Prevailing Wind Belts of Earth. The earth is encircled by several broad prevailing wind belts, which are separated by narrower regions of either subsidence or ascent. The direction and location of these wind belts are determined by solar radiation and the rotation of the earth. The three primary circulation cells are known as the: Hadley cell; Ferrel cell; and Polar cell.
On or near the equator, where average solar radiation is greatest, air is warmed at the surface and rises. This creates a band of low air pressure, centered on the equator known as the intertropical convergence zone (ITCZ). The Intertropical Convergence Zone draws in surface air from the subtropics. When this subtropical air reaches the equator, it rises into the upper atmosphere because of convergence and convection. It attains a maximum vertical altitude of about 14 kilometers (top of the troposphere), and then begins flowing horizontally to the North and South Poles. This rising air comprises one segment of a circulation pattern called the Hadley Cell (see diagram below). The Hadley cell eventually returns air to the surface of the earth, near 30 deg N and S.
The descending portion of the Hadley Cell produces a band of high air pressure at these latitudes called the subtropical high. From this zone, the surface air travels in two directions. Winds are generated between the subtropical high and the equatorial band of low pressure (ITCZ), as air moves from high surface pressure toward low surface pressure. These winds are deflected from east to west as they travel toward the equator by the coriolis force, and are called the Trade Winds or the Tropical Easterlies. The other portion of the surface air moves towards the poles from the subtropical high zone. This air is also deflected by the Coriolis force, producing the Westerlies.