Market forces to help reduce emission, increase storage of CO2
assigned each of the scenarios a specific target amount of the sun’s energy that gets trapped in the atmosphere, a property called radiative forcing. Because of differences between the scenarios, each one will produce slightly different degrees of warming.
The RCP 4.5 scenario shoots for 4.5 Watts per square meters radiative forcing in 2100 and lets economics reveal how to achieve that goal the cheapest way possible. The scenario’s 4.5 W/m2 means roughly 525 parts per million carbon dioxide in the atmosphere (currently, it hovers around 390 parts per million). It also means approximately 650 parts per million carbon dioxide-equivalents, which includes greenhouse gases besides carbon dioxide.
Unlike the other three scenarios, RCP 4.5 includes carbon in forests in the carbon market. This affects how people use land, as cutting down forests emits carbon dioxide but expanding forests stores it. An earlier modeling study showed that without placing such a value, forests could get cut down for use as biofuels and the land on which they stood used for crops.
The greenhouse race
Starting with the world as it looked in 2005 and setting the endpoint at 2100, the team let the model simulate the greenhouse gas emissions and land use change over the next century. They also ran the model without any explicit greenhouse gas control policy or carbon price to compare how such a future might turn out.
Without any emission controls, carbon dioxide concentrations in the atmosphere doubled by 2100. By design, RCP 4.5 limits them to about 35 percent higher than 2005 levels.
The conditions to limit emissions did not specify how to go about doing that, only that carbon from all sources had economic value. Under limiting conditions, carbon dioxide prices rose steadily until they reached $85 per ton of carbon dioxide by 2100, in 2005 dollars.
In the scenario, the price of carbon stimulated a rise in nuclear power and renewable energy use. Also, it became cheaper to implement technologies that capture and store emissions from fossil- and bio-fuel based electricity than to emit carbon dioxide. Buildings and industry became more energy efficient and used cleaner electricity for their energy needs.
Additionally, carbon dioxide emissions from man-made sources peaked around 2040 at 42 gigatons per year (currently, emissions are at 30 gigatons per year), decreased with about the same speed as they rose, then leveled out after 2080 at around 15 gigatons per year.
Resolving power
Also, the team converted the results of the scenario to match the resolution of the climate models that are using the results. That way, scientists can more easily integrate RCP 4.5 with climate models. Economies, for example, occur on national scales, but chemical reactions of gas in the air occur in much smaller spaces.
This change in scale to accommodate climate models reveals important regional details. For example, although globally methane emissions change little over the century, their geographic origins shift around. As the century wears on, South America and Africa put out more methane and the industrialized nations less.
In addition, the percentage of people’s income that they’re spending on food goes down even though food prices rise. The researchers attribute this result to a shift from agricultural practices with high carbon footprints to lower ones, as shown in previous work.
While introducing this scenario to climate researchers, the PNNL researchers provide comparisons to other scenarios with similar emissions limits, as well as to scenarios of the other three radiative forcing targets covered by this community activity. The special issue of Climatic Change features papers documenting those other three scenarios as well as several papers reviewing specific parts of the entire scenario exercise.
“It’s very important that the climate community has this resource so that they all work from the same data. This common thread will help researchers and policymakers address the problems that climate change will bring us,” said Thomson.
Data and results from RCP 4.5 studies are Open Access and are available from JGCRI’s Web site.
This work was supported by the U.S. Department of Energy Office of Science.
— Read more in Allison M. Thomson et al., “RCP4.5: a pathway for stabilization of radiative forcing by 2100,” Climatic Change (29 July 2011) (DOI: 10.1007/s10584-011-0151-4)