This interactive visualization explains the chemical relationship between carbon dioxide, shell building, and ocean acidification.

SYNOPSIS: In this lesson, students think critically about carbon emission reduction strategies proposed by companies.

SCIENTIST NOTES: This lesson challenges students to analyze "green" claims and provides context to "net zero" greenhouse gas emission goals. Students are tasked with evaluating a company’s sustainability plan and then presenting their findings to classmates. The included video resources are well-sourced and highlight how greenwashing can mislead consumers and how "net zero" emission goals are often just a way for corporations to procrastinate on taking meaningful steps to mitigate climate change. This lesson is recommended for teaching.

POSITIVES:
-Students will be assessing the validity of sustainability plans within companies which helps with critical thinking skills.
-Students become more informed consumers.

ADDITIONAL PREREQUISITES:
-Teachers should try to find their school or Board of Education’s sustainability policy prior to class.
-Teachers should be familiar with what a sustainability plan looks like.

DIFFERENTIATION:
-Students may need help with research techniques. Teacher could give five options for students to choose from, and the students pick a company from those five options.
-Students may need help picking a company to research. Students can focus on companies where they spend money, either online or in their neighborhood.

In this video segment adapted from NOVA, find out how cars made of a material stronger than steel and half the weight can help combat climate change.

In this lesson, students calculate their own carbon footprint using Peter Kalmus's methodology in his book Being the Change: Live Well and Spark a Climate Revolution.

Step 1 - Inquire: Students watch a short video on the climate crisis. Students engage in a brief discussion on the prompt "Do my individual actions matter?"

Step 2 - Investigate: Students calculate their own carbon footprints.

Step 3 - Inspire: Students engage in a discussion, reflecting on this activity and the importance of individual actions.

Step 1. Students are asked to keep track of their energy use from a variety of sources (heating/cooling, electricity, transportation, secondary emissions, etc) during the 9 days of Thanksgiving break, when many of them are likely to travel. They use the total for the 9 days that they calculated using an online calculator to estimate their yearly footprint and compare it to US and world averages. For most of them, the amount of carbon emitted during those 9 days is quite large because of airplane travel or long-distance driving. However, using a week of break when many students will travel allows them to become aware of the significance of transportation in carbon emissions. We provided a table with electricity and heating/cooling bills for various residence halls for students who stay on campus during the break.

Step 2. Students complete an online survey where they are asked to enter the values that they have obtained for the various components of the calculator, perform some simple calculations and compare their annual footprint to the U.S. average. We used SurveyGizmo for the survey because it allows to download the data in a spreadsheet format and has some limited plotting features. The free version allows a maximum of 250 submissions, the Basic version ($19 per month, can be canceled at any time) has unlimited submissions.
Step 3. Students write an essay through BlackBoard/WebCT (Assignment). A few guiding questions are provided for this essay where students reflect on the results of their impact on the global carbon budget, what they found surprising, and if they plan to make any changes to their lifestyle to limit their impact. No length limit is set for the essay.

The guidelines and components of this assignment are available on a wiki page. The three steps can be implemented in BlackBoard/WebCT as a Lesson Plan with links to the online calculator (step 1), to the survey (step 2), and to the Assignment/essay (step 3).

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

SYNOPSIS: This lesson shows that different foods have different environmental impacts. Students will calculate ratios and practice proportional thinking.

SCIENTIST NOTES: This lesson is thoroughly sourced. It is engaging and suitable for students to understand how to measure carbon footprint from food sources. The activities in the lesson would also enable them to build their quantitative skills to determine the extent of CO2 impact on the environment. The lesson has passed our science review, and it is advised for classroom use.

POSITIVES:
-This lesson is great because it shows that different foods have different environmental impacts.
-It shows the great disparity between certain types of foods. For example, creating 1 kg of beef (from a beef herd) emits 99.48 kgCO2eq. Creating 1 kg of potatoes creates only 0.46 kgCO2eq. Raising beef creates more than 200x the carbon dioxide than raising the same amount of potatoes!

ADDITIONAL PREREQUISITES:
-You will need to share the Student Slideshow with students and grant them editing rights. They will all be writing in the same slideshow.
-In general, animals and animal products use far more resources than plants.
-Kilograms are used in this lesson. Some students will be unfamiliar with this unit. You can read more about the kilogram at Britannica. An easy conversion from kilograms to pounds is 1 kg = 2.2 lbs.
-Kilograms of CO2 equivalent are also used in this lesson. This is pretty abstract for the students. You can have them imagine holding a 2.2-pound ball in their hands. This ball has mass and takes up space. This is the "pollution" generated when creating different foods.

DIFFERENTIATION:
-You can create groups of students with mixed abilities.
-If a group finishes early, you can ask these extension questions:
-"Food 1’s emissions are what % of food 2’s emissions?"
-"Can you convert your answers from kilograms to pounds?"
-The Investigate section features a completed table of calculations. You can use this before the students begin their calculations. You can also share this with certain students or groups and let other groups complete their calculations on their own. Another option is to have students use the completed table to check their thinking when they are finished. There is a walkthrough of calculations in the speaker notes of this slide.

This video features a number of different climate scientists describing the effects of the increasing amount of carbon dioxide on global climate and proposing a series of solutions to mitigate these effects. Video addresses health problems and other costs to humans associated with climate change.

Carbon pricing, including cap-and-trade and carbon taxes, is one tool in the toolbox governments have to reduce the impacts of climate change. What kind of a tool is it? After an introduction to carbon pricing, students use an online simulator to investigate multiple pathways to a cooler future.

This Guide for Educators was developed by the MIT Environmental Solutions Initiative as an extension of our TILclimate (Today I Learned: Climate) podcast, to make it easier for you to teach climate change, earth science, and energy topics in the classroom. It is an extension of the TILclimate episode "TIL about carbon pricing."

Students play the role of carbon atoms to learn about the carbon cycle and how it is changing. Students create two carbon cycle diagramsâvisual models of the cycle before and after the Industrial Revolution. They reflect on the game and how scientists believe humans are impacting this critical Earth system.

This series of two lessons uses cutting-edge scientific research on the effects of climate change on communities in the intertidal. Through a combination of a dynamic presentation and several videos, students are introduced to the effects of climate change on the ocean (ocean acidification and temperature increase) and what is known about how ocean organisms are affected. Then students read and interpret graphs and construct a scientific explanation based on data from this research.

This lesson engages students with an environmental issue and allows them to use their artistic skills to create an artwork about caring for the oceans.

Step 1 - Inquire: Students read Somebody Swallowed Stanley and discuss the colors and emotions in the book.

Step 2 - Investigate: Students practice art techniques.

Step 3 - Inspire: Students create artworks about oceans and display them around their school or local community for others to view.

In this video segment from NatureScene, explore Cartwheel Bay, a wetland in South Carolina, and learn about the variety of carnivorous plants native to this unique landform.

In this video adapted from Texas Parks and Wildlife Department, learn about carnivorous plants that act as both producers and consumers in an ecosystem. See sundews and blatterworts capture and digest insects.

In this activity, student teams research and develop a proposal to decrease the carbon footprint of their city's/town's public transportation system and then prepare a report that explains why their transportation plan is the best for their community.

This multi-term assignment introduces students to local indigenous stories, significant plants and animals of our region and some basic skills in reading animal tracks and signs.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

I designed this activity as a role-playing game to help students understand both the concept of climate modeling and how the climate system works. Students take on the role of a climate system component, examining their personal reactions to climate stimuli and building a future scenario based on their group's reactions. You can implement this teaching collection as part of the Climate of Change InTeGrate Module, Unit 5, or as a stand-alone activity.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

In this activity, students consider how several communities are adapting to climate change-related problems including drought's impacts on agriculture, loss of assets due to climate-related hazards, freshwater availability, and extreme heat waves. They will read brief case studies about agro-forestry, insurance strategies, the "Room for the River" program in the Netherlands, water storage from retreating glaciers, and city planning for heat waves. Based on these examples and knowledge of their own community, they will suggest possible adaptation strategies that will be most beneficial to their area.

(Note: this resource was added to OER Commons as part of a batch upload of over 2,200 records. If you notice an issue with the quality of the metadata, please let us know by using the 'report' button and we will flag it for consideration.)

You’ve heard of Jackson Pollock and know of his infamous “drip paintings,” but what is it that you’re supposed to do when you look at his work today? Why did it cause shockwaves in 1947, and what does it mean now? We explore the life, evolution, and legacy of Jackson Pollock.

After exploring the “Case of the Disappearing Log,” students will probably never look at a log the same way again. In this activity, students assume the roles of detectives faced with a nature mystery. First, they explore a decomposing log and look for evidence of how the log is changing. They make possible explanations for what might be causing log to disappear. Students then learn about common “suspects”—organisms that decompose wood—and the signature evidence they each leave behind. Students use a Disappearing Log Key to identify which organisms might have left behind which evidence, and use this information to make explanations about what has happened to the log since it was a tree. Finally, students learn that the log isn’t really disappearing, it’s turning into the invisible gases that are part of the cycling of matter in all ecosystems.