Evaluation of land surface ecosystems and managed systems such as those in agriculture during the growing season
Received: 27-Jul-2022 / Editor assigned: 29-Jul-2022 / PreQC No. jescc-22-72247 (PQ) / Reviewed: 12-Aug-2022 / QC No. jescc-22-72247 / Revised: 16-Aug-2022 / Manuscript No. jescc-22-72247 (R) / Accepted Date: 16-Aug-2022 / Published Date: 23-Aug-2022 DOI: 10.4172/2157-7617.1000635
Abstract
The evaluation were made on four treatments physical SWC structures; micro basin, eyebrow basin, micro-trench and traditional pit. The treatments are replicated three times. Soil samples before and after the trial, soil moisture conservation and test tree data were collected for analysis. Except pH and soil texture some soil properties like; TN, P, OM, OC showed an improvement due to the SWC structures implementation. In the first year of trial there was no significant difference was observed soil moisture, plant height and collar diameter. In the second year of the trial highly significant variation at (p<0.05) was observed in soil moisture conservation percent. Micro-trench conserved the higher percent of moisture than other structures. In the third year only plant height show significant difference, but the others were not statistically significant. The result depicts that implementation of physical SWC structures are very important to conserve soil moisture at dry areas. Therefore, all stake holders should practice construction physical structure integrated with tree for land rehabilitation and alleviate soil moisture stress.
Keywords
Soil moisture stress; Land degradation; Soil moisture conservation; SWC structures
Introduction
Land degradation process occurs slowly, causing long lasting impacts on rural population who become increasing vulnerable [1,2]. Estimates showed that about 85% of land attenuation globally is because of soil erosion reducing crop productivity by about 17%, affecting the soil fertility initially and in the long term resulting in land desertification [3].
Land degradation can occur due to intensive crop cultivation, deforestation, excessive tillage for land preparation, overstocking and overgrazing both pasture and cropland, shifting cultivation without adequate fallow periods, absence of soil conservation practices and overuse of certain cattle routes and watering points [4]. The immediate impact of land degradation has reduced crop yield and productivity [5].
Soil moisture is one of the determining factors of the stress or health on land surface ecosystems and managed systems such as those in agriculture. Plant growth and crop yield are closely related to the amount of moisture available during the growing season.
The variation in soil water content is influenced by a number of factors; such as soil properties (soil texture, structure, organic matter, depth, density and salinity), climate (precipitation, solar radiation, temperature, etc.), topography and land cover [6]. These influencing parameters can regulate permeability, infiltration, water holding capacity and moisture loss rates. Currently, the practices like; crop type choice, agronomic practices, input fertilizers application and irrigation management practices are expected to vary the dynamics of soil moisture [7] due to their impacts on the physical and bio-geochemical interactions within ecosystems [8].
To alleviate moisture stress and land degradation problem, soil and water conservation practices were initiated in Ethiopia during the 1970s and 1980s [9]. The basic need of the initiatives was to minimize soil erosion risk, restore soil fertility status, reclaim degraded land, and increase agricultural productivity (Mekuria et al., 2007).
Wera district is characterized as moisture stressed dry land area, due to its high temperature, erratic rainfall pattern and low soil water holding capacity. The is also characterized by intensive and frequent tillage practice, overgrazing, deforestation, limited number of enclosures and less SWC (soil and water conservation) practice that exacerbate soil moisture deficiency and cause land degradation (Wera, district, 2020).
Many research findings by different authors argue that SWC measures are effective for soil management [10]. Some of them argue that SWC contributes for runoff reduction and sediment deposit [11] and increased soil moisture conservation [12,13]. So, this study was done to with the objectives; to compare and select best physical moisture conservation technique, to show the effect of different conservation structures on moisture conservation and tree growth.
Materials and Methods
Study area description
The experiment was laid out at Wera district located in Halaba Zone. The district is located in 86 km far away from Hawassa Town, Southern nation’s nationalities and peoples region (SNNPR) capital and 310 Km far from Addis Ababa, Capital of Ethiopia. Geographically the district is located in 37 0 58’0’’E to 38 0 13’30’’E and 7 0 14’30’’N to 7 0 26’30’’N. The elevation ranges from 1700 to 2150 m above sea level. The income for majority of the people in the area comes from agricultural practice. The major growing crops on the area includes pepper, teff, sorghum, wheat, maize and common bean.
Treatments and experimental design
Treatments the treatments evaluated were
1. Micro basins with tree planting holes.
2. Eye-brow basins with tree planting holes.
3. Micro trenches with tree planting holes.
4. Only traditional tree planting without any supportive structure. Gravillea robusta seedling was planted behind each structure to evaluate impacts of structures on tree growth.
Experimental design
The treatments were arranged in RCBD (completely randomized block design) with four replications. Each treatment had three structures arranged in staggered manner. The diameters and foundation of the structures excluding traditional pit were 2m and 20cm respectively. The width and depth for traditional planting pit were 40cm and 50cm respectively. The trenches had length of 2m, width of 0.5 and depth of 0.5m. The inter space between blocks were 1.5m.
Data collection and analysis
Data collection
Sixteen (16) soil samples were collected before and after the trial to evaluate the impact of the moisture conservation structures on soil physico-chemical properties. The soil moisture content data were collected within each tree month’s interval. The tree data; like tree height, above ground biomass, collar diameter of seedling, seedling survival and performance were collected with four months interval. The structures construction work and soil samples collection were done during dry season. But, tree planting were undertaken during wet season. In other way, soil moisture data were collected after rainfall event within three months interval.
Statistical data analysis
The collected soil sample before and after the trial were analyzed at Hawassa Agricultural Research Center Soil laboratory. Soil moisture was determined by removing soil moisture by oven-drying a soil sample until the weight remains constant. The soil moisture content (%) was calculated from sample weight measured before and after oven drying for each sample. This was done to know and compare soil moisture conservation between treatments. The tree height, above ground biomass, collar diameter of seedling, seedling survival and performance were analyzed to evaluate the performance and growth status between the treatments. Finally, all data were analyzed using R-Software package. LSD (least significant difference) was used to depict data mean difference between treatments and the statistical analysis process was employed following standard procedures applicable for RCBD (Randomized complete block design).
Result and Discussion
Soil properties of soil before and after the experiment
The average pH, OC (%), OM (%), TN (%), P (ppm) of the study area before the trial was; 7.47, 1.42, 2.97, 0.13 and 16.43 respectively as shown on Table 1. The average composition of clay, silt and sand were 17.33%, 24% and 58.67% respectively. According to USG soil textural class classification, the experimental site was dominantly categorized under Sandy loam textural class.
Samples | Soil texture | ||||||||
---|---|---|---|---|---|---|---|---|---|
pH(1:2.5) in H2O | OC (%) | OM (%) | TN (%) | P (ppm) | % clay | % silt | % sand | Textural class | |
Sample one | 7.51 | 1.05 | 3.5 | 0.09 | 17.0 | 14 | 28 | 58 | Sandy loam |
Sample two | 7.55 | 1.58 | 3.3 | 0.14 | 15.9 | 10 | 32 | 58 | Sandy loam |
Sample three | 7.35 | 1.63 | 2.1 | 0.15 | 16.12 | 28 | 12 | 60 | Sandy clay loam |
Average | 7.47 | 1.42 | 2.97 | 0.13 | 16.34 | 17.33 | 24.0 | 58.67 |
According to the Table 2 shown below the average soil property values of OC, OM, TN and P after the trial were 2.0 %, 3.5 %, 0.21% and 23.12 ppm respectively. This result conveys that physical soil and water conservation structures poses an impact for the improvement of above listed soil properties like; organic carbon, organic matter, total nitrogen and phosphorus contents of the soil compared with the analysis result before the structures establishment. But, the percent composition of texture and pH value cannot show any change due to the structures construction. This is because the impact of physical soil and water conservation structures requires long time to show improvement on soil texture and pH value.
Samples | Soil texture | ||||||||
---|---|---|---|---|---|---|---|---|---|
pH(1:2.5) in H2O | OC (%) | OM (%) | TN (%) | P(ppm) | % clay | % silt | % sand | Textural class | |
Sample one | 7.51 | 2.25 | 3.9 | 0.2 | 21.25 | 14 | 28 | 58 | Sandy loam |
Sample two | 7.55 | 2.25 | 3.9 | 0.25 | 24.65 | 10 | 32 | 58 | Sandy loam |
Sample three | 7.35 | 1.5 | 2.59 | 0.18 | 23.45 | 28 | 12 | 60 | Sandy clay loam |
Average | 7.47 | 2.0 | 3.5 | 0.21 | 23.12 | 17.33 | 24.0 | 58.67 |
Conclusion and Recommendation
Construction of small physical SWC (soil and water conservation) structures is an important option to improve soil moisture and better tree growth, through harvesting runoff water. This study showed that the four evaluated physical soil and water conservation structures were important for soil moisture conservation, tree growth and degraded area rehabilitation as a whole. In addition to improving soil moisture the measures had a positive impact on improving other soil physic-chemical properties. The highest percent of soil moisture was conserved by micro-trench, followed by micro basin and eyebrow basin. But, the lowest percent was observed on traditional pit. In this study the researchers recommend that construction of physical SWC structures are the best options to rehabilitate degraded land and improve soil moisture content of soils at dry and moisture stressed areas. So, communities and stake holders of the study area should practice construction of those physical structures to alleviate moisture stress problem of the area.
References
- Adimassu Z, Mekonnen K, Yirga C, Kessler A (2014) Effect of soil bunds on run-off, soil and nutrient losses, and crop yield in the central highlands of Ethiopia. Land Degrad Develop 554-564.
- Dagnew DC, Guzman CD, Zegeye AD (2015) Impact of conservation practices on runoff and soil loss in the sub-humid Ethiopian highlands: the Debre Mawi watershed. J Hydrol Hydromech 210-219.
- Fu B, Wang J, Chen L (2003) The effects of land use on soil moisture variation in the Danangou catchment of the Loess Plateau, China. Catena 197-213.
- Haregeweyn N, Tsunekawa A, Nyssen J (2015) Soil erosion and conservation in Ethiopia: a review. Prog Phys Geogr 39(6):750-774.
- Mekuria WA (2017) Assessing the effectiveness of land resource management practices on erosion and vegetative cover using GIS and remote sensing techniques in Melaka watershed, Ethiopia. Environ Syst Res 6:16.
- Mekuria W, Veldkamp E, Haile M (2007) Effectiveness of exclosures to restore degraded soils as a result of overgrazing in Tigray, Ethiopia. J Arid Environ 270-284.
- Muchena FN (2008) Indicators for Sustainable Land Management in Kenya’s Context. GEF Land Degradation Focal Area Indicators, ETC-East Africa. Nairobi Kenya.
- Niyogi D, Kishtawal C, Tripathi S (2010) Observational evidence that agricultural intensification and land use change may be reducing the Indian summer monsoon rainfall. Water Resour Res 46.
- Nyssen J, Clymans W, Descheemaeker K, Poesen J, et al. (2010) Impact of soil and water conservation measures on catchment hydrological response—a case in North Ethiopia. Hydrol Process 1880-1895.
- Rosenzweig C (2008) Attributing physical and biological impacts to anthropogenic climate change. Nature 353-357.
- Shaxson F, Barber R (2003) Optimizing soil Moisture for Plant Production. FAO Soils Bulletin 1-125.
- Shiferaw B, Holden S (2001) Farm-level benefits to investments for mitigating land degradation: Empirical evidence from Ethiopia. Environ Dev Econ 335-358.
- Tefera B (2002) Nature and causes of land degradation in the Oromiya Region: A review. Work Pap 36.
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Indexed at, Google Scholar, Crossref
Citation: Cope A (2022) Evaluation of land surface ecosystems and managed systems such as those in agriculture during the growing season. J Earth Sci Clim Change, 13: 635. DOI: 10.4172/2157-7617.1000635
Copyright: © 2022 Cope A. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Share This Article
Recommended Journals
Open Access Journals
Article Tools
Article Usage
- Total views: 1028
- [From(publication date): 0-2022 - Nov 21, 2024]
- Breakdown by view type
- HTML page views: 849
- PDF downloads: 179