4.1: The Earth in Space

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Earth’s orbit about the sun is nearly circular at a mean distance of \(1.5 \times 10^{8}\) km. The eccentricity of the orbit is small, 0.0168. Thus Earth is 3.4% further from the Sun at aphelion than at perihelion, the time of closest approach to the sun. Perihelion occurs every year in January, and the exact time changes by about 20 minutes per year. In 1995, it occurred on 3 January. Earth’s axis of rotation is inclined 23.45\(^{\circ}\) to the plane of Earth’s orbit around the sun (figure \(\PageIndex{1}\)). The orientation is such that the sun is directly overhead at the Equator on the vernal and autumnal equinoxes, which occur on or about 21 March and 21 September each year.

Diagram of the Earth in space, showing how the ellipticity of Earth’s orbit around the sun and the tilt of Earth’s axis of rotation relative to the plane of orbit leads to an unequal distribution of heating and to the seasons. Earth is closest to the sun at perihelion, at winter solstice. — Figure \(\PageIndex{1}\): The Earth in space. The ellipticity of Earth’s orbit around the sun and the tilt of Earth’s axis of rotation relative to the plane of Earth orbit leads to an unequal distribution of heating and to the seasons. Earth is closest to the sun at perihelion.

The latitudes of 23.45\(^{\circ}\) North and South are the Tropics of Cancer and Capricorn respectively. The tropics lie equatorward of these latitudes. As a result of the eccentricity of earth’s orbit, maximum solar insolation averaged over the surface of the earth occurs in early January each year. As a result of the inclination of earth’s axis of rotation, the maximum insolation at any location outside the tropics occurs around 21 June in the northern hemisphere, and around 21 December in the southern hemisphere.

If solar heat was rapidly redistributed over earth, maximum temperature would occur in January. Conversely, if heat were poorly redistributed, maximum temperature in the northern hemisphere would occur in summer. So it is clear that heat is not rapidly redistributed by winds and currents.

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