This is lesson five of a 9-lesson module. Activity explores the effects of climate change on different parts of the Earth system and on human well-being: polar regions, coral reefs, disease vectors, extreme weather, and biodiversity.

How does global warming affect humans? The Climate Change Webcast explores the causes and effects of climate change as students work together to create an international climate change proposal to present at the United Nations Climate Summit.

Road to Doha explores critical environmental issues through addressing the driving question “How do we, as youth, impact climate change in our communities?”

The Tech Camps curriculum explores the use of technology and sustainable design to address environmental challenges in local and global communities. How do we, as youth, use technology to create solutions for climate change issues affecting our local and global communities?

This activity supports educators in the use of the activities that accompany the GLOBE Program's Earth System Poster 'Exploring Connections in Year 2007'. Students identify global patterns and connections in environmental data that include soil moisture, insolation, surface temperature, cloud fraction, precipitation, world topography/bathymetry, aerosol optical thickness, and biosphere (from different times of the year) with the goal of recognizing patterns and trends in global data sets.

Students use an online mapping tool to investigate changes in global snow cover, develop a problem statement about global snow cover, and then use the tools to investigate a problem or question of their own design.

In this activity, students create graphs of real temperature data to investigate climate trends by analyzing the global temperature record from 1867 to the present. Long-term trends and shorter-term fluctuations are both evaluated. The data is examined for evidence of the impact of natural and anthropogenic climate forcing mechanisms on the global surface temperature variability. Students are prompted to determine the difficulties scientists face in using this data to make climate predictions.

Students analyze the global temperature record from 1867 to the present. Long-term trends and shorter-term fluctuations are both evaluated.

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This video segment demonstrates carbon dioxide's role in the greenhouse effect and explains how increasing concentrations of C02 in the atmosphere may be contributing to global warming. Video includes an unusual demonstration of C02's heat-absorbing properties, using infrared film, a researcher's face, and a stream of C02 between them.

Detailed, annotated example of Socratic questioning for topics of climate change, global warming, and greenhouse gases in the atmosphere.

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In this assignment, you will conduct an experiment to simulate the greenhouse effect and global warming. You will be recording and graphing your results.

Brian Fagan is an emeritus professor of anthropology at University of California, Santa Barbara who has written several books about past climate change and its effect on the course of European history. His latest book, "The Great Warming," focuses on the Medieval Warm Period (circa 10th to 14th centuries) during which the North Atlantic region experienced an unusually warm climate, and discusses historical events and trends that can be correlated with this climatic change. This assignment uses this book, along with student-retrieved newspaper articles, as the basis for a research paper that addresses the issue of global warming, its effect on past civilizations and its anticipated effect on the future of the citizens of New York City.

Based primarily on "The Great Warming", students address the following questions in a 5 page paper:

What methods and data sources do scientists use to determine climates of the past? How reliable are these various approaches?
How was European climate different during the Medieval Warm Period, and how did this climate affect the lives of people in Europe?
How was climate different during the Medieval Warm Period for one other region of personal interest, and how did this climate affect the lives of people who lived in that region?

Using information from "The Great Warming" and three to six articles from past issues of a major newspaper, such as the New York Times, students determine probable effects of global warming to the future populations of either their home city, or of the region for which they documented past climate change.

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A sequence of five short animated videos that explain the properties of carbon in relationship to global warming, narrated by Robert Krulwich from NPR.

This course introduces the basic science underpinning our knowledge of the climate system, how climate has changed in the past, and how it may change in the future. The course focuses on the fundamental energy balance between incoming solar radiation and outgoing infrared radiation in the climate system, and how this balance is affected by greenhouse gases. We will also discuss physical processes that shape the climate, such as atmospheric and oceanic convection and large-scale circulation, solar variability, orbital mechanics, and aerosols, as well as the evidence for past and present climate change. We will discuss climate models of varying degrees of complexity, and you will be able to run a model of a single column of the Earth’s atmosphere to simulate many of the important elements of climate change.
This course is part of the Open Learning Library, which is free to use. You have the option to sign up and enroll in the course if you want to track your progress, or you can view and use all the materials without enrolling.

This course provides students with a scientific foundation of anthropogenic climate change and an introduction to climate models. It focuses on fundamental physical processes that shape climate (e.g. solar variability, orbital mechanics, greenhouse gases, atmospheric and oceanic circulation, and volcanic and soil aerosols) and on evidence for past and present climate change. During the course they discuss material consequences of climate change, including sea level change, variations in precipitation, vegetation, storminess, and the incidence of disease. This course also examines the science behind mitigation and adaptation proposals.

This course provides students with a scientific foundation of anthropogenic climate change and an introduction to climate models. It focuses on fundamental physical processes that shape climate (e.g. solar variability, orbital mechanics, greenhouse gases, atmospheric and oceanic circulation, and volcanic and soil aerosols) and on evidence for past and present climate change. During the course they discuss material consequences of climate change, including sea level change, variations in precipitation, vegetation, storminess, and the incidence of disease. This course also examines the science behind mitigation and adaptation proposals.

This video segment adapted from NOVA/FRONTLINE examines the greenhouse effect, its role in keeping Earth habitable, and the industrial changes that have led to an increase in the planet's average temperature.

In this video segment adapted from Spanner Films, visit the Alaska Native village of Shishmaref, and learn how an entire town may be forced to relocate because of warmer temperatures, melting sea ice, and coastal erosion.

In this Webquest activity, students assume roles of scientist, business leader, or policy maker. The students then collaborate as part of a climate action team and learn how society and the environment might be impacted by global warming. They explore the decision making process regarding issues of climate change, energy use, and available policy options. Student teams investigate how and why climate is changing and how humans may have contributed to these changes. Upon completion of their individual tasks, student teams present their findings and make recommendations that address the situation.

In the first part of this activity, students think about their personal carbon emissions and driving habits. They reflect on what might be done to reduce our carbon emissions, as individuals and as a society as a whole. In the second part of the activity, students calculate how much sea level would rise if a range of ice melting scenarios occur. They then examine topographic maps of local coastlines to see how different regions would be affected under the range of scenarios.

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