Mediterranean soils are generally deficient in humus, not so much because of sparse vegetation cover as because of the slowness of the chemical processes that convert the vegetable matter to humus. Low rainfall, occurring when temperatures are lowest, retards chemical weathering. The uneven surface relief of the regions where these soils occur also makes it difficult for mature soils to develop, since the land, except in the valley bottoms, is not sufficiently flat over wide enough areas to allow the soil-forming (parent) materials to remain in place and thus to be thoroughly weathered. Soil problems

Soil is the foundation of Africa’s economic life, and as such its detailed study is most important. Failure to appreciate the physical and chemical properties of the soils has led to disastrous results for several projects for agricultural improvement.

In studying the soils of Africa, it is essential not to lose sight of the importance of such social factors as the ability or inability of mostly uneducated farmers to judge the quality of the soil. Thus, schemes for transforming traditional systems of farming that are based on soil classification but that do not take into account local perception may have little chance of success.

For desert soils to be productive they must be irrigated, as they are on the desert margins of North Africa; their excessive salinity or alkalinity must also be reduced. Compared to desert soils, the chestnut-brown soils are easier to work and are more productive under irrigation. Black soils tend to have a markedly crumbly structure and are sometimes difficult to plow. In the wet season, the black soils of the Accra Plains swell and become slippery, while in the dry season they shrink once more and crack to such an extent that they are said to plow themselves. Red tropical soils need careful handling. Despite their luxuriant vegetation cover, high temperatures coupled with humidity promote the rapid decay of organic matter and keep the humus content low. Erosion is a constant threat if the soils are exposed to the elements for any length of time; the soils remain cultivable only if the sesquioxides remain below the surface.

In the Atlas and Cape regions, there is a clearer relationship between soil characteristics and parent material than in the humid tropical areas. Over expanses of limestone, for example, the soils contain large amounts of calcium compounds, some of which must be washed away or neutralized before the soils can become fully productive. Climate Factors influencing the African climate

A number of factors influence the climate of the African continent. First, most of the continent—which extends from 35° S to about 37° N latitude—lies within the tropics. Second, the near bisection of the continent by the Equator results in a largely symmetrical arrangement of climatic zones on either side. This symmetry is, however, imperfect because of a third factor—the great east–west extent of the continent north of the Equator, in contrast to its narrow width to the south. In consequence, the influence of the sea extends farther inland in Southern Africa. Moreover, a quasi-permanent subtropical high-pressure cell (the Saharan anticyclone) develops in the heart of northern Africa, while in Southern Africa the belt of high pressure on land weakens during the time of high sun (the season when the Sun is overhead—in December and January in the south). A fourth factor consists of the cool ocean currents, which chill the winds that blow over them and thereby influence the climate of the neighbouring shores. Fifth, because of the extensive plateau surfaces of the continent and the absence of high and long mountain ranges comparable to, for example, the Andes in South America or the Himalayas in Asia, climatic zones in Africa tend to shade into one another, rather than change abruptly from place to place. Finally, the high mountains have climatic zones of their own that vary with altitude.

While these factors help to account for the broad climatic patterns of the African continent, there are nevertheless numerous local variations to be found from place to place within the same climatic zone. Urban areas, for example, have climates that often differ in many respects from those of the surrounding countryside. Typically experiencing higher average temperatures, urban areas also frequently have less wind and lower relative humidity; there is too little relevant data from Africa, however, to permit a detailed study of urban climates.

The most important differentiating climatic element is rainfall; this, together with several other climatic elements, depends upon the characteristics of the dominating air mass. The air masses of relevance to the African climate may be broadly classified as maritime tropical, maritime equatorial, continental tropical, maritime polar, and continental polar. Of these, the least important are the continental polar air masses, which may occasionally bring intense cold to northern Egypt in December and January, and the maritime polar air masses, which are associated with rain-bearing depressions over the northern and southern extremities of the continent during the winter. With the exception of these, the continent is affected both by a continental tropical air mass to the north and by maritime tropical and maritime equatorial air masses to the south.

These northern and southern air masses meet at the intertropical convergence zone (ITCZ). The hot, dry continental tropical air mass, which is present in the upper levels of the atmosphere, descends to the ground only at the convergence zone. Less hot than the continental tropical are the maritime tropical and maritime equatorial air masses, which originate from the Indian and South Atlantic oceans, respectively; they differ only in that the maritime equatorial air mass is unstable and brings rain while the maritime tropical air mass, when fully developed, is stable and does not normally bring rain unless it is forced to rise by a high mountain.

In July the ITCZ—following the sun—moves northward toward the area of low pressure over the Sahara; there the maritime and continental tropical air masses converge, with the maritime air masses swinging inland from the sea. There is no rainfall on the northern side of the convergence zone, since the region is completely under the dry continental tropical air mass originating over the Sahara. At the ITCZ itself, however, precipitation is prolonged and intense as air converges between the maritime and continental air masses and is forced aloft. Immediately south of the convergence zone, rainfall is heavy because of the unstable nature of maritime tropical air over a heated land surface. South of the Equator, at yet greater distance from the convergence zone, the maritime air masses are less-heated, thick, and stable, and they bring hardly any rainfall, except over some of the East African highlands. Only the southern tip of South Africa receives rainfall at this time, from winter cyclones.

During the period of low sun in the Northern Hemisphere (from December to January, when the sun has moved to its southern limit), the situation described above is reversed. The convergence zone moves southward, dipping into Southern Africa. At this season the whole of northern Africa (except the Atlas Mountains) is under the dry continental tropical air mass, while Southern Africa receives rainfall except in the Cape region and on the southwest coast, where the maritime air mass remains stable offshore over the cool Benguela Current. Climatic regions