Our global society is not sustainable. We all know about the challenges we’re facing: waste, climate change, resource scarcity, loss of biodiversity. At the same time, we want to sustain our economies and offer opportunities for a growing world population. This course is about providing solutions we really believe in: a Circular Economy.

In this course we explore the Circular Economy: how businesses can create value by reusing and recycling products, how designers can come up with amazingly clever solutions, and how you can contribute to make the Circular Economy happen.

SYNOPSIS: This lesson is about the distribution and density of trees in urban areas and how that relates to environmental justice.

SCIENTIST NOTES: This lesson uses data from peer-reviewed research that breaks down the forest cover in cities as it correlates to income. The evidence is clear and convincing that more affluent neighborhoods have more tree cover, which has a documented benefit on the residents. All external links are scientifically sound, and this lesson has pass our science quality assessment.

POSITIVES:
-This is an engaging lesson because it is so personal. Students will think about tree cover where they live and how that relates to demographic data.
-Students will practice their data analysis skills.

ADDITIONAL PREREQUISITES:
-It is necessary to share the Student Slideshow with your students and give them editing access before beginning the lesson. All students will be writing in the same slideshow.
-The videos list the benefits of trees pretty quickly. It might be hard for students to type fast enough to keep up. You could play the videos at 0.9 speed or replay parts of the videos as necessary.
-The following is a list of benefits of trees. Students will create a similar list while they are watching the two videos outlining the benefits of trees.

-Reduce nearby outside temperatures
-Reduce amount of energy used for heating and cooling buildings
-Absorb carbon dioxide, thus mitigating climate change
-Filter urban pollutants and fine particulates
-Provide habitat, food, and protection to plants and animals
-Provide food for people
-Increase biodiversity
-Provide wood that can be used at the end of a tree’s life
-Improve physical and mental health of people
-Increase property values
-Create oxygen
-Provide shade for people and animals
-Control stormwater runoff, protecting water quality and reducing the need for water treatment
-Protect against mudslides
-Help prevent floods
-Improve air quality
-Increase attention spans and decrease stress levels in people
-Improve health outcomes in hospital patients

DIFFERENTIATION:
-Teachers can use the glossary at the end of the slideshow at any point throughout the lesson to help students understand vocabulary.

-The spreadsheet and the graph on slide 11 might be tricky. Encourage your students to turn and talk to one another for help.

-Many students will not have a good understanding of Celsius. Easy reminder: Multiply the temperature in Celsius by 1.8 to get degrees Fahrenheit. Example: 2.5°C x 1.8 = 4.5°F (The temperature difference between poorest and richest census blocks in Milwaukee, Wisconsin.)

Around the world, major challenges of our time such as population growth and climate change are being addressed in cities. Here, citizens play an important role amidst governments, companies, NGOs and researchers in creating social, technological and political innovations for achieving sustainability.

Citizens can be co-creators of sustainable cities when they engage in city politics or in the design of the urban environment and its technologies and infrastructure. In addition, citizens influence and are influenced by the technologies and systems that they use every day. Sustainability is thus a result of the interplay between technology, policy and people’s daily lives. Understanding this interplay is essential for creating sustainable cities. In this MOOC, we zoom in on Amsterdam, Beijing, Ho Chi Minh City, Nairobi, Kampala and Suzhou as living labs for exploring the dynamics of co-creation for sustainable cities worldwide. We will address topics such as participative democracy and legitimacy, ICTs and big data, infrastructure and technology, and SMART technologies in daily life.

Here we propose carrying out a project based on citizen science, where students conduct real research on the impact of climate change on the predation of caterpillars.

From June 2018 to May 2019, we administered an assessment to 3,446 students, a national sample that matches the demographic profile of high school students in the United States. The six exercises in our assessment gauged students’ ability to evaluate digital sources on the open internet. The results—if they can be summarized in a word—are troubling: •Fifty-two percent of students believed a grainy video claiming to show ballot stuffing in the 2016 Democratic primaries (the video was actually shot in Russia) constituted “strong evidence” of voter fraud in the U.S. Among more than 3,000 responses, only three students tracked down the source of the video, even though a quick search turns up a variety of articles exposing the ruse. Two-thirds of students couldn’t tell the difference between news stories and ads (set off by the words “Sponsored Content”) on Slate’s homepage.Ninety-six percent of students did not consider why ties between a climate change website and the fossil fuel industry might lessen that website’s credibility. Instead of investigating who was behind the site, students focused on superficial markers of credibility: the site’s aesthetics, its top-level domain, or how it portrayed itself on the About page.

This activity is a classroom and schoolyard investigation where students collect daily temperature and precipitation readings, weather observations, and weekly phenology reports in a phenology binder and in nature journals. Students then analyze this data and compare to recorded values in the Weatherguide calendar.

This video and accompanying essay examine ways to reduce the environmental impact of burning coal. Two technologies are discussed: turning solid coal into a clean-burning fuel gas (syngas), and capture and storage of CO2.

In this lesson, students further their knowledge of redox titrations while examining the pressures that contamination and climate change put on access to clean water.

Step 1 - Inquire: Students observe a field scientist testing the dissolved oxygen content of the Hudson River and generate questions.

Step 2 - Investigate: Students apply the Winkler Method as a tool for assessing the health of bodies of water and identify the stresses placed on water sources by climate change.

Step 3 - Inspire: Students explore Sustainable Development Goal #6 and consider what steps they can take to protect the drinking water in their communities.

Students observe and discuss a simple balloon model of an electrostatic precipitator to better understand how this pollutant recovery method functions in cleaning industrial air pollution.

Engineers design methods of removing particulate matter from industrial sources to minimize negative effects of air pollution. In this activity, students will undertake a similar engineering challenge as they design and build a filter to remove pepper from an air stream without blocking more than 50% of the air.

In this activity, students learn about the scientific evidence supporting climate change, use this information to evaluate and improve conclusions some people might draw about climate change, and participate in a role-play to negotiate solutions to climate change.

The goal of this unit is that the students will be able to:
1. work in a blended learning environment to understand climate change and its impact on the world.
2. master a basic understanding of climate change
3. work in groups to research focused questions, present their research, and propose a way to combat climate change.
4. present their completed projects to their classmates. This unit is based on a lesson plan from The Learning Network found here: http://learning.blogs.nytimes.com/2015/04/22/guest-post-climate-change-questions-for-citizen-scientists/

In this activity students learn how Earth's energy balance is regulating climate. This activity is lesson 4 in the nine-lesson module Visualizing and Understanding the Science of Climate Change.

This article continues an examination of each of the seven essential principles of climate literacy on which the online magazine Beyond Weather and the Water Cycle is structured. Principle 2 covers the complex interactions among the components of the Earth system. The author discusses the scientific concepts underlying the interactions and expands the discussion with diagrams, photos, and online resources.

Collaborative and sharing work between students from Portugal and Romania, in the context of environmental concerns. Model Brigdge 21.

Collaborative and sharing work between students from Portugal and Romania, in the context of environmental concerns. Bridge 21 Model.

This lesson plan is aimed to show why it is important to learn about climate change. Here in the north of Brazil, most students, even teachers don’t understand we should care more about the environment.The class starts with a warmup activity showing how lots of people are already facing problems because of environmental issues.

This course explores how citizen science can support community actions to combat climate change. Participants will learn about framing problems, design ways to gather data, gather some of their own field data, and consider how the results can enable action. Leaks in the natural gas system—a major source of methane emissions, and a powerful contributor to climate change—will be a particular focus. The course was organized by ClimateX and Fossil Free MIT, with support from the National Science Foundation for the methane monitoring equipment. It was offered during the Independent Activities Period (IAP), which is a special 4-week January term at MIT.

This course explores how citizen science can support community actions to combat climate change. Participants will learn about framing problems, design ways to gather data, gather some of their own field data, and consider how the results can enable action. Leaks in the natural gas system—a major source of methane emissions, and a powerful contributor to climate change—will be a particular focus.
The course was organized by ClimateX and Fossil Free MIT, with support from the National Science Foundation for the methane monitoring equipment. It was offered during the Independent Activities Period (IAP), which is a special 4-week January term at MIT.

Climate Action! is a freely available community research guide developed by the Smithsonian Science Education Center (SSEC) in partnership with the InterAcademy Partnership as part of the Smithsonian Science for Global Goals project. Smithsonian Science for Global Goals community research guides use the United Nations Sustainable Development Goals (SDGs) as a framework to focus on sustainable actions that are defined and implemented by students.

Climate Action! is the new community research guide from the Smithsonian Science for Global Goals project for students aged 11 to 18. In the guide, young people explore the question “How can we mitigate human impact on the atmosphere?” The guide contains themes that lead youth to discover their interconnectedness with the atmosphere and understand complex climate systems. Together, these themes help prepare youth to take action towards a sustainable future for the planet.

© 2024 Smithsonian Institution
All rights reserved. First Edition 2024.

Copyright Notice
No part of this module, or derivative works of this module, may be used or reproduced for any purpose except fair use without permission in writing from the Smithsonian Science Education Center.

Heidi Gibson, Smithsonian Science Education Center - Manager of the Global Sustainability Series, is the author.

Jamie Rumage is the Oregon Open Learning - Science Group Administrator, not an official author or contributor of the published materials of the Smithsonian Science Education Center.