This unit explores Performance Expectations MS- ESS3-2, ESS2-3 and ETS1-4 by engaging students in Project-Based learning to develop a community presentation that examines whether your community is ready to respond to a major tectonic event.

In this activity, students will learn about the Richter Scale for measuring earthquakes. The students will make a booklet with drawings that represent each rating of the Richter Scale.

In this activity, students will learn about the Mercalli Scale for rating earthquakes. Also, students will make a booklet with drawings that represent each rating of the scale.

Students learn about the remote sensing radio occultation technique and how engineers use it with GPS satellites to monitor and study the Earth's atmospheric activity. Students may be familiar with some everyday uses of GPS, but not as familiar with how GPS technology contributes to our ongoing need for great amounts of ever-changing global atmospheric data for accurate weather forecasting, storm tracking and climate change monitoring. GPS occultations are when GPS signals sent from one satellite to another are altered (delayed, refracted) by the atmosphere passed though, such that they can be analyzed to remotely learn about the planet's atmospheric conditions.

Wildfires are a contributing factor to greenhouse gas emissions. Scientists estimate that wildfires emitted 8 billion tons of CO2 per year for the past 20 years. Wildfires have risks and benefits that humans are impacted by. In this storyline, students will learn about the risks and benefits of wildfires, the science behind how fire occurs and the conditions that make a fire catastrophic. Students will evaluate local/regional fires to determine how human activities contribute to wildfires. Students will research how forest management decisions are made to decrease the negative impacts of wildfires and to decrease the amount of CO2 that is emitted from those fires. 

Sea level is rising due to climate changes that result from increased emissions of greenhouse gases. In this storyline, students will explore mechanisms of sea level rise and the impacts on Indigenous peoples along with other groups such as urban communities. Natural hazards such as erosion, storm surges, and flooding are intensified by sea level rise. The effects on natural resources, the economies built from those natural resources, and land usage in general can be predicted by utilizing current and historical data.

Los incendios forestales son un factor que contribuye a las emisiones de gases de efecto invernadero. Los científicos estiman que los incendios forestales emitieron 8 mil millones de toneladas de CO2 por año durante los últimos 20 años. Los incendios forestales tienen riesgos y beneficios que afectan a los seres humanos. En este caso, los estudiantes aprenderán sobre los riesgos y beneficios de los incendios forestales, la ciencia detrás de cómo ocurren los incendios y las condiciones que hacen que un incendio sea catastrófico. Los estudiantes evaluarán los incendios locales / regionales para determinar cómo las actividades humanas contribuyen a los incendios forestales. Los estudiantes investigarán cómo se toman las decisiones de manejo forestal para disminuir los impactos negativos de los incendios forestales y disminuir la cantidad de CO2 que se emite por esos incendios.

SYNOPSIS: In this lesson, students engage in activities and experiments to explore the concept of physical changes, and apply their learning to understand climate change-induced sea level rise.

SCIENTIST NOTES: The lesson introduces students to the physical changes of state from solid-liquid-gaseous phase. All materials, including artcicles and simulations, are well-sourced and relevant to improve students' ability in understanding the impact of physical changes in ice caps and its ambient environment and how they could take action to limit these changes. This lesson has passed our science credibility process and is recommended for teaching.

Positive

-Students work collaboratively in groups and with partners to share diverse ideas and perspectives.
-Students participate in hands-on learning to aid in understanding and participation.
-Students learn through a variety of pathways including kinesthetic, auditory, visual, etc. to engage with different learning.
-Students are given a variety of optional extensions to create the most meaningful change in their communities.

ADDITIONAL PREREQUISITES:
-It is recommended that teachers use this as a multi-day lesson in 5 parts. Use the Multi-Day Schedule Visual to determine appropriate stopping points for each day.
-Materials needed for the Physical Change Activity include the following:
-Ice
-Cup
-Playdough (one container per group)
-Different shaped cookie cutters (two per group)
-Materials needed for each group for the Investigate section experiment include the following:
-Two identical, clear, plastic containers (e.g., 6x6 inches)
-Clay, playdough, or small rocks
-Tray of ice cubes
-Ruler
-Cold water
-Piece of paper
-Permanent marker (optional)
-Materials may be substituted as necessary
-Students must create free accounts on the CK-12 website to participate in the simulations.

DIFFERENTIATION:
-All activities, experiments, and simulations can be completed in differentiated groups or as demonstrations at the discretion of the teacher.
-The article may be read aloud in groups or as a class to aid in understanding at the discretion of the teacher.
-Student Document questions may be completed individually, in mixed ability groups, or as a whole group led by the teacher.
-Videos may be paused and discussed in short segments.
-As noted in the TED video, the economic influences on climate change cannot be ignored. An extension to this lesson may be to include a social studies educator to teach students about the local economic elements and issues that contribute to climate change.

Remote Sensing is the gathering of data remotely. This data is gathered from satellites, airplanes, and even drones flying through hurricanes.

Travel to the Pacific Northwest, home to some of the most seismically active areas in the U.S. Learn from experts about tectonic activity and find out if they know when the "big one” will hit.

Students learn about seismology by using a sample seismograph constructed out of common classroom materials. The seismograph creates a seismogram based on vibrations caused by moving a ruler. The students work in groups to represent an engineering firm that must analyze the seismograph for how it works and how to read the seismogram it creates.

Students learn about tornadoes, the damage they cause, and how to rate tornadoes. Specifically, students investigate the Enhanced Fujita Damage Scale of tornado intensity, and use it to complete a mock engineering analysis of damage caused by a tornado. Additional consideration is given to tornado warning systems and how these systems can be improved to be safer. Lastly, students learn basic tornado safety procedures.

Students will analyze data of tornadoes throughout the United States. They will create a bar graph of the number of tornadoes for the top ten states in the country and then calculate the median and the mode of the data.

Students learn about tsunamis, discovering what causes them and what makes them so dangerous. They learn that engineers design detection and warning equipment, as well as structures that that can survive the strong wave forces. In a hands-on activity, students use a table-top-sized tsunami generator to observe the formation and devastation of a tsunami. They see how a tsunami moves across the ocean and what happens when it reaches a coastline. They make villages of model houses to test how different material types are impacted by the huge waves.

There is a 40% chance that the lower ⅓ of the of the Cascadia subduction zone will rupture in the next 50 years, generating a large earthquake and ensuing tsunami. In this project, students will work collaboratively to design and test a model of a vertical evacuation structure. They will evaluate the performance of their models and propose further modifications to improve their design. Students will then make a scale drawing and a model to apply math concepts of scale to designing and creating an ideal model of a vertical evacuation structure. Finally, students will present their findings and proposed final design to their peers and an adult audience. The entire process takes about 2 weeks, and was expanded to include more information and activities with earthquake/tsunami prediction and application of scale. The unit is a great fit for standards within Earth Science (specifically plate tectonics and human mitigation) as well as Engineering and Design standards.

This activity examines the impacts of hurricanes and storm surges on coastal communities.

So what exactly can be be captured from space and how is satellite imagery being used today?

Students will be exploring the idea of ecosystems and wildfires. They will become familiar with what an ecosystem is and how to keep them healthy. Students will also see the positive and negative effects of wildfires on ecosystems. Also how wildfires influence the local government and federal government when it comes to land management.

In this activity, students will learn about how tornadoes are formed and what they look like. By creating a water vortex in a soda bottle, they will get a first-hand look at tornadoes.