Earth, Sun & Moon: seasons, eclipses, tides

What you will learn

how Earth’s rotation produces day and night, and why the Sun appears to “move” across the sky,
how Earth’s $23.5°$ axial tilt (not its distance from the Sun) causes the seasons,
the cause of the Moon’s phases and the difference between a lunar and a solar eclipse,
how the Moon’s gravity produces two tidal bulges on Earth,
why eclipses do not happen every month.

Worked example 0 Real-world example: why summer in Melbourne is December

On 21 December, the Southern Hemisphere is tilted towards the Sun.

Sunlight hits Melbourne at a steeper angle — the same beam of light covers less ground, so more energy per square metre.
Days are longer in summer (more hours of sunlight).
The atmosphere has less time to cool down overnight.

Result: hot summer days even though Earth is actually a little further from the Sun in December than in June.

Key idea: it is the tilt, not the distance, that causes seasons. The tilt causes both steeper sunlight and longer days for the tilted-towards hemisphere.

1. Day, night and the Earth’s rotation

Earth spins on its axis once every 24 hours. At any instant half the Earth faces the Sun (day) and half faces away (night). From the ground, the Sun appears to move east to west because we are rotating west to east.

The axis is tilted at $23.5°$ from the vertical, and this tilt stays pointed in the same direction in space all year as Earth orbits.

2. Seasons

Earth takes about $365.25$ days to orbit the Sun once. Because of the axial tilt:

When the Southern Hemisphere is tilted towards the Sun → Southern summer (Dec/Jan/Feb).
When it is tilted away → Southern winter (Jun/Jul/Aug).
When the tilt is sideways to the Sun → spring or autumn (equinoxes around March and September).

Earth's axial tilt (23.5°) and the four positions in its orbit. The Southern Hemisphere is tilted towards the Sun in December.

Worked example 1 Why the equinoxes are equal day and night

At the equinoxes (around 21 March and 23 September), Earth’s tilt is sideways to the Sun.

The Sun is directly overhead at the Equator.
The terminator (line between day and night) passes through both poles.
Every place on Earth gets roughly $12$ hours of daylight and $12$ hours of night.

The word “equinox” means “equal night”.

3. Phases of the Moon

The Moon orbits Earth about once every $29.5$ days (a “lunar month”). Half the Moon is always lit by the Sun, but we only see the lit side from certain angles.

New Moon: Moon between Earth and Sun — we see the unlit side.
First quarter: a quarter-orbit later; we see half lit.
Full Moon: Earth between Moon and Sun — we see the fully lit side.
Last quarter: three-quarters of the way around; we see the other half lit.

Worked example 2 Why the Moon looks like a 'D' or a 'C'

In the Southern Hemisphere:

A waxing Moon (getting fuller, first half of cycle) looks like a backwards D (curve on the left).
A waning Moon (getting thinner) looks like a backwards C.

In the Northern Hemisphere the shapes are reversed because the observer is “upside down” relative to the ecliptic.

Key idea: the phase tells you the angle between Sun, Earth and Moon — not a change in the Moon itself.

4. Eclipses

An eclipse happens when Sun, Earth and Moon line up.

Solar eclipse — Moon is between Sun and Earth. Moon’s shadow falls on Earth. Happens at New Moon.
Lunar eclipse — Earth is between Sun and Moon. Earth’s shadow falls on the Moon. Happens at Full Moon.

Eclipses do not happen every month because the Moon’s orbit is tilted about $5°$ from Earth’s orbit around the Sun. Most months the Moon passes above or below the Earth-Sun line rather than through it.

Top: solar eclipse geometry. Bottom: lunar eclipse geometry. Distances not to scale.

5. Tides

The Moon’s gravity pulls the water on Earth’s surface slightly towards it. This creates a bulge of water on the side facing the Moon. A second bulge forms on the opposite side (because the solid Earth is pulled away from the water on the far side).

As Earth rotates, each point passes through two bulges and two low regions — so most coasts see two high tides and two low tides each day (every $\approx 12$ h $25$ min).

Spring tides (largest range): Sun and Moon aligned (New or Full Moon).
Neap tides (smallest range): Sun and Moon at right angles (First/Last quarter).

Worked example 3 Why tides are biggest at New Moon

At New Moon the Sun, Moon and Earth line up.

Moon’s gravity pulls water towards it — creates the main tidal bulge.
Sun’s gravity adds a smaller bulge in the same direction.
Combined bulge is higher; the opposite (far-side) bulge is also larger.

Result: a bigger high tide and a lower low tide — a spring tide. Spring tides are why king tides happen around a New or Full Moon.

Key idea: tides depend on the alignment of Sun and Moon, not how close they are.

Practice: Year 7

Fluency

Tier 1: recall and identify

How long does Earth take to spin on its axis? How long to orbit the Sun?
Why do we have day and night?
Explain in one sentence why Earth has seasons.
What is the angle of Earth’s axial tilt?
Name the phases of the Moon in order starting from New Moon.
How long is one lunar month (from New Moon to New Moon)?
What lines up during a solar eclipse? At what phase does a solar eclipse happen?
What lines up during a lunar eclipse? At what phase?
How many high tides does most of the Australian coast see each day?
What is a spring tide?

Reasoning

Tier 2: explain and reason

Explain why summer days are longer than winter days.
Why are temperatures hottest about a month after the summer solstice, not on the solstice itself?
Explain why a solar eclipse does not occur at every New Moon.
Sketch the relative positions of Sun, Earth and Moon at (a) Full Moon, (b) First quarter.
Why does a lunar eclipse turn the Moon reddish rather than simply making it disappear?
Explain why tides still occur on lakes but are much smaller than ocean tides.

Problem solving

Tier 3: apply to a novel context

If Earth’s tilt were $0°$ instead of $23.5°$ , describe two ways life would differ.
On a planet with no moon, would tides still exist? Justify.
A sailor plans a week-long coastal trip and wants the biggest tidal range to explore tidal pools. Which phase of the Moon should she pick?
Mars has a tilt similar to Earth’s ( $25°$ ) but takes about $687$ days to orbit the Sun. Predict how seasons on Mars would differ from Earth’s.

Challenge

Reasoning

Harder reasoning

The Moon is slowly moving away from Earth (about $3.8$ cm per year). Predict what will eventually happen to (a) the length of a day on Earth and (b) the size of tides, and justify each.
Some years have a “blue Moon” — two Full Moons in the same calendar month. Explain why this is possible, using the $29.5$ -day lunar cycle.
If the Moon’s orbit were in exactly the same plane as Earth’s orbit around the Sun, how often would solar eclipses occur? Explain.
Design a classroom model using a torch (Sun), a ball (Earth) and a smaller ball (Moon) that shows why we see lunar phases. State one limitation of the model.