One reason that temperatures are lower in the winter than in the summer is that

Lamp (with shade removed)
Large ball (an air-filled beach ball is ideal)
Marker
Drinking straw (cut in half)
Plasticine
LEGO™ figure or other small object
Room that can be made dark

Safety First!

Light bulbs can get very hot. Make sure your hands and other objects do not touch the bulb.

Draw a line around the middle of the ball to represent the Earth’s equator. Stick the opening of one piece of a drinking straw on the ‘North Pole’ using plasticine. The straw should stick out from the surface of the ball at a right angle. Do the same thing with the other piece of drinking straw at the ‘South Pole.’ The drinking straws represent the line of the Earth’s axis.
Stick a LEGO™ figure, or other small object, about 3/4 of the way above the equator to represent someone living in Canada.
Move the ball (Earth) around the lamp (Sun) in a circular motion. This represents the Earth’s orbit. The line you drew on the ball to represent the equator should be at the same level as the lamp’s light bulb.
Next, hold the Earth with its axis (straw at the ‘North Pole’) tilted at about a 20 degree angle towards the Sun on the side where the LEGO™ figure is located. The LEGO™ figure and equator line should be fully lit up by the light bulb. In North America, we call this position relative to the Sun “summer.” To see what day and night is like during the summer, spin the ball around its axis and watch where there is light and shadow on the Earth.
Next, move the Earth over to the opposite side of the light keeping the axis at the same angle as you did for the previous step. Ensure you keep the ‘North Pole’ pointing in the same direction as you did previously. That is, if the ‘North Pole’ was tilted to the left in relation to the Sun, it should still be pointed to the left when moved to the opposite side. This represents 6 months later. Make sure the Earth is slightly closer to the Sun at this point. In North America, we call this position relative to the Sun “winter.” Rotate the Earth so that LEGO™ figure is on the side facing the Sun. Notice where the light and shadow is now. To see what day and night is like during the winter, spin the ball around its axis and watch where there is light and shadow on the Earth.
Complete the year by having the Earth move around the Sun back to the starting (“summer”) position. The Earth should be further from the Sun at this point than it was in its winter position.

People often think that it is hotter in the summer (in the northern hemisphere) because the Earth is closer to the Sun. In fact, in the northern hemisphere summer, the Earth is farther away!

The reason for the difference in temperature between the summer and the winter actually has to do with the tilt of the Earth’s axis. If the Earth were not tilted at an angle, there would be no summer or winter.

In the summer, the northern hemisphere is tilted toward the Sun which means that the Sun’s rays hit this part of the Earth’s surface more directly. Since there is more direct sunlight, more of the Sun’s energy is absorbed by the land surface. As a result, the temperature is higher. Depending on where you live in relation to the equator, if you look up towards the Sun at noon (12 p.m.) in the summer, you will see that the Sun is higher in the sky than it is in the winter.

In the winter, the northern hemisphere is tilted away from the Sun, which means that the Sun’s rays hit this part of the Earth in a more oblique or slanted manner. Since there is less direct sunshine, less energy is absorbed by the surface and the temperature is lower. If you look up towards the Sun at noon in the winter, you will see that the Sun lower in the sky.

The southern hemisphere experiences the reverse of the northern hemisphere. When it is summer in the northern hemisphere, it is winter in the southern hemisphere and vice versa. So remember, seasons are all about the tilt of the Earth’s axis, not the distance between the Earth and the Sun!

People often think that it is hotter in the summer (in the northern hemisphere) because the Earth is closer to the Sun. In fact, in the northern hemisphere summer, the Earth is farther away!

The tilt of the Earth as it travels around the Sun determines our seasons.

Try the activity again, changing the tilt of your Earth. What would happen if the Earth had no tilt? What if it was tilted at 90°?

For more information on this topic check out these Let's Talk Science resources:

Why do we have seasons? (Backgrounder) - Learn why seasons change. Discover how they’re different in the Northern and Southern hemispheres.

Try the activity again, changing the tilt of your Earth. What would happen if the Earth had no tilt? What if it was tilted at 90°?

For more information on this topic check out these Let's Talk Science resources:

Why do we have seasons? (Backgrounder) - Learn why seasons change. Discover how they’re different in the Northern and Southern hemispheres.

Teaching Guidance for 11-14

Wrong Track: Clouds stop heat from the Sun – there are more clouds in the winter, blocking out the Sun's heat.

Wrong Track: Distance of Earth from the Sun – we get the four seasons by the Sun moving around and if the Earth moves away from the Sun it will get colder and if the Earth moves closer to the Sun it will be warmer. They change because in the summer the Sun is closer to the Earth and in the autumn the Sun is a lot farther away and in the winter it is cold because the Sun is a long way away.

Wrong Track: Sun on other side of the Earth – in the summer the Sun is next to us but in the winter it goes around to the other side of the world.

Getting off on the right lines – it's all about angles

Right Lines: The seasonal changes are due to the tilt of the Earth's axis and the effect that has on the angle at which the Sun's rays meet the surface of the Earth as the Earth orbits the Sun.

Considering what might go wrong

Thinking about the learning

Clouds stop heat from Sun: These explanations involve clouds stopping the Sun from warming us in the winter months.

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Distance of the Earth from the Sun: These explanations all involve the Earth being closer to the Sun in the summer and farther away from the Sun in the winter.

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Sun on the other side of the Earth: The idea here is that when the Sun is on your side of the Earth it's summer and when it's on the other side of the Earth it's winter.

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Here are the responses of two mixed ability science classes of 11-year-olds (one had completed their year's work on the solar system, while the other had not yet started – total of 50 pupils) in well established comprehensive schools to the challenge: Use words and diagrams to explain your ideas about why we get the seasons.

A large-scale study focusing on simple astronomical ideas was recently carried out with the general adult public and 16-year-old pupils. The correct scientific explanation for seasonal changes was offered by less than 50 % of the pupils. As for the public, 60 % of them knew that the Earth orbits the Sun rather than vice versa but only 33 % knew that it took one year.

These are not easy ideas to teach.

Planning for teaching

Thinking about the teaching

By far the most common response to explaining the seasons is in terms of distance from the Sun. This is based on the common-sense reasoning that if you go closer to a glowing source, then you become warmer.

Voice of the street: The Earth is closer to the Sun in the summer, so it must be warmer.

This seems to be a reasonable line of argument, further developed as

Voice of the lane: The closer you are, the warmer it gets.

Unfortunately it's on the wrong track!

The slightly elliptical orbit of the Earth around the Sun means that we (in the Northern Hemisphere) are 152 million km from the Sun in summer but 147 million km from the Sun in winter. The Earth is actually nearer to the Sun in winter!

(And it is only a 3 % difference, probably not enough to explain the difference in average temperatures between summer and winter in any case.)

This idea is, unfortunately, supported by those textbooks which show the orbit of the Earth around the Sun as a very obvious and flattened ellipse.

This not an accurate representation. The orbit of the Earth is only slightly elliptical.

One thing you should look out for are those children who accept the idea that seasonal changes are due to the tilt of the Earth but then suggest that the tilt makes one hemisphere closer to the Sun, thereby bringing summer.

This is not correct; it is a projected area effect not a distance effect.

Here is the essence of the argument. There is much more in the Physics Narrative.

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There is another line of thinking, that experience suggests you are more likely to come across in adults, but it is worth watching out for.

Wrong Track: The Sun is lower on the horizon in the winter, so there the rays have to travel through a greater thickness of atmosphere, so they are weaker.

As ever, there is some reason for believing this, but the numbers just don't stack up. The Sky does appear more red in the morning and evening because some of the blue fraction of the light is affected by the atmosphere, and is scattered (which is why the sky overhead appears blue). Notice that this is an effect that depends on direction, rather than on thickness.

There is, of course, some absorption of the insolation by each kilometre of atmosphere, but a model of the differences between a summer and winter day do not suggest that there is enough of a difference for it to be a significant factor in accounting for the seasons.

The atmosphere is a variable and complex filter – the quantity of water vapour locally is a big factor – but a justifiable range for the absorption is 5–16 watt metre-2 kilometre-1.

is a type of Main Sequence Star