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Moons of our Solar System: from captured rocks to ocean worlds, with a deep dive on Earth's Moon

📚 Science 🎓 Grade 6 ⏱️ 40 minutes

Learning Objectives

  • Define a moon (natural satellite) and explain how moons differ from planets and dwarf planets.

  • Describe which planets in our Solar System have moons and compare examples of remarkable moons.

  • Use a simple model to explain why we always see nearly the same face of Earth's Moon (tidal locking) and clarify the 'far side' vs 'dark side' idea.

  • Explain, using gravity and the Earth-Moon system, why most coasts experience two high tides and two low tides per day and why tides shift later each day.

Progress 7 sections
1

Engage: What is a moon?

~5 minutes

Essential question

How do moons form and behave, and why does Earth's Moon matter for life on Earth?

Quick warm-up (1 minute)

Look at a picture of the night sky (or imagine it). What is one thing you already know about the Moon or other moons?

Vocabulary you will use


Moon (natural satellite): a natural object that orbits a planet or dwarf planet.
Gravity: the attractive force between masses.
Orbit: the path an object follows as it goes around another object.
Tide: the regular rise and fall of ocean water level.
Tidal locking: when an orbiting object rotates in the same amount of time it takes to orbit, so it keeps the same face pointed toward its partner.

📖 What is a moon?

A moon is a natural satellite, meaning it is not man-made and it orbits a planet or dwarf planet. Moons can be rocky, icy, or a mix. Some are round like planets. Others are lumpy like potatoes.

2

Moons across the Solar System

~10 minutes

How do moons get there?

Scientists think moons form in a few common ways:

1. Made with the planet: material around a young planet clumps together into moons (many large, regular moons). 2. Captured: a planet's gravity grabs a passing asteroid or dwarf planet (often small, irregular moons). 3. Big impact: a huge collision throws material into orbit that later clumps into a moon (a leading idea for Earth's Moon).

Not every planet has moons. Mercury and Venus have zero known moons.

Known moons by planet
Horizontal bar chart showing the number of known moons for each planet: Mercury 0, Venus 0, Earth 1, Mars 2, Jupiter 97, Saturn 274, Uranus 29, Neptune 16. Note that counts can change as new moons are...

Known moons in our Solar System (snapshot)

Counts can change as astronomers discover tiny moons and as objects get confirmed by international naming groups.

PlanetKnown moons
Mercury0
Venus0
Earth1
Mars2
Jupiter97
Saturn274
Uranus29
Neptune16
Why so many for the giant planets? They are massive and have strong gravity, so they can collect and keep many moons.

💡 Some moons are bigger than planets

Jupiter's moon Ganymede is bigger than Mercury. Saturn's moon Titan is also bigger than Mercury. Moons can be world-sized.

Remarkable moons worth knowing (quick tour)

Pick a few of these to highlight based on time.

- Io (Jupiter): extremely active volcanoes.
Europa (Jupiter): icy crust with strong evidence for a deep ocean.
Ganymede (Jupiter): largest moon in the Solar System.
Titan (Saturn): thick atmosphere and lakes of liquid methane and ethane.
Enceladus (Saturn): ice geysers that spray material into space.
Triton (Neptune): orbits backward compared with Neptune's spin, suggesting it may have been captured.
Phobos and Deimos (Mars): small, irregular moons that look like captured asteroids.

Teacher note: If students ask "Could there be life?", focus on what scientists look for: liquid water, energy, and the right chemistry.

Our Moon Isn't the Only Moon (NASA Space Place video)
3

Earth's Moon: orbit and tidal locking

~15 minutes

Earth's Moon (deep dive)

In the rest of this lesson, you will focus on Earth's Moon and why it matters.

Moon basics


• Average distance from Earth: about 384,400 km.
• The Moon takes about 27.3 days to orbit Earth once (sidereal month).
• New Moon to New Moon takes about 29.5 days (synodic month).
• The Moon is slowly moving away from Earth over time.

Even though the Moon looks like it "follows" Earth, Earth and the Moon actually move together around a shared center of mass.

Earth-Moon orbit, barycenter, and tilt
Diagram showing Earth with a small dot inside labeled barycenter, the Moon on a slightly elliptical orbit, and an arrow showing the Moon orbits counterclockwise. Two lines at the bottom show the Moon'...
💡 Two different 'months'

A 27.3-day month is based on the Moon's orbit compared with the stars. A 29.5-day month is based on how long it takes the Moon phases to repeat (New Moon to New Moon). Both are true, they measure different things.

The Moon's 'weird' orbit (in a good way)

The Moon's orbit is not a perfect circle. Sometimes it is a little closer (perigee) and sometimes a little farther (apogee).

The Moon's orbital path is also tilted about 5 degrees compared with Earth's orbit around the Sun. This is one reason eclipses do not happen every month.

If you want a challenge question:
• What would change if the Moon's orbit were not tilted at all?

Tidal locking: why we see nearly one face of the Moon
Two-panel diagram. Left panel shows a Moon that does not rotate: the same mark stays pointed in one direction, so Earth would see different sides at different orbit positions. Right panel shows a tida...

Tidal locking (why we see one face)

A common mistake is to say "the Moon does not spin." It does spin.

- The Moon spins once on its axis in the same time it orbits Earth once.
• That is why the same face stays pointed toward Earth. This is called tidal locking (or synchronous rotation).

Near side, far side, and "dark side"


• The near side is the half that faces Earth most of the time.
• The far side is the half that faces away most of the time.
• The far side is not always dark. It gets sunlight during its own day, just like the near side.

Extra interesting detail (optional)

Because the Moon's orbit is a little tilted and a little oval, the Moon appears to wobble (called libration). Over time, we can see a little more than half of the Moon's surface from Earth.

Question 1

Tidal locking means the Moon makes one ______ on its axis in the same time it makes one orbit around Earth.

Word Bank:
rotation revolution gravity eclipse
Question 2

We see only one face of the Moon because the Moon does not rotate.

4

Tides: bulges, timing, spring vs neap

~10 minutes
What Causes Tides? (NOAA video)
Tides: two ocean bulges caused by the Moon
Diagram showing Earth with an ocean shape stretched toward and away from the Moon, creating two high tide bulges on opposite sides. Low tides are shown on the sides at right angles. Earth rotation is ...

Tides and the Moon

The Moon's gravity pulls on Earth. It pulls a little more strongly on the side of Earth that is closer to the Moon than on the side that is farther away. This difference helps create two bulges in Earth's oceans:

- one bulge on the side facing the Moon
• one bulge on the opposite side

As Earth rotates, a coastline can pass through: 1. a bulge (high tide), 2. a low point (low tide), 3. the other bulge (high tide), 4. the other low point (low tide).

That is why many coasts have two high tides and two low tides each day.

Why do tides happen later each day?

Earth is spinning, but the Moon is also moving along its orbit. So Earth needs a little extra time to "catch up" to the Moon's position. Tide timing shifts about 50 minutes later each day.

Spring tides and neap tides (patterns)


Spring tides: when the Sun, Earth, and Moon line up (New Moon or Full Moon). Tides are extra strong.
Neap tides: when the Sun and Moon pull at right angles (First Quarter or Last Quarter). Tides are less strong.

Reality check: real tide heights also depend on local coastline shape, ocean depth, and weather.

5

Check for understanding

~5 minutes
Question 3

Which definition best matches a moon?

Question 4

Which planets have zero known moons? (Select all that apply)

Select all that apply.

Question 5

Match each moon with an interesting fact:

Io
Europa
Titan
Enceladus
Question 6

Put these Moon phase names in order for one cycle, starting at New Moon:

⋮⋮ Last Quarter
⋮⋮ Full Moon
⋮⋮ New Moon
⋮⋮ First Quarter
Drag items to reorder, then confirm
6

Exit ticket and wrap-up

~5 minutes

Key takeaways

  • Moons are natural satellites that orbit planets or dwarf planets.

  • Giant planets have many moons because of their strong gravity.

  • Earth's Moon is tidally locked, so we see nearly the same face.

  • The Moon's gravity is the main driver of Earth's ocean tides.

  • Tides shift later each day because the Moon moves in its orbit.

Question 7

In your own words, explain why many coastlines get two high tides and two low tides each day. Use the idea of two ocean bulges in your answer.

Expected length: 40-120 words

Question 8

Exit ticket: Choose one remarkable moon from the quick tour (Io, Europa, Titan, Enceladus, Triton, Phobos, Deimos). Write 2-3 sentences explaining what makes it interesting and what question you would want scientists to answer about it.

Expected length: 40-120 words

7

Optional extension (if time or homework)

Gravity and Orbits (PhET Interactive Simulation)