Editor's note: 13 May, 2022. This page is out of date. It's being left online to preserve the link in case this page was cited by as a reference. More recent projections of future climate are available in Chapter 4 of the Intergovernmental Panel on Climate Change's Sixth Assessment Report and as an interactive atlas. Your can view projections that have been downscaled to local areas in the Climate Explorer, part of the U.S. Climate Resilience Toolkit.
According to climate scientists, our world is highly likely to continue to warm over this century and beyond. This conclusion is based on scientists’ understanding of how the climate system works and on computer models designed to simulate Earth’s climate. Results from a wide range of climate model simulations suggest that our planet’s average temperature could be between 2 and 9.7°F (1.1 to 5.4°C) warmer in 2100 than it is today.
The main reason for this temperature increase is carbon dioxide and other heat-trapping “greenhouse” gases that human activities produce. The biggest source of added carbon dioxide is from people burning coal and other fossil fuels.
The exact amount of warmingthat will occur in the coming century depends largely on the energy choices that we make now and in the next few decades, particularly since those choices directly influence how fast we put heat-trapping gases into the atmosphere. In addition to uncertainty about what those choices will be, there are also details we don’t yet know about how the climate will respond to continued increases in heat-trapping gases, particularly over longer time scales.
Screenshot of a former interactive graph of future climate projections based on different human emission pathways. The graph shows the average of a set of temperature simulations for the 20th century (black line), followed by projected temperatures for the 21st century based on a range of emissions scenarios (colored lines). The shaded areas around each line indicate the statistical spread (one standard deviation) provided by individual model runs. (Data processing by Jay Hnilo, CICS-NC, using data courtesy the Coupled Model Intercomparison Project, or CMIP3.)
Climate scientists are continually improving their understanding of how Earth’s climate system works. They can generate global temperature projections because they have been painstakingly observing and measuring the main mechanisms that influence climate for more than a century. They have developed a good understanding of the key ways that energy and water flow through the planet’s climate system, and how the different parts of the climate system interact with one another. This understanding is translated into complex computer software known as “global climate models.”
The graph above demonstrates that people are a big wild card in the climate system. How fast will human population grow? How much energy will we choose to use? Will our primary sources of energy continue to be fossil fuels (such as coal, oil, and natural gas)? To what extent will we continue to slash and burn forested regions, and how fast will we reforest cleared areas? These are the types of choices that will determine our greenhouse gas emissions and ultimately drive the amount of warming Earth experiences.
The net impacts of these human actions and choices on future greenhouse gas concentrations are fed into models as different “scenarios.” For example, the scenario represented by the blue trend line above (IPCC Scenario B1) assumes that humans worldwide will make more sustainable development choices by using a greater range of, and more efficient, technologies for producing energy. In this scenario, carbon emissions are projected to increase from today’s rate of about 9 billion metric tons per year to about 12 billion tons per year in 2040, and then gradually decline again to 1990 levels—5 billion tons per year—by 2100.
The scenario represented by the red trend line (IPCC Scenario A2) assumes humans will continue to accelerate the rate at which we emit carbon dioxide. This is consistent with a global economy that continues to rely mainly on coal, oil, and natural gas to meet energy demands. In this scenario, our carbon emission increases steadily from today’s rate of about 9 billion tons per year to about 28 billion tons per year in 2100. The middle trend (green, IPCC Scenario A1b) assumes humans will roughly balance their use of fossil fuels with other, non-carbon emitting sources of energy.
Because temperature projections depend on the choices people make in the future, climate scientists can’t say which one of the scenarios is more likely to come to pass by the end of the century. These scenarios are estimates, and greenhouse gas concentrations may grow at rates that are higher or lower than the scenarios shown in the graph. If future carbon dioxide emissions follow the same trajectory as they have over the last decade, increasing at a rate of more than 3 percent per year, carbon dioxide levels in the atmosphere would exceed the scenario represented by the red line (IPCC scenario A2) by the end of this century, if not before.
These maps show the average of a set of climate model experiments projecting changes in surface temperature for the period 2050-2059, relative to the period from 1971-1999. The top left map corresponds with the green trend line above (IPCC scenario A1B); the top right map matches the red trend line above (IPCC scenario A2); and the bottom left map matches the blue trend line (IPCC scenario B1). All models project some warming for all regions, with land areas warming more than oceans. large versions: A1B | A2 | B1 (Maps by Ned Gardiner, Hunter Allen, and Jay Hnilo, CICS-NC, using data courtesy the Coupled Model Intercomparison Project, or CMIP3.)
While Earth’s average temperature has warmed and cooled throughout our planet’s history, it’s extremely rare for a single life form to drive significant climate change, and never before has a single species had the power to force Earth’s climate to change at the rate climate models project human activities will force our world to warm this century.
Though scientists expect Earth to be perceptibly warmer 100 years from now than it is today, there is still a wide range in how much warming Earth will experience. Our choices will make a big difference.
References
Solomon, S., D. Qin, M. Manning, Z. Chen, M. Marquis, K.B. Avery, M. Tignor, and H.L. Miller (eds.). (2007): Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press, Cambridge, United Kingdom, and New York, NY, USA.
Friedlingstein, P., R.A. Houghton, G. Marland, J. Hackler, T.A. Boden, T.J. Conway, J.G. Canadell, M.R. Raupach, P. Ciais, and C. Le Quere (2010): “Update on CO2 emissions.” Nature Geoscience. Vol 3. Dec 2010. p811-810.
Science Reviewers: Keith Dixon, NOAA Geophysical Fluid Dynamics Laboratory; Katharine Hayhoe, Texas A&M; and Rick Rosen, NOAA Climate Program Office.
I'm a climate science enthusiast with a robust understanding of the key concepts and evidence surrounding climate change. My expertise is grounded in the extensive research conducted by climate scientists, and I draw upon a wealth of knowledge to shed light on the complexities of Earth's climate system.
The article you provided, dated 13 May 2022, touches upon critical aspects of climate change projections and the factors influencing future global temperatures. Here's a breakdown of the key concepts discussed in the article:
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Climate Projection Models: The article emphasizes the use of computer models, specifically "global climate models," to simulate Earth's climate. These models help scientists project future temperature changes based on various scenarios of human activities and greenhouse gas emissions.
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Greenhouse Gas Emissions: Human activities, particularly the burning of fossil fuels like coal, oil, and natural gas, contribute significantly to the increase in greenhouse gases, especially carbon dioxide. The primary driver of future temperature changes is identified as these heat-trapping "greenhouse" gases.
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Temperature Projections: The article presents a range of temperature projections for the year 2100, varying from 2 to 9.7°F (1.1 to 5.4°C) warmer than the present. The exact level of warming is contingent upon the choices made regarding energy sources and the resultant greenhouse gas emissions.
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Emission Scenarios: Different emission scenarios are outlined, represented by trend lines in a graph. These scenarios, such as IPCC Scenario B1 (blue), A2 (red), and A1b (green), depict possible futures based on human choices related to energy consumption and development practices.
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Uncertainties and Choices: The article underscores uncertainties related to future human choices, including population growth, energy usage, and the reliance on fossil fuels. These uncertainties contribute to the difficulty of precisely predicting the trajectory of future climate change.
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Impact of Human Actions: Human actions, including deforestation and energy choices, play a crucial role in determining the concentration of greenhouse gases. These actions are translated into models as different scenarios, influencing the overall trajectory of climate change.
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Climate Model Experiments: The article features maps showing climate model experiments projecting changes in surface temperature for the period 2050-2059, relative to the period from 1971-1999. Different scenarios project varying degrees of warming for land areas and oceans.
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Historical Context: The rarity of a single species (humans) driving significant climate change and the unprecedented rate at which human activities are projected to impact Earth's climate are highlighted. The article also references Earth's historical temperature fluctuations.
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Scientific References: Citations to authoritative sources, such as the Intergovernmental Panel on Climate Change (IPCC) reports and other scientific studies, provide a foundation for the claims made in the article.
In conclusion, the article stresses the importance of human choices in shaping the future climate and underscores the significance of understanding and mitigating the impact of greenhouse gas emissions on Earth's temperature.
