Effects of Land Use Types on Selected Soil Properties in Central Highlands of Ethiopia

Rapid land use changes have been observed in recent years in central Ethiopia. )e shift from natural ecosystem to artificial ecosystem is the main direction of change. )erefore, this study was initiated to assess the effects of land use types on selected soil properties inMeja watershed, central highlands of Ethiopia.)e randomized complete block design, including three adjacent land use types as treatments with three replications and two soil depths (0–15 and 15–30 cm), was applied in this study. )ere were significant differences in some soil properties among the three land use types. Lower soil pH and electric conductivity were observed in cultivated land soils than Eucalyptus woodlots soils. )is has indicated the worsening soil conditions due to the shift from Eucalyptus woodlots to cultivated land. Less decomposition rate of the Eucalyptus leaves and debris collection for fuel could result in lowest soil organic carbon at the upper layer of Eucalyptus woodlot soils. However, the highest soil organic carbon at the lower layer was observed in Eucalyptus woodlot soils. )e presence of highest soil potassium, cation exchange capacity, and exchangeable potassium in cultivated land soil was related to application of artificial fertilizers. Grassland soils have highest exchangeable sodium at the lower layer while highest soil carbon and sum cations at the upper layer, which can be related to the grass root biomass return and less surface runoff on grassland. )ere was the highest exchangeable sodium percentage on Eucalyptus woodlot soils at the upper layer; it can be due to the less surface nutrient movement and growth characteristics of the tree. )e soils in cultivated land was shifted to more acidic and less electric conductivity.)is shift can lead to soil quality deterioration that affects the productivity of the soils in the future.Nutrient leaching, application of artificial fertilizer, soil erosion, and continuous farming have affected the soil properties in cultivated land. )e presence of highest exchangeable sodium percentage and lowest sum of cations at the upper layer of soil in Eucalyptus woodlot should be noted for management and decision makers. )e previous negative speculations on Eucalyptus woodlots which can be related with the soil texture, soil moisture, bulk density, total nitrogen, exchangeable magnesium, calcium, and available sulfur should be avoided because there were no significant differences observed among the three land use types in the study area. )e study recommends further studies on the effects of Eucalyptus on soil properties by comparing among different ages and species of Eucalyptus. Finally, planting of Eucalyptus on central highlands of Ethiopia should be supported by land use management decision.


Introduction
Land use, which is human driven activities on land, is one of the major characteristics of land [1]. Land use type could determine the total production from the land and the status of the producer. e land use type could be determined by the need of producer, the environmental condition (soil, climate, rainfall, altitude, etc.), socioeconomic status (land lord, tiller, or peasant), and political (tenure, land policy, and ownership) and cultural manners (beliefs, norms, and bylaws on the land) of the given area [2,3]. e aforementioned factors could influence the owner to decide the type of land use on their land. Among the factors that could influence the user's preference is the soil condition of the field. e soil condition can be identified by analyzing the soil properties and comparing with the standards.
Rapid population growth is believed to influence the type of land use and the rate of expansion of specific land use type [3,4]. is could affect the soil properties of a given land when it is changed from natural to artificial land use system or vice versa. e intensified agricultural land expansion on the expense of the loss natural environment could also lead to severe land degradation. In the central highlands of Ethiopia, there is significant land use change from natural ecosystem to artificial ecosystem within five decades [5][6][7]. Recently, Eucalyptus woodlot has joined the artificial ecosystem with rapidly expanding on grassland, woodland, riverside wetlands, cultivated land, and degraded land in the central highlands of Ethiopia [6][7][8][9][10].
Eucalyptus, as economic and social problem relieving tree species, is expanding in the central highlands of Ethiopia [6,7,9,11]. e species was planted in the highlands of Ethiopia in the end of 19 th century as the source of fuel wood for the settlers of the newly established capital city of Ethiopia [12]. In some places, it has expanded to 18% within 30 years with farmers' demand [9,10,13]. Eucalyptus has benefited farmers with filling household fuelwood demand, improving income, and providing social and cultural value and environmental benefits. [14][15][16]. However, many still did not accept its planting by raising concerns on its impacts such as water consumption, nutrient competitiveness, soil erosion, and land degradation [10,[17][18][19].
Various studies have been done to quantify the effect of land use types on soil properties in Ethiopia [3,9,11,[20][21][22]. Some have compared the natural forest and woodland with the artificial land uses [3,20]. Furthermore, some studies have compared the effects of different cultivated land along ages on soil properties [20,21]. e effects of plantation forest and natural forest on soil properties were also studied [23]. Some have compared the effects of conserved areas, cultivated land, plantation, and natural forest on soil properties. Zerfu et al., [24] have compared the effect of Eucalyptus on soil properties before and after harvesting. Chanie et al. [10] have studied the variation of soil properties along different distances from Eucalyptus tree. Some have compared the effect of Eucalyptus along ages [25].
However, the effects of land use types, comparing the effects of natural land use (grassland) and the artificial land use (cultivated land and Eucalyptus woodlots) on soil, were less studied in the central highlands of Ethiopia and elsewhere. us, the farmers' Eucalyptus planting trend is increasing with the expansion of natural and cultivated land. Currently, due to its social and economic benefits, it is difficult to hinder farmers to not plant Eucalyptus on their land [13,[26][27][28]. However, it is beneficial to understand the effects of the land use types on soil properties to support generating land use management options. erefore, the objective of this study was to assess the effects of land use types on selected soil properties in the central highlands of Ethiopia.

Description of the Study Area.
e study was conducted at Meja watershed in West Shewa zone, Central Ethiopia. It is found 110 km west of the capital, Addis Ababa ( Figure 1). e watershed is found in two districts: Jeldu and Dendi. e watershed is located within 9°07′ to 9°17′N and 38°02′ to 38°07′E, with an altitude ranging from 2400 to 3200 m above mean sea level. e watershed is also found in southern upper Blue Nile basin. e total area of the watershed is 10107 ha. e mean annual temperature ranges from 17°C to 25°C. e rainfall is bimodal with the short rainy season from February to May and long rainy season from June to September. e mean annual rainfall is 1400 mm though there is variation of rainfall amount along the altitude. e agroecology of the site is grouped locally under Dega and Wurch (cool highlands with sufficient rainfall, with some extreme cool weather condition). Eucalyptus globulus is the main exotic tree planted in the watershed. Very few places are covered by small patches of natural forest; otherwise, bushlands are dominated the riversides, ridges, and steep slope. Scattered trees are still visible on cultivated land and grassland. Acacia abyssinica, Hagenia abyssinica, and Buddleja polystachya are some of the indigenous trees and shrubs in the area. Eucalyptus globulus woodlots are abundant in the watershed replacing bush land, cultivated land, and marginal grazing lands. e major river in the watershed is the Meja River, which is one of the tributaries of the Nile River. e Meja River originates at high altitude just near Galessa village in the Dendi district. e head waters are in a flat wide valley, which is a wetland heavily utilized for livestock grazing in Galessa. Many tributaries drain into the Meja river from both the east and west sides of the watershed. e river flows throughout the year with high flow at July, August, and September. e southern upper Blue Nile, which includes the study area, is dominated by Vertisol. e soil in the study area is classified under Pellic Vertisol. e textural class of the soil at upper section of the watershed is dominated by clay loam and clay soil. e lower section of the watershed has loam soil. e soil textural class of this study area is clay soil. e soil pH value ranges from 4.9 to 5.9, which is moderately acidic soil. Soil erosion by water is common threat for sustainability of cultivated land in the study area. e land use of the area is predominantly mixed croplivestock-tree production system. Major crops grown in the area are barley (Hordeum vulgare), wheat (Triticum vulgare), potato (Solanum tuberosum), and maize (Zea mays). Livestock production (cattle, sheep, and horses) for various purposes is also practiced. Eucalyptus plantations and woodlots are produced mainly for sale in the study area. e major cash sources for farmers in the watershed are from sale of potato and Eucalyptus. e estimated population of the study area is 42000. e estimated annual population growth is 2.5%. e average number of people per household is 6 people. Landholding size per household ranges from 0 to 4 hectares. Half of the population are youth in the study area.. Majority of the population live in the rural area.

Experimental Design.
e comparison of the effects different land use types on selected soil properties was studied by collecting soil samples from three different land use types. e experimental design for this study was randomized complete block design (RCBD) in which the land use types were considered as treatments.
ree land use types, namely, Eucalyptus woodlot, cultivated land, and grassland, were selected for comparison as treatments. Grassland was considered as control treatment in the study. e three adjacent land use types, which shares similar biophysical condition such as soil and slope, are grouped in a block. . Four replications of each land use type were used in the four different sites forming a total of twelve sample plots.

Soil Sampling.
e soil samples were collected only one time from three land use types at four different sites in Meja watershed, Jeldu district. From each site, three soil sampling locations were systematically selected with having three adjacent land use types. e three land use types within each site have similar topography and other conditions, which made the local soil forming factors relatively uniform (Table 1). e soil samples were collected at twelve points with four replications of land use types in the study area. Plot with square dimension (20 m × 20 m) was laid at the middle of each land use types. e pits were dug at four corners and center of the plots using auger, and two soil samples were taken from the pit at two soil depths (0-15 cm and 15-30 cm).

Soil Laboratory Analysis.
e collected soil samples were bulked to one composite sample with similar depth at each plot of the land use types. Two composite soil samples were collected from each land use types. In total, six composite samples were collected from each site and twenty-four composite samples were collected from the study site. e composited sample that weighs one kilogram was taken, properly labelled, and packed with plastic bags prior to transporting it to laboratory.
For bulk density and moisture analysis, two soil samples at depths 0-10 cm and 20-30 cm were taken using core sampler (height � 10 cm and diameter � 7.2 cm) and their weight was also measured directly at the field. e soil samples were collected in a labelled polyethylene bag, registered, and transported to soil laboratory of water works design and supervision enterprise at Addis Ababa, Ethiopia. All soil samples were air-dried at room temperature and sieved (mesh size 2 mm).
Soil organic carbon (OC) was determined using the Walkley and Black method as stated in Nelson and Sommers [29]. Total nitrogen (TN) was estimated by the Kjeldhal method as used by Bremner [30]. e soil texture was determined using the hydrometer method [31]. Soil pH was determined by a pH meter. Electrical conductivity of the soil was determined on the saturated paste. Bulk density was determined by dividing the oven dry mass (105°C) by the volume of the core. Exchangeable cations (Ca 2+ , K + , Mg 2+ , and Na + ) were determined using 1 M ammonium acetate at pH of 7.0 [32]. Cation exchange capacity (CEC) was calculated by summing up the charge concentrations of Ca 2+ , K + , Mg 2+ , and Na + . Available potassium (K) was determined by flame photometer with dissolved 0.3728 g of dried KCl in one litre of extracting solution [33]. Exchangeable sodium percentage (ESP) was computed by dividing exchangeable sodium by soil CEC and multiplying by 100. Available sulfur of the soil was extracted by the Mehlich-3 multinutrient extraction method [34]. Available phosphorus was determined by the Bray 2 method [35].

Statistical Analysis.
e soil laboratory results were analyzed with Statistical Package for Social Sciences (SPSS) Applied and Environmental Soil Science software version 20 [36]. e data were tested for normality prior to analysis. Analysis of variance (ANOVA) test was run using the multivariate general linear model to test the effects of land use type on dependent variables. Significant means were separated using least significant difference (LSD) at 5% significance level for pair wise comparison of means to assess the mean differences of the land uses and depth levels depending on soil chemical properties.

Soil pH, EC, Texture, Moisture, and Bulk
Density. e pH (H 2 O) of the soils in the three land use types is grouped under strongly acidic (5.1-5.5) class. ere was a significant difference (p ≤ 0.05) in soil pH among land use types in both layers (Table 2). e pH of soils in grassland > Eucalyptus woodlot > cultivated land in upper layer and the pH of grassland > cultivated land > Eucalyptus woodlot in the lower layer.
e soil EC of the study site ranges from 0.75-0.92 mS/cm; this could indicate that it is grouped into the soil salinity class of nonsaline soil. e EC of the soils could depend on the amount of moisture present in the soil.
ere was a significant difference (p ≤ 0.05) in soil EC among land use types in the upper layer (Table 2). e grassland soils had the highest EC value in the upper layer, while cultivated land soils had the lowest EC value in the upper layer as compared to others.
ere was no significant difference (p ≤ 0.05) in soil moisture, texture, and bulk density among land use types in both layers (Table 2). e soils of the study area are grouped under clay class according to USDA classification. ere was highest soil moisture content in grassland at the upper layer, while the highest soil moisture content was observed in eucalyptus woodlot soil in the lower layer. Cultivated land had the highest bulk density value in both layers, while grassland had the lowest bulk density in both layers as compared to others.

Soil Organic Carbon, Total Nitrogen, Potassium, and Available S and P.
e results of soil organic C, total N, potassium, and available S and P are listed in Table 3. ere was a significant difference (p ≤ 0.05) in soil organic carbon content among land use types in the upper layer (Table 3). e soil organic carbon content of grassland > cultivated land > Eucalyptus woodlot in the upper layer. e upper surface of the soils in grassland contains higher soil organic carbon than in the lower surface.
ere was higher soil organic carbon deposition in the Eucalyptus woodlot soils at the lower layer. However, there was less soil organic carbon on Eucalyptus woodlots in the upper surface as compared to the other two land use types.
Soil potassium is classified as macronutrient that is an essential nutrient for plant growth. ere was a significant difference (p ≤ 0.05) in soil potassium content among land use types in the lower layer (Table 3). Cultivated land soils had highest potassium content in the lower layer, while grassland soils had lowest potassium content in the lower layer. However, there was no significant difference in soil potassium content among land use types in the upper layer. e soil CEC of the study site (21.1-31.6 meq/100 g) is rated as high based on its value [37]. ere was a significant difference (p ≤ 0.05) in soil CEC among Eucalyptus woodlot, cultivated land, and grassland in the upper layer (Table 3). e CEC of cultivated land > grassland > Eucalyptus woodlot in the upper layer. ere was no significant difference (p ≤ 0.05) in total nitrogen, available S, and available P among land use types in both layers (Table 3). Grassland had highest total nitrogen content in both layers, while Eucalyptus woodlot soils had total nitrogen content in both layers. Cultivated land and eucalyptus had the highest and lowest available S, respectively, in both layers. Eucalyptus woodlots had highest available P, while grassland had the lowest available P in both layers.

Soil Exchangeable Cations (Na, K, Ca, and MG), Sum of Cations, and ESP.
ere was a significant difference (p ≤ 0.05) in soil exchangeable sodium among land use types in the lower layer. e exchangeable Na + soils of grassland > Eucalyptus woodlot > cultivated land in the lower layer (Table 4). e exchangeable potassium level of the soils in the study area could be grouped under low category (0.2-0.4 cmol (+)/kg of K + ).
ere was a significant difference (p ≤ 0.05) in soil exchangeable potassium among land use types in the lower layer (Table 4). Cultivated land soils had the highest soil exchangeable potassium, while grassland soils had lowest soil exchangeable potassium in the upper layer. e sum of cations is directly related with CEC because it is one part of measurement to determine CEC. As it is listed above in Table 3, the CEC of the three land use types was significantly different among each other. e sum of cations value could be varied due to the presence of other cations and soil physical condition. us, there was a significant difference (p ≤ 0.05) in sum of cations of the soils among land use types in the upper layer. Grassland soils had highest sum of cations, while eucalyptus woodlot soils had lowest sum of cations in the upper layer (Table 4). e soil exchangeable sodium percentage (ESP) of the study site ranges from 8.3% to 9.5%. If the ESP of the soil is less than 15%, the soil will not be sodic. In this case, the soil of the study site was not sodic. ere was a significant difference (p ≤ 0.05) in soil ESP among land use types in the upper layer (Table 4). Eucalyptus woodlot soils had highest ESP, while grassland soils had the lowest ESP in the upper layer.
ere was no significant difference (p ≤ 0.05) in soil exchangeable cations calcium and magnesium among land use types in both layers (Table 4). Grassland soils had highest exchangeable calcium, while Eucalyptus woodlot soils had lowest exchangeable calcium in both layers. Grassland soils had highest exchangeable magnesium, while cultivated land soils had lowest exchangeable magnesium in both layers as compared to the others.

Effects of Land Use Types on pH, EC, Texture, Moisture, and Bulk Density.
e soils in cultivated land were more acidic than the other land use types in the upper layer. is can be due to application of ammonium-based fertilizers, erosion, and improper ploughing direction [38]. Differently, the pH of Eucalyptus woodlot soils was lower than that of cultivated land and grassland soils in Ethiopia [3,11,39,40]. e soil pH can influence the solubility and availability of nutrients in the soil. e soil pH can vary within short distance due to nitrification, root activity, and decomposition of organic matter. According to Chemeda et al. [41], the pH of grassland soils was higher than that of the soils in cultivated land and forest land. But, Yimer et al. [42] have found that the pH of cultivated land soils was higher than that of the soils in grassland and forest land. e reason for lower soil pH in the Eucalyptus woodlot can be due to frequent cation uptake and removal of cations around the tree [11]. e soil EC value was related with the soil pH in the upper layer. e EC level can affect the soil texture, CEC, organic matter condition, and subsoil characteristics of the soils. Various studies have found higher EC in grassland soils as compared to the soils in cultivated land and other land use types [43][44][45]. e lower EC value in cultivated land soils can   Applied and Environmental Soil Science 5 be related with the loss of exchangeable base from the soil due to leaching and erosion as a result of continuous farming.

Effects of Land Use Types on Selected Important Soil
Nutrients. In several findings, grassland soils can accumulate higher soil carbon than other land use types except natural forest [3,[45][46][47]. e decomposed humus from grassroots and above-ground biomass in the upper layer of grassland soils could increase the carbon content. e upper surface of the grassland soils contains higher soil carbon than the lower surface. It is due to the presence of easily decomposing materials on the upper surface than other land use types.
In the other case, the reason behind higher soil organic carbon content in the cultivated land than Eucalyptus woodlots was due to fertilizer application and higher leaf decomposition of the cultivated crops. However, there was higher soil organic carbon in Eucalyptus woodlot than the other two land uses in the lower layer. is could be due to slow decomposing rate of Eucalyptus leaves and debris collection for fuel wood that could reduce the accumulation of organic matter under the tree canopy. Similar to this study, grassland soils had higher soil organic carbon than cultivated land in other studies [41,42,45,47]. is is due to the presence of numerous amounts of grass root growth and biomass turnover rate; in addition to this, less erosion and absence of tillage could lead to higher accumulation of soil organic carbon in the grassland soils. On contrary to the above, studies have found higher soil organic carbon in Eucalyptus woodlot soils than grassland and cultivated land soils in the upper layer [3,21,40,48]. In general, the soil organic carbon content for the study site soils ranges from 2.47%-3.78%, which could be grouped under optimum status. e occurrence of higher potassium in the lower layer of cultivated land soils can be related with the application of fertilizers and the leaching of nutrient to the lower layer due to ploughing [21]. Similar findings have observed significantly higher potassium content in the cultivated land soils as compared to other land use types [45]. e soil potassium content of the study site rages from 0.16 to 41 meq/100g, which could be considered as very low for plant growth on the soil. e higher CEC in the upper layer of cultivated land soils can be related with the presence of higher exchangeable sodium and potassium in the soils that can be related to the application of fertilizer. Similarly, other findings have observed higher CEC in the cultivated land soils as compared to other land use types [3]. However, Chemeda et al. [41] and Adugna and Abegaz [22] have found higher CEC in grassland soils than cultivated land soils. CEC can be related with soil carbon, clay content, and pH value of the soil. e lower CEC value in Eucalyptus woodlot soils can be related with the lower soils' pH value (more acidic soil). e other reason can be depletion of exchangeable bases in Eucalyptus and grassland soils. Application of fertilizers, which can initiate the presence of cations on cultivated land, can also affect the CEC of cultivated land soils. e value of CEC in upper layer of cultivated land is smaller than that in the lower layer; this could be resulted due to exchangeable sodium leaching.

Effects of Land Use Types on Exchangeable Cations and ESP.
e result has also indicated the inverse relation of soil exchangeable sodium with soil potassium in the similar layer. is can be also related with the application of fertilizers and nutrient movement to the lower layer. In addition, it can be connected to the crop nutrient uptake for their growth. is result matches with the finding of Seyoum [44] and Feyisa et al. [45] by the higher content of soil exchangeable sodium in grassland soils as compared to the other land use types. Other studies have observed higher soil exchangeable sodium in the lower layer of the cultivated land soils as compared to the upper layer [43,44]. is is due to leaching of exchangeable cations, in this case, sodium. Similarly, on grassland soils, the nutrient loss can be reduced due to lesser surface water movement. So, it was observed the higher soil exchangeable sodium in grassland soils as compared to cultivated land. However, other studies have found higher soil exchangeable sodium in cultivated land soils than grassland soils in both layers [21,43].
e aforementioned result about the soil exchangeable potassium content has shown the direct relationship of the presence of soil potassium and exchangeable potassium under similar land use type soils. e presence of higher exchangeable potassium in cultivated land soils can be related to the type of fertilizers applied on the cultivated land soils. Oppositely, Lemma and Olsen [49] have found significant variation between cultivated land and Eucalyptus woodlot soils. e result has indicated that there was higher soil exchangeable potassium in the Eucalyptus woodlot soils than cultivated land soils [3]. However, other studies have also found higher soil exchangeable potassium in the cultivated land soils as compared to other land use types [20][21][22]. e sum of cations in grassland soils was higher as compared to the other land use types. is is due to less surface water movement in grassland and lesser consumption of these cations by grasses. Other findings have also observed higher sum of cations in the grassland soils as compared to the other land use types [45]. In the other case, the lower sum of cations in the Eucalyptus woodlot soils at upper layer was observed which is due to the root characteristics of the tree. e Eucalyptus tree's deep roots can also influence the downward movement of these cations from the upper layer so that lower value of cations was observed in the upper layer of Eucalyptus woodlot soils. e presence and absence of sodium in the soil can be related to the plant growth characteristics and the nutrient movement in the soil at surface layer. Here, it can be related to surface water movement and fertilizers application. A study has indicated that there was higher ESP in the cultivated land soil than grassland and other land use types [50].

Conclusions
Land use types can affect the soil properties and the presence of essential nutrients in the soils. Central Ethiopia has observed significant change in land use as a result of expansion of cultivated land and Eucalyptus woodlots. e result of this study has shown that there was a significant difference in soil properties due to the effects of land use types in the study area. e soil pH and EC have shown significant difference among the three land uses types in the upper layer. Cultivated land soils have shown lower pH and EC than Eucalyptus woodlot soils in the upper layer. is is due to the application of ammonium base fertilizers, cation loss as a result of leaching, and water erosion due to continuous farming. ere was a significant difference in soil organic carbon among land use types with lowest in Eucalyptus woodlots soils in upper layer. e highest soil organic carbon was observed in lower layer of the Eucalyptus woodlot soils. is could be due to less decomposing rate of Eucalyptus leaves and the collection of debris for fuel wood, which could reduce the accumulation of organic matter in Eucalyptus woodlots. Grassland soils have highest soil organic carbon in the upper layer as a result of higher number of grass root growth and biomass turnover rate. Furthermore, there was a significant difference in soil potassium, CEC, exchangeable sodium, exchangeable potassium, sum of cations, and ESP among land use types.
ere was the highest potassium value in cultivated land soils as compared to others due to leaching of applied fertilizers during soil sampling. Related with this, there were highest CEC and exchangeable potassium in the upper layer of cultivated land soils. is can be related with application of fertilizer. However, exchangeable sodium was highest in grassland soils at lower layer. is can be related with leaching of nutrients from the upper layer. e highest sum of cations was seen in grassland soils at the upper layer.
is can be related with less nutrient loss due to less surface runoff from the field. e highest ESP was observed in Eucalyptus woodlot soil at the upper layer. is is due to the less surface nutrient movement and growth characteristics of the tree. In general, the study has observed important soil properties which were significantly affected due to the effects of land use types. Cultivated land soils were shifted to more acidic and lesser EC content soil, which could lead to less productive soil in the future. Nutrient leaching, application of fertilizers, soil erosion, and continuous farming have affected the soil properties in cultivated land. ese effects should be managed with proper and sustainable farm management practices in order to avoid the degradation of cultivated land soils from the study area. e presence of the highest ESP and lowest sum of cations at the upper layer and lowest pH at the lower layer in Eucalyptus woodlot soils should be noted for management and decision makers.
ere were no significant differences in soil texture, soil moisture, bulk density, total nitrogen, exchangeable magnesium, exchangeable calcium, available sulfur, and available phosphorus among the three land use types. is could avoid the negative rumors on Eucalyptus woodlots, which can be related with the aforementioned soil properties in the study area. e study also recommended further studies on the effects of Eucalyptus on soil properties by comparing among different ages and species of Eucalyptus. Finally, planting of Eucalyptus on central highlands of Ethiopia should be supported by proper land use management decision.

Abbreviations
ANOVA: Analysis of variance CEC: Cation exchange capacity EC: Electrical conductivity ESP: Exchangeable sodium percentage pH: Potential of hydrogen LSD: Least significant difference RCBD: Randomized complete block design SPSS: Statistical Package for Social Sciences USDA: United States Department of Agriculture.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e author declares that there are no conflicts of interest.