Reasons for Seasons
Teacher's Background Information

(Reasons for Seasons Mini-Unit)

Watching the wave of spring sweep northward is at the heart of Journey North. All seasonal changes – temperature, plant growth and life cycles, animal migrations, and so on – are driven by shifts in:

  • the amount of available sunlight (called day length or photoperiod)
  • the intensity of sunlight (related to the angle at which it strikes the Earth)


Rotation vs. Revolution
Viewed from above, the Earth makes a complete counterclockwise rotation (spins on its axis) once in each 24-hour period. This is why the sun appears to rise in the east and set in the west. But this daily rotation has nothing to do with seasons. The Earth also revolves counterclockwise around the sun once every 365 1/4 days. This yearly revolution, combined with the earth’s tilt causes seasons.

Earth's yearly revolution,
Tilt and Revolution
The Earth's axis is not oriented vertically, but is tilted by 23.5 degrees. The north end of the axis is always pointed toward the North Star as the Earth revolves around the sun. This tilt, combined with its revolution around the sun, causes seasonal changes. (When it’s summer in the northern hemisphere, it’s winter in the southern, and vice versa.) If the axis was not tilted, our year-round climate would be rather boring and many places on earth wouldn’t receive much light!


During our summer, the Northern Hemisphere leans toward the sun in its revolution, there are more daylight hours, and the sun’s angle is more perpendicular to us than at other times of year. The longer days and more concentrated sunlight and results in more heating. (Shadows are shorter in the summer because the sun strikes Earth more directly.)

During winter, the Northern Hemisphere leans away from the sun, there are fewer daylight hours, and the sun hits us at an angle; this makes it appear lower in the sky. There is less heating because the angled sun’s rays are “spread out” rather than direct. (Shadows are longer because of the lower angle of the sun.)

In equatorial regions, the length of days and the directness of sunlight don't change as much. The further you get from the equator, the more dramatic the seasonal changes.

During the spring and fall, the Earth leans neither toward nor away from the sun; daylight and nighttime hours are more equal and temperatures are moderate. (The shadow of an object is similar during these seasons.)

Season animation

Common Misconceptions
Many students (and adults) believe that the Earth is closer to the Sun in the summer and further away in the winter. (It’s actually somewhat closer to the sun in the winter, but the angled rays and short days don’t give us much heat.) Another misconception is that the earth orbits the sun in an elongated ellipse, which makes the earth’s distance from the sun dramatically different at different locations. The reality is that the earth’s orbit is nearly circular.

Solstice vs. Equinox

Solstice refers to the two times each year when the sun's strongest rays are furthest from the equator (north of it during our summer solstice and south during the winter). For the northern hemisphere, summer solstice occurs around June 21st; we have the maximum number of daylight hours at that time. Winter solstice is around December 21st when we have the fewest daylight hours.

Equinox refers to the two times each year when the sun's strongest rays are directly hitting the equator. Everywhere on earth has 12 hours of daylight on the spring and fall equinoxes. In the northern hemisphere, spring equinox occurs around March 21st and autumnal equinox around September 21st.