13 Unit 3: Earthquakes, Volcanoes & Tsunamis

14 🌋 Unit 3: Earthquakes, Volcanoes & Tsunamis

Why do earthquakes, volcanoes, and tsunamis occur where they do — and can we predict them?

14.1 Anchor Phenomenon

On August 27, 1883, the volcanic island of Krakatoa in Indonesia exploded with the force of 10,000 atomic bombs. The sound was heard 4,800 km away in Australia. The eruption triggered tsunamis up to 30 meters high that killed over 36,000 people. Ash circled the globe, lowering world temperatures for years.

Why do massive volcanic eruptions, earthquakes, and tsunamis happen? Why do they occur in certain places but not others? And is there anything we can do to protect ourselves?

14.2 Driving Question

Why do earthquakes, volcanoes, and tsunamis occur where they do — and how can humans prepare for and minimize the damage from these natural hazards?

14.3 Performance Expectations

HS-ESS1-5 HS-ESS2-1 HS-ESS2-3 HS-ESS3-1

Standard	Description
HS-ESS1-5	Evaluate evidence of the past and current movements of continental and oceanic crust
HS-ESS2-1	Develop a model to illustrate how Earth’s internal and surface processes operate at different spatial and temporal scales to form features and features
HS-ESS2-3	Develop a model based on evidence of Earth’s interior to describe cycling of matter by convection
HS-ESS3-1	Construct an explanation based on evidence for how natural hazards have shaped the development of human civilizations

14.4 Lesson Sequence

Chapter	Topic	Key Questions	Time
Opening	🌋 The Krakatoa Enigma	Why do massive eruptions happen? Can we predict them?	2 days
Chapter 1	🔬 Earth's Interior	How do we know what's inside Earth if we've never been there?	7-8 days
Chapter 2	🗺️ Surface Features & Plate Boundaries	Why do earthquakes and volcanoes form patterns on a map?	7-8 days
Chapter 3	⚡ Energy & Matter in Earth's Interior	What drives plate movement? Where does the heat come from?	7-8 days
Closing	🏗️ Hazard Risk Assessment	How can we minimize the damage from natural hazards?	2 days

14.5 Learning Objectives

By the end of this unit, you will be able to:

Explain how we know about Earth’s interior structure using seismic wave evidence
Describe how density differences created Earth’s layered structure
Identify plate boundary types and explain the geological features at each
Model how convection in the mantle drives plate tectonics
Evaluate evidence for continental drift and seafloor spreading
Construct explanations for why natural hazards occur where they do
Develop a risk assessment and mitigation plan for a real location
Argue whether a location’s natural hazard risk outweighs its resource benefits

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