperature (six thermal zones) and moisture (seven classes of length of growing periods), Ethiopia is classified into 32 major agro-ecologies (MoARD, 2005). Based on this classification, the study watersheds are classified as cool sub-moist highland, a zone covering more than 13,000 km2 area (1.2%) of the country. For this class, temperature varies from 11 to 15°C with an elevation variation of 2400–3200 m above sea level.
Meteorological data from a nearby station show daily minimum temperature within a range of 0.5–19.5°C. The maximum daily temperature ranges from 9.5 to 28.5°C. Monthly rainfall distribution for each year is highly variable (coefficient of variation, CV > 30%) except in July and August (25%). Despite high monthly rainfall variability, annual total variability is quite low (CV = 16%) with an average rainfall amount of 1449 mm and standard deviation of 228 mm (Fig. 2). The nearby metrological station data also revealed that the study area received bimodal rainfall, Kiremit (June to September) being the long-rainy season and Belg (February to March) is short-rainy season. However, there is little occurrence of rains and/or absence during the short-rainy season (Belg rain). The same pattern is reported by other studies in the region (Engda, Reference Engda2009).
The major farming system of the area is crop-livestock production. The major crops grown include barley, wheat, faba bean and potato. The area has generally moderate slope but descending to very complex, rugged and steep slope toward the Jemma River.
Selection and characterization of the sub-watersheds
Two proximate sub-watersheds with similar physiographic characteristics were identified to assess the impacts of SWC practices on runoff and soil loss. The two sub-watersheds are adjacent to each other with an altitude range between 3040 and 3160 m above sea level. Both sub-watersheds have oval shape where the dimension is wider at the middle part (Fig. 3).
Sub-watershed1 (WS1) where SWC practices were implemented as of 2013 is about 910 m long and 457 m wide at the middle part of the watershed. Sub-watershed2 (WS2) without SWC only in 2014 is about 837 m long and 360 m wide at its middle part. SWC practices were introduced in sub-WS2 since 2015. About 87 and 85% of the area has slope greater than 8% for the WS1 and WS2, respectively (Table 1). Land use distribution of the two watersheds is similar whereby about 68 and 64% of the WS1 and WS2, respectively, are classified as cultivated land (Table 1).
Our field assessment and aerial photograph interpretation showed minor differences in overall topographic and geo-morphological settings. The dominant landform elements in both sub-watersheds in ascending order are spur, ridge and slope (Table 1).
Data collection and analysis
Experimental set-up to assess soil erosion and runoff at the plot level
Runoff plots were setup within sub-WS1 to evaluate the effect of different land uses and SWC practices on runoff and soil loss during 2014 to 2017 rainy season (Kiremit) (Fig. 3). Four treatments (with different land use and management options) were assessed (Table 2). Treatment 1 was control (cultivation without soil bund) where rotation of faba bean with barley was practiced. Faba bean was planted in the first year of the experiment. Treatment 2 was similar land use to treatment 1 but it had SWC measures in place mainly level bund with trench. The spacing between consecutive conservation structures inside the plot was 12 m. Treatment 3 was established at woodlot (Eucalyptus trees) treated with well-established grassland underneath. Treatment 4 was grazing land (cut and carry practiced). The plot-level treatment at the grazing was within the treated watersheds, thus free roaming and grazing of livestock is restricted.
After the locations and land uses were identified, hydrologically bounded runoff plots of 15 m length and 4 m width were installed for each treatment (Fig. 4) within sub-WS1. Eight runoff plots (four treatments with two replications) were laid out on 10% land slope. Plot boarders were enclosed by iron sheets except for lower ends where collecting trough and slotting devisor were placed. The iron sheets were placed 18 cm above and 15 cm below the ground surface to prevent run-on entering into and runoff out of the plots. Water and sediment collection tanks (tank A and tank B) were placed in a cascading manner to receive runoff and eroded soil collected from each plot. Each tank was attached to the container through a device (slotting divisor) to receive fraction of runoff from each plot (Adimassu et al., Reference Adimassu, Mekonnen, Yirga and Kessler2012). The two tanks were firmly fixed into the ground so that flood or subsurface flow will not overturn them. To complement the existing meteorological station (owned by national meteorological agency for precipitation and temperature), an automatic weather station (for precipitation, temperature, relative humidity, wind speed and soil moisture) was installed at Gudo Beret town, about 1 km away from the study plot location.
Runoff and soil loss estimation at the plot level
The depth of water collected in both tanks A and B was measured from each treatment using a graduated measuring stick every morning on a daily basis in order to determine the volume of runoff. After it was stirred thoroughly, half a litter of runoff sample was taken for sediment concentration analysis using special evaporation method (Guy, Reference Guy1977). In the laboratory, the water samples were put into the beakers and 10 ml of 10% HCl was used in each beaker as a flocculating agent to reduce the settling time of naturally dispersed clay and speed up the siltation process within 24 h. After carefully pouring out the clean water, the remaining turbid sample was taken and oven dried at 105°C for 24 h in order to determine the dry soil weight. In addition, the wet sediment on runoff collecting ditch (the place between the plot and the slot divisor) was weighed and known sample (100–250 g) taken for oven dried in order to determine the dry sediment weight. The suspended sediment concentration (SSC, g l−1) of each sample was determined as the mass of suspended sediment divided by the sample volume. The SSC was then multiplied by the total daily volume of run-off in order to estimate the total suspended soil losses. The total daily soil loss was calculated as the sum of suspended soil loss and dry sediment from runoff collecting ditch.
Installing hydrological stations to estimate discharge and sediment yield at the watershed level
To facilitate comparing treatment effect, a pair of sub-watersheds with similar terrain, soil, and land use characteristics was identified within the study watershed. Two hydrological stations were then installed at the outlet of the two sub-watersheds to measure discharge and sediment yield (Fig. 3). The two sub-watersheds have an area of 33.83 and 22.08 ha. The former is treated with about 0.36 km ha−1 length terrace integrated with trench and grass strips, while the second is without any significant SWC structures in place (only in 2014). SWC measures were implemented from 2015 onward (in sub-WS2) and our analysis considered temporal variation. Manual measurements of water flow and sediment sampling were made on two gaged streams at the outlets of the two sub-watersheds. Each measurement consisted of reading flow depth, determining runoff discharge (Q, m3 s−1) using the velocity area method and sampling the suspended sediment. Gage readings were taken two times a day (morning and evening). If abrupt change in stream depth is observed especially during rainfall event, more than three measurements and sediment sampling were taken every day. To avoid bias on the estimation of the sediment export, data were collected as much as possible on a flow proportional basis since highest suspended sediments were observed during rainfall events. In order to determine discharge at different flow depth, velocity and cross-sectional area measurement were occasionally taken at the outlet of the watershed. Accordingly, measurements (at different depths in between 10 and 72 cm) were taken to determine discharge-depth relation. Rating (fitting) curves are determined for low (<15.5 cm), medium (15.5–30 cm) and high flow (>30 cm) in both WS1 and WS2 (Fig. 5). Refer to equations (Equations 1 and 2) in the section ‘Discharge, sediment concentration and sediment yield estimation’.
Discharge, sediment concentration and sediment yield estimation
Once flow depth data were collected, discharge (Q) was determined using the area velocity method (Bartram and Ballance, Reference Bartram and Ballance1996; Vanmaercke et al., Reference Vanmaercke, Zenebe, Poesen, Nyssen, Verstraeten and Deckers2010). To convert the flow depth to runoff discharge, depth–discharge relationships were developed between the manually measured instantaneous runoff discharges and their corresponding flow depth:
where Q is the discharge in m3 s−1; d is the calibrated flow depth in cm and a, b, c, r and s are empirical constants. The power equation (Equation 1) is best fitted for low and medium flows in both watersheds. The polynomial equation (Equation 2) is best fitted for high flow in both watersheds. Refer to empirical constants of the fitting curves shown in Figure 5.
For sediment concentration analysis, around 500 ml river water sample was taken using integrated sediment sampling. The same procedure as in the section ‘Runoff and soil loss estimation at the plot level’ was used for sediment concentration analysis in the laboratory. Daily sediment export values were then calculated as (Asselman, Reference Asselman2000):
where Qs,d is the daily sediment export (ton day−1); n is the number of sediment sampling intervals per day; Qi is the runoff discharge for each sediment sampling interval (m3 s−1), derived from the continuous flow depth series with Equations (1) and (2); SSCi is the corresponding estimated SSC (kg m−3) and Ti is the corresponding time interval (s). Total sediment export was then calculated as the sum of all Qs,d values. For statistical analysis purpose, the daily discharge data were summarized on weekly basis.
Land use, slope, terrace length and hydrological analysis
The land use of the study watershed was produced from high resolution (0.5) PLEIADES satellite image (2013) using ArcGIS 10.1. After defining training area and signature files, the maximum likelihood classification tool was used to produce land use map of the study area. Slope of the study watersheds was produced from the recently released SRTM 30 m DEM (Jarvis et al., Reference Jarvis, Guevara, Reuter and Nelson2008). The length of the terrace of the study watershed was estimated from Goggle Earth (since the area has high resolution recent image) on screen digitizing using Google Earth tools (Fig. 3).
A web GIS-base Hydrological Analysis Tool was used to separate base flow using the recursive digital filter method (Lim et al., Reference Lim, Engel, Tang, Choi, Kim, Muthukrishnan and Tripathy2005; Recha et al., Reference Recha, Lehmann, Walter, Pell, Verchot and Johnson2012). Total daily flow (91, 136, 94 and 91 days for the respective 2014, 2015, 2016 and 2017 year) were used for both watersheds in analysis. The base flow index (BFI) and the flashiness index (RB index) were used to characterize the impacts of land management in the sub-watersheds hydrology. The BFI (the ratio of base flow to total flow) indicates the dynamics of stream water in relation to the ground water aquifer (Moliere et al., Reference Moliere, Lowry and Humphrey2009; Berhanu et al., Reference Berhanu, Seleshi, Demisse and Melesse2015). The RB index indicates the frequency and rapidity of short term changes in stream flow (Baker et al., Reference Baker, Richards, Loftus and Kramer2004):
where i is the time step (i = 1, 2, …, n) and q is the daily flow.
Data organization for scale comparison
In order to derive the watershed values, the plot soil loss and runoff values were used with the corresponding land use types and management practices. The weighted average plot values (based on proportional area of each land use) were used to compare with that of water and sediment yield measured at the watershed scale. Soil loss and runoff at the different scales were extracted per land use/cover types to understand major differences and possible drivers.
Data analysis (statistical)
The runoff and soil loss data were subjected to analysis of variance using the SAS statistical computer package version 8.2. The total variability for each trait was quantified using separate and pooled analysis of variance over years using the following model (Gomez and Gomez, Reference Gomez and Gomez1984):
where Pijk is the total observation, μ is the grand mean, Yi is the effect of the i th year, Rj (i) is the effect of the j th replication (within the i th year), Tk is the effect of the k th treatment with i th year, TY (ik) is the interaction of k th treatment with i th year and eijk is the random error. A least significant difference test at the 5% level of significance was used in order to establish the differences among the means.
Results
Runoff and soil loss at the plot level
Within 4 years, a total of 48 runoff events (15, 9, 9 and 15 events, in years 2014, 2015, 2016 and 2017, respectively) were observed. The highest mean runoff (434 mm) was observed on grazing land and was highly significantly (P < 0.01) different compared to that of the woodlot and managed crop land treatments (Fig. 6). In the period of our study, terraces together with trenches reduced runoff by 44, 31, 14 and 17% on crop land in comparison with unmanaged crop lands in the respective years of 2014, 2015, 2016 and 2017, with a mean reduction of 26%. Figure 6 shows that eucalyptus woodlots averagely reduced runoff by 20% over the study period in comparison with unmanaged crop lands.
In terms of soil loss, the highest mean rate (8.56 ton ha−1) was recorded from unmanaged cropland and this is highly significantly (P < 0.01) compared to other land use types (Fig. 7).
Discharge and sediment yield at the watershed level
The comparisons of discharge and sediment yields at the watershed level are based on sub-WS1 with SWC and sub-WS2 without SWC practices for the year 2014, and with various ages of SWC practices in years 2015, 2016 and 2017 (Table 3). The results of the first year (2014) discharge and sediment yield assessment showed clear differences between the two sub-watersheds; with and without SWC practices. For statistical analysis purpose, the daily discharge data were summarized on weekly basis. Discharge showed significant variation (P < 0.01) between the two sub-watersheds in the first year. However, there were no significant differences in the second, third and fourth years (Table 4). Due to the lack of maintenance, the effectiveness of SWC is reducing over the years. This means that the SWC would not provide the intended service more than four years for this particular case. In the first year (2014) discharge was 298 and 535 mm from WS1 and WS2, respectively. A 44% reduction in discharge was observed due to the implementation of SWC measures at the sub-watershed scale. The intervention impact is also reflected on storm unit hydrograph (Fig. 8). The discharge of sub-WS1 is smaller due to the fact that some of the water is retained inside the trench for ground water recharge which can contribute to subsequent downstream base flow. The higher BFI (0.53) and the lower flashiness index (0.14) were also observed in sub-WS1 in 2014. The daily result showed that a significant amount of discharge had occurred during rain events for sub-WS2. On the contrary, more or less uniform discharge with minimal fluctuation was observed for sub-WS1 (Fig. 9a). WS2 was more efficient in reducing surface runoff in 2016 and 2017, although, there was no significant difference between the two sub-watersheds (Table 4; Fig. 9c, d). An 8 and 2% reduction in discharge was observed in WS2 with younger SWC measures in comparison with WS1 with relatively older SWC measures, in 2016 and 2017, respectively. The WH efficiency reduction observed at the plot level is also reflected at the sub-watershed scale.
**Highly significant (P < 0.01); *significant (P < 0.05) and NS: no significant difference.
The suspended sediment yields (SSYs) of the sub-watersheds with (WS1) and without (WS2) SWC measures were significantly different (P < 0.05) at about 1.21 and 4.72 ton ha−1, respectively in 2014 (Fig. 10a; Table 4). The SWC measures have trapped a considerable amount of sediment inside the trench in WS1.
WS2 was more efficient in reducing sediment in all the three years, although, the SSY was not significantly different in 2015, 2016 and 2017 (Table 4; Fig. 10b–d). In the fourth year (2017), the SSY was 3.70 and 3.03 tons per hectare of land from WS1 and WS2, respectively. A 18% reduction in SSY was observed due to the younger (3 years old) SWC measures in WS2 in comparison with the older SWC one (5 years old) in WS1. The volume of the trench is reducing over the years due to siltation and sedimentation. As a result the efficiency of the structure (SWC) reduces as the age increases. Although, the regular maintenance of the structure is important for sustainability, it is rarely happening in the area. The statistical analysis also showed that in terms of SSY, there were no significant differences between the one, two, three and four year old SWC measures in both sub-watersheds that were observed in the second and third years of study (Table 4; Fig. 10b, c).
Just like the plot level observation, as the number of years since SWC measures were in place increased, their effectiveness declined (Fig. 11). In the first year (2014), 80% more discharge retention and 291% more sediment yield reduction were realized due to SWC interventions at the sub-watershed level. In 2015, the older structure in WS1 was only 8% more efficient than the newer structure. However, the older structure was 8 and 2% less efficient in discharge retention compared to the relatively newer structures in years 2016 and 2017, respectively. In terms of sediment reduction, SWC in sub-WS1 was 12, 17 and 18% less effective than the sub-WS2 in years 2015, 2016 and 2017, respectively. As the age of SWC increases the trap efficiency of the trench reduced due to the lack of regular yearly maintenance.
Soil loss estimates at different scales
Runoff and soil loss analyses were done at both plot and landscape scales. Table 5 shows the soil loss values at the plot level extrapolated proportionally to a watershed scale for WS1 and WS2 in 2014. Although, the experimental plots were located in WS1, the control (cropland without SWC) was used for extrapolation in WS2. Sediment yield measured at the outlet of the sub-watersheds with SWC (WS1) is 1.21 ton ha−1 while the calculated sub-watershed soil loss based on the plot values is 2.17 ton ha−1, which is an over estimate by 79% in 2014. On the contrary, it is underestimated by 19% for sub-watershed without SWC (WS2) in 2014. In the period 2015–2017, the annual variation was significantly high (P < 0.01) and the calculated mean (based on plot data) was an underestimate for sub-watershed WS1 and overestimate for WS2 (Fig. 12).
The study shows that only 56% of the soil eroded at the plot level was lost from the conserved sub-watershed (WS1) due to the fact that most of the sediment had been trapped within the sub-watershed in 2014. The newly applied SWC practices in sub-watershed WS2 was on average 25% more efficient in reducing the soil loss than the old SWC in WS1 for the period 2015–2017 (Fig. 12). In this study, it was also observed that flashiness index negatively correlated with the SSY.
This study reinforced the fact that extrapolating plot data to the sub-watershed scale is problematic and does not give good estimation (Fig. 12 and Table 5).
Discussion
Runoff and soil loss at the plot level
The grazing land runoff amount was 24% higher than that of unmanaged cropland (control). This is possibly because the soil was compacted through livestock trampling, which can reduce infiltration and increase surface runoff. This is in general agreement with another study which showed a lower infiltration rate on grazing land without manure application (Taddesse et al., Reference Taddesse, Peden, Abiye and Wagnew2003). Crop land with SWC measures were averagely reduced runoff by 26% in comparison with unmanaged crop land. Other studies reported mean seasonal runoff reduction of 32% on level bunds, with spatial variability ranging from 27% in Andit Tid (North Shoa Zone, Ethiopia) to 39% in Maybar (Wello, Ethiopia) (Hurni, Reference Hurni2000a, Reference Hurni2000b). It is also observed that trench WH efficiency reduced over years due to the lack of maintenance. The well-established grass cover underneath the woodlot could have contributed to retarding surface flow and encouraging infiltration. Other studies also showed that younger (4 years old) eucalyptus can reduce runoff twice than that of older trees (Vertessy et al., Reference Vertessy, Hatton, Benyon and Dawes1996).
The mean soil loss (3.7 ton ha−1) of the grazing land is 51% lower in comparison with unmanaged crop land. This underlines the role of grasses in reducing soil erosion. This is contrary to observations by Tamene and Vlek (Reference Tamene and Vlek2007) where grazing areas showed a higher rate of soil erosion and gully formation. This could be due to differences in management between communal and private grazing lands where protection and management may not be at a more intense level in the former. It was also observed that terraces along with trenches reduced soil loss from cultivated plots by 37% in comparison with unmanaged crop land. A similar study in northern Ethiopia showed 68% annual reduction in soil loss from areas conserved with stone bunds coupled with trenches (Gebremichael et al., Reference Gebremichael, Nyssen, Poesen, Deckers, Haile, Govers and Moeyersons2005). It has also been reported that terraces and bunds reduced soil loss by 61% at Myleba (Tigray), 63% at HendeLafto (Harerghie), 63% at Maybar (Wello), 78% at Andit Tid (Shewa), 59% at Anjeni (Gojam), 58% at Gununo (Gamogofa), 89% at Dizi (Illubabor), 47% at Galena (Shewa) with an average of 65% (Hurni, Reference Hurni2000a, Reference Hurni2000b; Haregeweyn et al., Reference Haregeweyn, Berhe, Tsunekawa, Tsubo and Meshesha2012). Woodlots have shown very low soil loss (71% lower than that of unmanaged cropland) possibly because of the frictional resistance of dense grass cover underneath the trees (FAO, 2009).
Discharge and sediment yield at the watershed level
The study showed that the implementation of SWC measures at the sub-watershed level reduced discharge by 44%. Higher BFI and lower flashiness index were also observed. Other studies on the effectiveness of integrated SWC measures at the sub-watershed scale also revealed a notable impact of SWC measures on runoff reduction; 18% at Enabered in Tigray region (Haregeweyn et al., Reference Haregeweyn, Berhe, Tsunekawa, Tsubo and Meshesha2012), 88% at May Zeg-Zeg in Tigray region (Nyssen et al., Reference Nyssen, Clymans, Poesen, Vandecasteele, Haregeweyn, Naudts, Moeyersons, Haile and Deckers2009) and 39% at Gununo in southern Ethiopia (Mitiku et al., Reference Mitiku, Herweg and Stillhardt2006).
The sub-watershed without SWC practices showed about threefold more sediment yield compared to that of with SWC measures. There might be a possibility of sediment re-deposition and thus sediment yield reduction (Trimble, Reference Trimble1983; Walling, Reference Walling1983; Vente et al., Reference Vente, Poesen, Arabkhedri and Verstraeten2007). This demonstrates that SWC options can play a significant role in checking soil erosion and retaining sediment at the sub-watershed scale. A study by Nyssen et al. (Reference Nyssen, Clymans, Poesen, Vandecasteele, Haregeweyn, Naudts, Moeyersons, Haile and Deckers2009) reported sediment yields reduction (78%) due to SWC intervention in northern Ethiopia (May Zeg-Zeg watershed). Another study also reported a 76% sediment yield reduction at Enabered (Tigray) (Haregeweyn et al., Reference Haregeweyn, Berhe, Tsunekawa, Tsubo and Meshesha2012) due to SWC intervention at the watershed scale. There was also a notable impact of SWC measures on sediment yield reduction (86%) at Gununo catchment in southern Ethiopia (Mitiku et al., Reference Mitiku, Herweg and Stillhardt2006).
Soil loss estimates at different scales
Extrapolating plot level results to watershed was overestimated by 79% for managed (WS1) and underestimated by 19% for unmanaged (WS2) sub-watersheds in 2014. Other studies reported similar overestimation of erosion results due to extrapolation (Loughran, Reference Loughran1989; Evans, Reference Evans1995). It is also reported that extrapolating plot level results to the watershed level and beyond can bring misleading results (Pimentel et al., Reference Pimentel, Harvey, Resosudarmo, Sinclair and Kurz1995; Trimble, Reference Trimble1999; Cammeraat, Reference Cammeraat2002; Leys et al., Reference Leys, Govers, Gillijns, Berckmoes and Takken2010). Even, extrapolating small watershed results to a large region have proved controversial (Pimentel et al., Reference Pimentel, Harvey, Resosudarmo, Sinclair and Kurz1995; Trimble, Reference Trimble1999). Soil loss data obtained at the plot scale are difficult to extrapolate at the catchment level, because the heterogeneity of a catchment is always higher than that of a plot (Stroosnijder, Reference Stroosnijder2005). Moreover, the delivery, transport and storage of sediment are highly scale dependent and controlled by hydrological and geomorphologic processes (Walling, Reference Walling1983; Cammeraat, Reference Cammeraat2002; de Vente and Poesen, Reference De Vente and Poesen2005).
However, soil erosion should be assessed and described at different scales for better understanding (Stroosnijder, Reference Stroosnijder2005). A study on soil loss at different scales provides different benefits for different stakeholders. A plot level study (on-site impact) gives an idea of what is happening within the farm and gives the fertility dynamics of the farm and fertilizer use efficiency. Plot level studies are useful to farmers and practitioners. On the other hand, a sub-watershed level study (off-site impact) gives the overall interaction of the erosion process and gives the net runoff and sediment yield. At the sub-watershed level, the regional managers and policy makers are much more interested.
This study reinforced the fact that extrapolating plot data to the sub-watershed scale is problematic and does not give good estimation. The plot data did not reflect the overall interaction of the erosion process with in the sub-watershed. Therefore, care should be taken while extrapolating plot data because it could be either by far greater, or smaller than the net soil erosion.
Conclusion and recommendations
The study showed significant differences at both plot and sub-watershed levels in runoff and soil loss between ‘treated’ and ‘non-treated’ areas. Although the efficiency reduced over years, in areas where there were terraces coupled with trenches, there was reduction of runoff and soil loss. The runoff retained within the trenches is useful because it can contribute to increased soil moisture in the landscape. There is also more water retained within the watershed during rainy season as the SWC practices significantly improved water retention capacity of the sub-watershed. Regular trench maintenance and cascading WH practices can also be implemented across the landscape to further improve and sustain the water retention capacity as well as reduce downslope erosion. To sustain the productivity of the sub-watersheds, there should be integrated SWC with purposeful regular maintenance of structures. Further studies on the costs and benefits of the SWC interventions are needed to establish their adoption and scalability.
Acknowledgements
We are very grateful to the American people delivered through the United States Agency for International Development (USAID) as part of the US Government's Feed the Future Initiative for funding the research. We would also thank for those directly and indirectly supported the research. This research is supported by the CGIAR Research Program on Water, Land and Ecosystems (WLE), Ethiopian Institute of Agricultural Research (EIAR) and Ethiopian Institute of Water Resources (EIWR) under Addis Ababa University. We thank various organizations, communities and individuals who contributed to the research in different forms. Special appreciation goes to Mr Temesgen Alene Africa RISING Debrebirhan site coordinator, Mr Bedlu Desta and Gudo Beret Kebele farmers for facilitation of experimental setup and data collection. We are also thankful to Debrebirhan Research Center who helped analyze the soil and water samples.
Financial support
This research was undertaken with support from Africa RISING, a program financed by the United States Agency for International Development (USAID) as part of the United States Government’s Feed the Future Initiative. The content is solely the responsibility of the author/s and does not necessarily represent the official views of USAID or the U.S. Government or that of the Africa RISING program. Africa RISING is aligned with research programs of the CGIAR. This research is also supported by the CGIAR Research Program on Water, Land and Ecosystems (WLE), Ethiopian Institute of Agricultural Research (EIAR) and Ethiopian Institute of Water Resources (EIWR) under Addis Ababa University.