📖 Lesson 29 ⏱ ~30 min Year 8 · Unit 3 ⚡ +115 XP

The Fossil Record and Evolution

In 1909, Charles Doolittle Walcott discovered the Burgess Shale in Canada, revealing 508-million-year-old soft-bodied creatures perfectly preserved, rewriting our understanding of animal evolution.

Today's hook: In 1909, Smithsonian palaeontologist Charles Doolittle Walcott stumbled upon the Burgess Shale in British Columbia, 508-million-year-old mudstone containing thousands of soft-bodied animals that normally never fossilise. The site revealed over 65,000 specimens and rewrote our picture of early animal evolution. Scientists estimate that 99% of all species that have ever lived are now extinct. What does this fossil graveyard tell us, and what can it predict about life today?

0/5QUESTS

Warm-up

Think First

+5 XP each

When an animal dies in a forest, what usually happens to its body? Under what conditions do you think the body might be preserved as a fossil instead?

Scientists say we are currently in a "sixth mass extinction" caused by human activities. How do they know past mass extinctions happened? What evidence would they look for in rocks?

Learning objectives

What you'll master

3 areas

● Know

The four main types of fossil formation: permineralisation, moulds/casts, amber, carbonisation
What an index fossil is and why it is useful
The two major mass extinction events: Permian-Triassic (252 Ma) and K-Pg (66 Ma)

● Understand

How the fossil record provides evidence for evolution and gradual species change
Why transitional fossils (Archaeopteryx, Tiktaalik) are significant
How mass extinctions actually drive diversification in surviving lineages

● Can do

Evaluate which fossil type would make the best index fossil and explain why
Describe the cause and scale of both major mass extinctions
Explain how the fossil record supports evolutionary theory

Vocabulary · tap to flip

Words You Need

8 terms

Core term Concept Skill Reference

Permineralisation

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Permineralisation

The most common fossil type: minerals from groundwater fill the porous spaces in buried bone, shell, or wood, replacing organic matter with rock.

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Index fossil

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Index fossil

A fossil from a species that lived for a short time but was widespread geographically. Finding it precisely dates the rock layer it is found in.

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Transitional fossil

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Transitional fossil

A fossil that shows features intermediate between an ancestral group and its descendants, demonstrating the gradual change of species over time.

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Mass extinction

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Mass extinction

A rapid and widespread decrease in biodiversity, where a large percentage of Earth's species disappear within a geologically short time (thousands to millions of years).

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Permian-Triassic extinction

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Permian-Triassic extinction

"The Great Dying" (~252 Ma): the largest mass extinction, eliminating ~96% of marine species and ~70% of terrestrial vertebrate species. Caused by Siberian Traps volcanism and resulting climate disruption.

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K-Pg extinction

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K-Pg extinction

The Cretaceous-Paleogene extinction (~66 Ma): caused by the Chicxulub asteroid impact (Mexico). Non-avian dinosaurs went extinct; mammals and birds diversified. K = Cretaceous; Pg = Paleogene.

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Carbonisation

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Carbonisation

A fossil type where organic material is compressed under pressure, leaving a thin carbon film impression. Common for leaves and soft-bodied organisms.

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Archaeopteryx

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Archaeopteryx

A ~150 Ma transitional fossil showing features of both dinosaurs (teeth, clawed wings, long bony tail) and birds (feathers, wishbone). Key evidence for bird evolution from theropod dinosaurs.

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Cross-lesson links: The fossil record is inseparable from the geological timescale in Lesson 1, fossils are one of the key tools scientists use to date rock layers. It also connects to Lesson 4, where shifts in the fossil record during ice ages reveal how species responded to past climate change, and to Lesson 16, where the rarity of complex life is discussed in a cosmic context.

Core learning

From death to discovery

How Fossils Form

+5 XP

In the Flinders Ranges of South Australia, hikers regularly find rocks imprinted with the curved outlines of Dickinsonia, oval, ribbed creatures that lived 560 million years ago, long before animals evolved hard shells. Those impressions exist because the organisms happened to be buried rapidly in fine seafloor sediment before they could decompose. Fossilisation is rare for exactly this reason, most organisms decompose entirely after death, leaving no trace, and only under specific conditions does a fossil form. There are four main types:

1. Permineralisation: The most common type. After burial in sediment, groundwater carrying dissolved minerals percolates through the porous spaces of bone, wood, or shell. The minerals precipitate, gradually replacing organic material with rock. The result preserves the original structure in rock. Most dinosaur fossils are permineralised.

2. Moulds and casts: The organism is buried and later dissolves, leaving a hollow mould in the rock. If minerals then fill the mould, a cast forms, a replica of the original organism. Fossils of soft-bodied organisms like jellyfish often form this way.

3. Amber preservation: Organisms (typically insects, spiders, small plants) become trapped in tree resin. The resin hardens over millions of years into amber, preserving the organism in extraordinary detail, sometimes including DNA fragments. Amber fossils give us unparalleled views of ancient insects and small organisms.

4. Carbonisation: Organic matter is compressed under high pressure, with gases and liquids squeezed out, leaving a thin carbon film on rock. Leaves and soft-bodied organisms are often preserved this way. Coal itself forms from carbonised plant material.

Why fossilisation is rare: Hard body parts (bones, shells) preserve far better than soft tissue. Organisms must be buried quickly (usually in sediment) before decomposition. This means organisms in rivers, lakes, and shallow seas are much more likely to fossilise than forest or savannah animals, creating a strong bias in the fossil record toward aquatic life.

Real-world anchor

Australian fossil sites: The Naracoorte Caves World Heritage Site (SA) is one of Australia's richest fossil deposits, containing the bones of extinct megafauna including giant wombats (Diprotodon), Tasmanian tigers (Thylacosmilus), and massive short-faced kangaroos (Procoptodon). These animals fell into natural cave traps over hundreds of thousands of years, and their bones have been preserved in extraordinary abundance. The site gives us a window into Australia's Pleistocene megafauna before their extinction (~46,000 years ago).

Which of the following organisms would be BEST suited to become an index fossil?

Reading the story of life

The Fossil Record as Evidence for Evolution

+5 XP

The fossil record is one of the most powerful lines of evidence for evolution. Reading through rock layers is like reading a history book of life, where each layer represents a snapshot of which species existed at a particular time.

What the fossil record shows:

Species change gradually over time, populations in younger rock layers often look slightly different from those in older layers
New, more complex body plans appear over geological time
Species that went extinct do not reappear in younger layers
Closely related species appear in nearby rock layers

Transitional fossils are particularly important, they show features intermediate between an ancestral group and its descendants:

Archaeopteryx (~150 Ma, Jurassic Germany): Shows a mix of dinosaur features (teeth, clawed wings, long bony tail) and bird features (feathers, wishbone, flight-capable anatomy). It is strong evidence that birds evolved from theropod dinosaurs.

Tiktaalik (~375 Ma, Devonian): A "fishapod" showing the transition from fish to land-dwelling tetrapods. It had fish-like scales and fins, but also a neck (unique among fish), ribs, and primitive limb-like fins with wrists that could support its weight on land. Found in Canada, Tiktaalik was predicted by evolutionary theory before it was discovered.

Geographic distribution: Related fossils found on continents that were once joined (e.g., Gondwana marsupials found across South America, Antarctica, and Australia) provide combined evidence for both evolution and continental drift.

Example

Australia's fossil marsupials beautifully illustrate both evolution and biogeography. When Australia separated from Gondwana ~45 Ma ago, its marsupials evolved in isolation, producing a remarkable diversity: wombats, kangaroos, possums, quolls, and the extinct Diprotodon (giant wombat, rhino-sized). Many Australian marsupials show convergent evolution with placental mammals elsewhere, the Tasmanian tiger (thylacine) looked remarkably similar to a wolf despite being more closely related to kangaroos. The fossil record shows this divergence gradually through rock layers.

Two truths, one lie+5 XP

Which ONE of the following statements about mass extinctions is FALSE?

When life nearly ended

Mass Extinctions and Recovery

+5 XP

Earth has experienced at least five major mass extinctions. Two dominate:

Permian-Triassic Extinction ("The Great Dying", ~252 Ma):

Scale: ~96% of marine species extinct; ~70% of terrestrial vertebrate species extinct
Cause: The Siberian Traps, a colossal eruption of flood basalts in what is now Russia. Over ~2 million years, eruptions released enormous amounts of CO₂ (causing rapid warming), sulfur dioxide (causing acid rain), and methane from ignited coal seams. The combination disrupted the carbon cycle and ocean chemistry globally.
Duration: ~60,000 years for the main pulse; ~5 million years for ecosystems to stabilise

Cretaceous-Paleogene Extinction (K-Pg, ~66 Ma):

Scale: ~76% of all species extinct, including all non-avian dinosaurs
Cause: The Chicxulub impactor, an asteroid ~10 km in diameter struck the Yucatan Peninsula (Mexico) at ~72,000 km/h. The impact triggered massive fires, tsunamis, and a global "impact winter": dust and sulfate aerosols blocked sunlight for months to years, collapsing photosynthesis and food chains globally
Evidence: A global iridium-rich layer (iridium is rare on Earth's surface but common in asteroids) found at the K-Pg boundary worldwide
Survivors and winners: Birds (avian dinosaurs), mammals, crocodilians, and many plant groups survived. Mammals diversified explosively in the Cenozoic

Key insight: Mass extinctions, while catastrophic, create ecological opportunities. The extinction of non-avian dinosaurs opened niches that mammals diversified into, eventually producing humans. Extinction drives evolution.

Watch out

Biodiversity recovery after a mass extinction takes millions of years, not thousands. After the K-Pg extinction, it took approximately 10 million years for marine ecosystems to recover fully and ~25 million years for tropical forests to recover. The K-Pg was "fast" by geological standards (a sudden spike in extinctions), but the recovery was slow. Current extinction rates are estimated at 100–1,000 times background levels, far faster than any previous mass extinction except the K-Pg itself.

The Permian-Triassic extinction was caused by the same mechanism as the K-Pg extinction, both were triggered by large asteroid impacts. True or false?

Activities

From the lesson

Activity 1

Fossil Type Analysis

For each organism described, predict which fossil type is most likely and explain your reasoning.

1 A large dinosaur that died on the bank of a prehistoric river and was quickly buried in floodplain sediment

2 A small spider walking across a pine tree that was oozing resin 100 million years ago

3 A fern leaf that fell into a swamp and was compressed under layers of sediment over millions of years

From the lesson

Activity 2

Comparing Mass Extinctions

Complete this comparison table by writing a brief answer for each cell.

1 What was the primary cause of the Permian-Triassic extinction?

2 What was the primary cause of the K-Pg extinction?

3 Which extinction was larger in scale? Cite the evidence (% species lost).

4 What group of organisms benefited most from the K-Pg extinction, and why?

Predict then reveal+8 XP

1 · Predict

2 · Reveal

3 · Compare

Scientists claim birds are living dinosaurs, specifically, that modern birds are avian theropod dinosaurs that survived the K-Pg extinction. What evidence from the fossil record would support this claim? Write your prediction before reading the reveal.

Confidence 50%

Reflect

Revisit your thinking

reflect

The hook asked: "99% of all species that have ever lived are now extinct, what can the fossil record tell us about the future?" Now that you've studied mass extinctions, answer this question with evidence from the lesson.

Interactive Tool, Evolution Timeline Open fullscreen ↗

Use the Evolution Timeline. Fossils provide evidence for evolution because they show:

Quick check · multiple choice

Quick check

Why is permineralisation the most common type of fossil preservation?

+10 XP

Quick check

For an organism to be useful as an index fossil, it must be:

+10 XP

Quick check

Archaeopteryx is described as a transitional fossil. What makes it "transitional"?

+10 XP

Quick check

A geologist finds a thin layer of iridium-enriched clay sandwiched between Cretaceous and Paleogene rock layers worldwide. What is the most likely explanation?

+10 XP

Quick check

Why does the fossil record show a strong bias toward marine organisms with hard shells?

+10 XP

MC complete

Ready for short answers

Short answer

Short answer · explain in your own words

Show your reasoning

3 questions

UnderstandCore4 marks

Q1. Explain how the fossil record provides evidence for evolution. Use at least ONE specific example of a transitional fossil in your answer.

ApplyCore4 marks

Q2. Compare the Permian-Triassic extinction and the K-Pg extinction. Your answer should address: (a) the scale of each extinction, (b) the cause of each, and (c) one way they differed.

AnalyseCore4 marks

Q3. A student says: "Mass extinctions are always bad for life on Earth." Evaluate this statement using evidence from the lesson. Do you agree or disagree?

Reflect

Revisit Your Thinking

The hook asked whether the fossil record, "basically a graveyard", can tell us anything about the future. What is your answer now?

Model answers (click to reveal)

Answers

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MCQ 1

C. Groundwater containing dissolved minerals percolates through the porous structure of buried bone or shell, depositing minerals that gradually replace the organic material. This is why hard-bodied organisms buried in sediment preserve so well.

MCQ 2

A. An index fossil must be geographically widespread (so it can be found on multiple continents to correlate rock layers) and short-lived as a species (so it pins the rock layer to a narrow time window). Long-lived species are useless as time markers.

MCQ 3

D. Archaeopteryx (150 Ma) is "transitional" because it shows features intermediate between two groups: dinosaur features (teeth, clawed wings, long bony tail) and bird features (feathers, wishbone, flight anatomy). It documents the evolutionary transition between theropod dinosaurs and modern birds.

MCQ 4

B. Iridium is rare in Earth's surface rocks but is common in asteroids. A global iridium-rich layer at a specific geological boundary worldwide is powerful evidence that a large asteroid impacted Earth at that time, distributing iridium globally via the impact plume and ejecta cloud.

MCQ 5

A. Marine organisms with hard shells (like ammonites, bivalves, foraminifera) are rapidly buried in fine-grained ocean sediment and their mineralised shells resist decomposition. Land animals in forests rarely get buried quickly, they decompose. This creates a strong bias in the fossil record.

Short Answer 1

Model answer: The fossil record provides evidence for evolution in several ways. First, organisms in younger rock layers tend to look slightly different from those in older layers, populations change gradually over time. Second, extinct species do not reappear in younger layers, consistent with irreversible evolutionary change. Third, transitional fossils document the actual intermediate forms between ancestral and descendant groups. For example, Archaeopteryx (150 Ma) has both dinosaur features (teeth, clawed wings, long bony tail) and bird features (feathers, wishbone). It shows that birds did not appear suddenly but evolved gradually from theropod dinosaurs, exactly as evolutionary theory predicts.

Short Answer 2

Model answer: (a) Scale: The Permian-Triassic was larger, eliminating ~96% of marine species and ~70% of terrestrial vertebrates. The K-Pg eliminated ~76% of all species. (b) Cause: Permian-Triassic was caused by the Siberian Traps volcanism, massive flood basalt eruptions over ~2 million years releasing CO₂, SO₂ and CH₄. The K-Pg was caused by the Chicxulub asteroid impact (~10 km diameter) that triggered fires, tsunamis, and a global impact winter. (c) Key difference: The Permian-Triassic was a prolonged event driven by slow volcanic processes over millions of years; the K-Pg was a sudden event with the initial impact occurring on a single day, though its environmental effects lasted years. The Permian-Triassic also affected marine and terrestrial ecosystems more symmetrically.

Short Answer 3

Model answer: I partially disagree. Mass extinctions are certainly catastrophic for the species going extinct, the Permian-Triassic eliminated 96% of marine species, and recovery took millions of years. In that sense, they are devastating. However, mass extinctions also create ecological opportunities for surviving lineages. The K-Pg extinction eliminated all non-avian dinosaurs, which had dominated terrestrial ecosystems for 165 million years. This freed ecological niches that mammals (previously small and nocturnal) could occupy. The explosive diversification of mammals in the Cenozoic, producing whales, bats, horses, elephants, primates, and ultimately humans, was made possible by the dinosaur extinction. Without the K-Pg extinction, mammals might never have diversified, and humans would likely not exist. So mass extinctions are catastrophic for existing species but can be enabling for future ones.

Quick-fire challenge

Game time

+25 XP

Mark lesson as complete

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