Geophysics Explorer

How does our planet work from the inside out?

Earth's Layers — An Onion Made of Rock and Metal

Earth isn't a uniform ball. It has layers — like a hard-boiled egg, but with a liquid part in the middle. Click each layer in the diagram to explore.

Crust

Mantle

Outer Core

Inner
Core

Click a layer above to explore it!

Each layer has different properties — different temperature, thickness, and what it's made of. The deeper you go, the hotter and denser it gets.

Key Concept — How Do We Know What's Inside?

We've never drilled deeper than 12 km (the Kola Superdeep Borehole in Russia — and Earth's radius is 6,371 km!). So how do we know? Seismic waves from earthquakes. Different types of waves travel at different speeds through solid vs liquid material, and they bend and reflect at layer boundaries. By studying thousands of earthquakes from stations around the world, scientists mapped the interior — like giving the planet an ultrasound.

Fun comparison

The hard-boiled egg model

Cut a hard-boiled egg in half: the shell is the crust, the white is the mantle, and the yolk is the core. The proportions are surprisingly similar! But notice how thin the shell is compared to everything else — Earth's crust is proportionally even thinner than that.

If Earth were shrunk to the size of an apple, the crust would be thinner than the apple's skin. Everything humans have ever built, mined, or explored sits on this impossibly thin shell floating on a sea of hot rock.

Scale check: The deepest mine in the world (Mponeng Gold Mine in South Africa) goes down 4 km. The deepest ocean point (Mariana Trench) is 11 km. Earth's radius is 6,371 km. We've barely scratched the surface — literally.

Plate Tectonics — The Moving Puzzle

Earth's crust isn't one solid piece. It's cracked into about 15 major plates that float on the slow-moving mantle — drifting a few centimetres per year, about as fast as your fingernails grow.

The Big Idea

The ground beneath your feet is moving right now

Tectonic plates are enormous slabs of crust (and upper mantle) that fit together like a jigsaw puzzle. They're constantly moving, driven by heat currents in the mantle below — hot rock rises, spreads sideways, cools, and sinks back down. This slow circulation is called convection.

It's the same thing you see when you heat soup in a pot — the hot soup rises in the middle, flows outward along the top, cools at the edges, and sinks back down. Earth's mantle does this, but over millions of years and with rock instead of soup.

These convection currents drag the plates along on top, like conveyor belts. Where plates interact, the most dramatic geology on Earth happens: mountains, volcanoes, earthquakes, and ocean trenches.

Proof it works: 200 million years ago, all continents were joined in one supercontinent called Pangaea. You can see it today — the east coast of South America fits almost perfectly into the west coast of Africa, like puzzle pieces. They even share the same fossils and rock types along those edges!

Three Types of Plate Boundaries

Click each to learn what happens

Divergent — Pulling Apart

↔ Plates move away from each other

Magma rises from below to fill the gap, creating new crust. This is happening right now in the middle of the Atlantic Ocean, at the Mid-Atlantic Ridge — the longest mountain range on Earth, running 16,000 km along the ocean floor.

Iceland sits directly on top of the Mid-Atlantic Ridge — it's literally being torn in two, growing about 2.5 cm wider every year. You can visit Thingvellir National Park and stand in the crack between the North American and Eurasian plates!

In East Africa, the continent is slowly splitting apart along the East African Rift. In tens of millions of years, East Africa will separate from the rest of the continent, forming a new ocean.

New land being born: In 1963, a volcanic eruption on the Mid-Atlantic Ridge created a brand new island off Iceland's coast: Surtsey. Scientists watched an entire island form from nothing in just a few years.

Convergent — Pushing Together

→← Plates collide into each other

When two plates push together, one slides underneath the other (subduction) or they crumple upward. This creates the most violent geology on Earth: deep ocean trenches, explosive volcanoes, and the tallest mountains.

Ocean plate vs continental plate: The heavier ocean plate dives under the lighter continental plate. This creates deep trenches (like the Mariana Trench — 11 km deep!) and volcanic mountain chains (like the Andes).

Continental plate vs continental plate: Neither can dive under the other, so they crumple upward like two cars in a head-on collision. This is how the Himalayas formed — India is still pushing into Asia, and the mountains are still growing about 5 mm per year!

Mind-blowing: The rock at the top of Mount Everest is limestone — made from the shells of ancient sea creatures. It was once at the bottom of the ocean! The collision between India and Asia pushed it nearly 9 km into the sky.

Transform — Sliding Past

↑↓ Plates grind sideways past each other

No crust is created or destroyed — the plates just scrape past each other. This builds up enormous stress that gets released suddenly as earthquakes. The San Andreas Fault in California is the most famous example.

Transform boundaries don't produce volcanoes (no magma is involved), but they produce some of the most devastating earthquakes. The plates don't slide smoothly — they lock up, stress builds, then they suddenly lurch. That sudden lurch is an earthquake.

Los Angeles (on the Pacific Plate) is slowly moving northwest toward San Francisco (on the North American Plate) at about 5 cm per year. In about 15 million years, they'll be neighbours!

Try this at home: Put your hands flat on a table and push them sideways past each other. They don't slide smoothly — they stick, build pressure, then suddenly slip. That jolt is exactly how earthquakes work at transform boundaries.

How fast do plates move?

Earthquakes & Volcanoes

Earthquakes and volcanoes aren't random — they happen at plate boundaries. Plot every earthquake and volcano on a map and you'll see the outlines of the tectonic plates appear, clear as day.

How Earthquakes Work

Stress → snap → shaking

Tectonic plates move slowly but they don't slide smoothly past each other. They lock up. Stress builds for years, decades, or centuries. Then suddenly — SNAP — the rocks break and lurch, sending shockwaves through the ground. That's an earthquake.

The point underground where the rock actually breaks is called the focus (or hypocentre). The point on the surface directly above it is the epicentre — where the shaking is strongest.

Earthquakes produce different types of waves. P-waves (primary) are compression waves — they push and pull rock like a slinky. They travel fastest and arrive first. S-waves (secondary) move rock side to side, like shaking a rope. They're slower but more destructive. S-waves can't travel through liquid — which is how we know Earth's outer core is liquid (S-waves disappear when they hit it).

The Ring of Fire: About 90% of all earthquakes and 75% of all volcanoes happen around the Pacific Ocean, in a horseshoe-shaped zone called the Ring of Fire. It follows the edges of the Pacific Plate, which is being subducted under the surrounding plates. Japan, Indonesia, Chile, and the US west coast all sit on it.

The Richter Scale — How Big Is That Earthquake?

Each step is 10× more ground movement and ~32× more energy!

Magnitude: 5.0

How Volcanoes Work

When rock melts and finds a way out

Volcanoes form when magma (molten rock from the mantle) reaches the surface. This mostly happens at plate boundaries — either where plates pull apart (magma fills the gap) or where one plate dives under another (the sinking plate melts, and the magma rises).

Not all volcanoes are the same. Shield volcanoes (like Hawaii) have gentle slopes and produce flowing lava — relatively safe and predictable. Stratovolcanoes (like Mount Vesuvius, Mount St. Helens) are steep, explosive, and dangerous — they can blast ash 20 km into the sky.

There are also "hotspot" volcanoes that aren't at plate boundaries at all. Hawaii sits in the middle of the Pacific Plate, over a hotspot — a plume of extra-hot mantle that melts through the plate. As the plate moves over the hotspot, it creates a chain of islands. The Big Island is currently over the hotspot; a new island (Lōʻihi) is already forming underwater to the southeast.

Supervolcanoes: Yellowstone National Park sits on top of a massive magma chamber. Its last super-eruption (640,000 years ago) ejected 1,000 km³ of material — enough to bury a large country in metres of ash. It will erupt again someday, but likely not for tens of thousands of years.

Key Concept — Seismic Waves as X-Rays

Seismologists use earthquake waves the same way doctors use X-rays — to see inside something you can't cut open. By tracking how P-waves and S-waves travel through Earth (where they speed up, slow down, bend, or disappear), scientists have mapped every layer of Earth's interior. The discovery that the outer core is liquid came from noticing that S-waves can't pass through it — they create a "shadow zone" on the opposite side of Earth from an earthquake.

Earth's Magnetic Field — Our Invisible Shield

Deep inside Earth, rivers of liquid iron flow in the outer core. This flowing metal generates a magnetic field that extends far into space — and it protects everything alive on the surface.

The Dynamo

A giant electromagnet powered by liquid metal

Earth's magnetic field is generated by the flow of liquid iron in the outer core — a process called the geodynamo. The iron is kept liquid by the immense heat from the inner core. As it flows, it creates electric currents, which produce the magnetic field. It's the same basic principle as an electromagnet, just on a planetary scale.

The magnetic field extends tens of thousands of kilometres into space, forming a protective bubble called the magnetosphere. It deflects the solar wind — a constant stream of charged particles blasted out by the Sun at 400+ km/s.

Without the magnetosphere, the solar wind would slowly strip away Earth's atmosphere. This is exactly what happened to Mars — it lost its magnetic field about 4 billion years ago (its core cooled and solidified), and the solar wind gradually eroded its atmosphere. Mars went from having a thick atmosphere and liquid water to the thin, cold, dry world it is today.

Compasses work because of this! A compass needle is a tiny magnet that aligns with Earth's magnetic field, pointing roughly toward the magnetic poles. Humans have used this for navigation for over 1,000 years — all thanks to rivers of molten iron 3,000 km beneath our feet.

Flipping Out

The magnetic poles have swapped hundreds of times

Earth's magnetic field isn't permanent — it flips! On average every 200,000–300,000 years, the north and south magnetic poles switch places. The last flip was about 780,000 years ago, so we're actually overdue.

We know this from the ocean floor. As new rock forms at mid-ocean ridges, iron minerals in the cooling lava align with the current magnetic field and get "frozen" in place. Scientists found alternating stripes of normal and reversed magnetism in the seafloor — a record of every flip going back millions of years.

A flip doesn't happen overnight — it takes 1,000–10,000 years. During the transition, the field gets weaker and more chaotic, with multiple north and south poles. This could increase radiation exposure on the surface, but it's happened hundreds of times before and life survived every one.

Right now: The magnetic north pole is moving! It drifted slowly from northern Canada for centuries, but since the 1990s it's been racing toward Siberia at about 50 km per year. Nobody is entirely sure why.

Light Show

The Northern and Southern Lights

The aurora borealis (north) and aurora australis (south) are caused by charged particles from the solar wind that slip past the magnetosphere near the poles and collide with gas molecules in the upper atmosphere, making them glow.

Different gases produce different colours. Oxygen at high altitudes produces green and red. Nitrogen produces blue and purple. The particles are channelled toward the poles by the magnetic field lines — which is why auroras are seen near the Arctic and Antarctic circles.

During strong solar storms, auroras can be seen much farther from the poles — they've been observed as far south as Mexico and as far north as Antarctica.

Auroras happen on other planets too! Jupiter and Saturn have spectacular auroras driven by their own magnetic fields. Jupiter's are thousands of times more powerful than Earth's.

Activity — Visualise Magnetic Field Lines

Place a bar magnet under a sheet of paper. Sprinkle iron filings on top and gently tap. The filings arrange themselves along the magnetic field lines, showing the invisible field. Earth's field looks like a much larger version of this — field lines emerging from the south, looping through space, and entering at the north.

Geophysics Beyond Earth

Every rocky planet and moon has its own geophysics story. Comparing them to Earth helps us understand why our planet is so special — and what we might find elsewhere.

Mars

The planet that lost its shield

Mars once had a magnetic field, a thick atmosphere, rivers, and possibly oceans. Then its core cooled, the dynamo stopped, and the solar wind stripped away the atmosphere. It's a cautionary tale about what happens when a planet's geophysics shuts down.

Mars is smaller than Earth, so it lost its internal heat faster. Its core solidified, ending the magnetic field. Without magnetic protection, the solar wind hammered the atmosphere, and with a thinner atmosphere, temperatures dropped and water either froze underground or escaped to space.

But Mars isn't entirely "dead" — there may still be liquid water underground, and volcanic features suggest eruptions occurred as recently as a few million years ago.

The lesson: Mars shows that a planet's surface habitability depends on what's happening thousands of kilometres below. Interior geophysics literally determines whether a planet can support life.

Venus

The planet with no plate tectonics

Venus is almost Earth's twin in size, but it has no plate tectonics. Without plates recycling carbon, CO₂ built up in the atmosphere, creating a runaway greenhouse effect (465°C surface temperature). It may periodically "resurface" itself with massive global volcanic eruptions instead.

On Earth, plate tectonics acts as a thermostat: volcanoes release CO₂ (warming), while weathering of silicate rocks absorbs CO₂ (cooling). This cycle regulates temperature over millions of years. Venus doesn't have this cycle.

Why no plates? Venus may be too hot for its crust to crack into plates (the rock is too soft), or it may lack the water that lubricates plate movement on Earth. Water turns out to be essential for plate tectonics — it weakens rock and helps subduction zones work.

Jupiter's Moon Io

The most volcanically active body in the Solar System

Io has over 400 active volcanoes — more than any other object we know of. Its interior is kept molten not by radioactive decay (like Earth) but by tidal heating: Jupiter's immense gravity flexes Io like a stress ball, generating heat through friction.

Io orbits Jupiter so closely that the gravitational tidal forces literally squeeze and stretch it. The other large moons (Europa, Ganymede) create orbital resonances that keep Io's orbit slightly elliptical, maintaining the flexing. This pumps enormous energy into Io's interior, keeping it volcanically hyperactive.

Tidal heating also creates oceans: The same tidal flexing that melts Io's interior is gentler on Europa (farther from Jupiter). There, it's just enough to maintain a liquid water ocean under the ice shell — making Europa one of the best candidates for extraterrestrial life.

Key Concept — Why Geophysics Matters for Life

For a planet to support life (as we know it), it needs: a magnetic field (to protect the atmosphere), plate tectonics (to regulate temperature and recycle chemicals), and internal heat (to drive both). Earth has all three. Mars lost its heat. Venus lost its plates. Understanding geophysics is understanding what makes a planet habitable.