What You Have to Know About Soil Classification of Zimbabwe

What you have to know about soil classification of Zimbabwe

Soil taxonomy

Orders

Groups

Family

Series

The concept of catena

Importance of soil classification

Distribution and use of soils in Zimbabwe

Reference

Nyamapfene, K.W., 1985. Distribution and management of some problem soils of Zimbabwe. FAO World Resource Bulletin No 58.

Soils of Zimbabwe

Figure 2.2: Distribution of major soil groups in Zimbabwe (Source: Department of Surveyor General 1979)

The soils of Zimbabwe can be classified into eight groups. These are the regosols, lithosols, vertisols, siallitic, fersialitic, paraferralitic, orthoferralitic and the sodic (Nyamapfene, 1991). The fersialitic soils are the most extensive soils in Zimbabwe. These are mainly formed from granite rocks. The soils are predominant in the middleveld and the central watershed (Figure 2.2). The fertility of the fersialitic soil is moderate hence a wide range of crops can be grown on them under rainfed and irrigated agriculture.

The siallitic which are rated number two in terms of area covered are mainly found in low rainfall areas and hence have a high base status, and clay contents. The soils can however be very shallow (less than 25 cm) and this tends to limit the rooting depth. The other notable limitation of these soils is the aridity of the environments in which they occur.

The lithosols which are rated third in terms of area covered occur in flat areas in the low rainfall areas especially in areas where the rocks are resistant to weathering, hence limited profile development (Nyamapfene, 1991). In the high rainfall areas, they occur in areas where erosion rates are high. These soils are not arable but are used for ranching purposes.

The regosol group is rated fourth in terms of area covered. The soils are mainly found in the Nyamandlovu area north of Bulawayo and also in the Gonarezhou area. There are also some sporadic occurrence in Mvuma and Chivu. The limitations of theses soils include low water holding capacity, low permeability and low nutrient reserves. They are therefore used for commercial forestry and also for production of crops like millet and /or sorghum (Nyamapfene, 1991).

The paraferralitic, orthoferralitic and sodic soils have the same rating in term of area covered. The paraferralitic are found in association with granite rocks only. The paraferralitic soils are found in upland areas in Harare, Marondera and Headlands. The soils are also found just outside Harare eastwards through Epworth. There is a long belt that extends southwards through Wedza to the Range - Chivu and then Buhera (Nyamapfene, 1991). The soils are rich in potassium since they are derived from granite rocks. These soils are the best for tobacco and maize production. Groundnuts can also be grown on the soils but in all cases, there is need to apply nitrogen and phosphorus. Liming is also essential (Nyamapfene, 1991).

The orthoferralitic soils are mainly found in areas where rainfall is greater than 900 mm per annum especially in the Eastern Highlands, Bikita - Ndanga, Mvurwi, Marondera and Headlands. Those orthoferralitic soils in the Eastern Highlands are more strongly leached and have considerable organic matter. These soils generally have high clay content and are potentially productive (Nyamapfene, 1991).

Sodic soils occur in the low rainfall areas, which include the Save and Zambezi Valleys. In moderate rainfall areas, interaction of parent material and relief results in significant soils for example Gokwe, Chivu and Chegutu. The soils have undesirable physical and chemical properties for example, their high pH which inhibits nutrient availability (Nyamapfene, 1991). In the low rainfall areas farmers do grow millet and sorghum on them since these can tolerate both high pH levels and sodium (Nyamapfene, 1991). This practice is common in areas where surface horizon depth is 25-30 cm overlying dense impermeable subsoil. In the latter case the surface soil that is light to medium textured acts as the rooting medium while the dense subsoil caters for water storage. In most cases however, the soils are shunned for agriculture and better left for grazing.

2.2.1Soil classification

Soil classification is an artificial means by which similar soils are grouped together. The classification of soils is very important since it forms the basis for scientific exchange of information about soils. The soil classification currently in use in Zimbabwe was developed in the middle of the twentieth century (Thompson, 1965) and was largely based on the principles used by the Inter - African Pedological services (S.P.I) for the soil map of Africa. A cardinal principle is that the classification is based on the degree of weathering and leaching to which the soils derived from a given parent material have undergone. The classification system by Thompson and Purves (1978) has some agronomic bias as it includes those characteristics considered important in agricultural production which include depth, water holding capacity, nutrient status and structure.

The approach used in Zimbabwe has been from the upper taxonomic level going downwards. Most of the important soil characteristics and properties are defined at higher taxonomic levels. The highest taxonomic level is the order followed by the group then the family and lastly the soil series level (Nyamapfene, 1991). In agroecological zoning, the most important taxonomic level is the group level since at this level, important soil characteristics such as depth, texture, nutrient status and water holding capacity can be inferred and hence soil productivity.

2.2.2Soils and agroecological zoning

Soils equally play a pivotal role in the possible land utilization types but the climate usually dominates the other factors limiting agricultural production. The degree of land utilization depends on the soil type (Vincent and Thomas, 1960). The soil type is an indicator of the inherent fertility of the soil, governs nutrient availability to crops, determines how much water is stored in the root zone, the time during which the water is stored for plant use and therefore how much water is available for plant use (Brady, 1999). Therefore, mean annual rainfall amount cannot be used as a single indicator in land evaluation.

According to Cook et al. (2000) land suitability can be done on assumptions that certain economically feasible improvements have been made on the land. In the case of the soils of Zimbabwe, the orthoferralitic soils, paraferralitic soils and fersialitic soils which have lower fertility than the vertisols and siallitic soils can be made highly productivity when certain nutrients are added to the soil. The same cannot be said about the lithosols whose limitation to cropping is depth and also the regosols which have a very poor structure. As for the sodic soils the major problem is that of high bulk density and poor structure (Nyamapfene 1991).