Hot Property: How to Manage Valuable US Landscapes for Carbon Sequestration

Achieving the goals of the 2015 Paris Agreement will almost inevitably require negative emissions from a combination of agriculture, land use, forestry, and other technologies that actively remove CO2 from the atmosphere. According to IPCC scenarios, 10–20 gigatons of negative emissions are required annually by 2100 to limit global average temperature increase to 1.5–2.0C° above preindustrial levels. That’s equivalent to 25–50 percent of today’s global annual fossil fuel emissions.

US landscapes sequester hundreds of millions of tons of CO2 every year, storing carbon in trees and soils, and offsetting fossil fuels. This carbon sequestration is critical as the United States is the third-largest country in the world, covers six percent of the world’s land mass and over 250 of the world’s 867 ecoregions, and supports a diverse range of agricultural and forestry industries. Bolstering this carbon storage ability is seen as a cost-effective climate strategy. But any policy to drive this action needs to be implemented carefully, balancing future needs for development and urban expansion, food and products production, and conservation.

Rocky Mountain Institute’s new report, Negative Emissions and Land-Based Carbon Sequestration: Implications for Climate and Energy Scenarios, helps policymakers and experts think strategically about the role of US landscapes in climate mitigation, and how to most responsibly manage this important resource. Negative emissions technologies—natural and engineered strategies for actively removing CO2 from the atmosphere such as agroforestry and silvopasture, biomass gasification and biochar, and forest expansion—deployed at scale in the United States could sequester between 0.6 and 1.4 gigatons of carbon annually by 2050. This would comprise a substantial portion of the estimated annual 7–10 gigatons of CO2 that could be sequestered globally through landscapes.

Why Do We Care About Carbon Sequestration?

Most models indicate that large amounts of carbon sequestration, or negative emissions, will be required, likely at very large scale, to head off the worst effects of climate change. Out of the 116 model scenarios consistent with keeping warming below 2C° used by the Intergovernmental Panel for Climate Change (IPCC), 87 percent utilize negative emissions technologies.

Note that most of these projections also assume that countries will implement aggressive emissions reduction strategies, quickly. With further delayed action, the need for negative emissions will only increase.

US Landscapes—The Goose That Laid the Golden Egg

Land and natural systems like oceans provide the only negative emissions currently operating at scale. In the United States, landscapes have sequestered between 10 and 15 percent of economy-wide greenhouse gas emissions every year for the past several decades. US farms and forests are also some of the most productive in the world, supporting 20 percent of global cereal production and 20 percent of global wood products.

Looking ahead, many models see a role for US lands in sequestering greater and greater amounts of carbon from the atmosphere. The US Mid-Century Strategy for Deep Decarbonization, released in 2016 by the Obama White House, suggests that US forests and soils could sequester nearly one gigaton of CO2 annually by 2050, while also supporting nearly 1 billion tons of biomass production for another negative emissions technology, bioenergy plus carbon capture and storage (BECCS).

Across a spectrum of carbon price levels, other estimates indicate that the sequestration and BECCS potential could be even higher (see Figure 1). Yet managing hundreds of millions of acres of US land to sequester carbon and produce biomass could come at the cost of alternative uses and ecosystem services. There is also potential for trade-offs across carbon sequestration strategies—for example, sequestering carbon in forests versus harvesting wood to offset fossil fuel-intensive building materials like steel and concrete; or using underutilized pasture to grow bioenergy grasses versus using it to expand forest area. All these trade-offs and constraints need to be addressed by thoughtful policy and safeguards.

Figure 1: Estimates of US annual CO2 million metric tons (MMT) sequestration through afforestation, enhanced forest management (EFM), improved agricultural soil management, and bioenergy plus carbon capture and storage (BECCS). Based on 13 studies (synthesized in Van Winkle et al., 2017; Murray et al., 2005; Chambers et al., 2016)
Balancing Many Needs Across a Limited Resource

In the coming decades, growing global populations will put even more pressure on US landscapes, beyond the effects of climate change and growing demand for carbon sequestration. US cities and suburbs are projected to grow by 15 to 45 million acres, supporting a growing population that could reach nearly 400 million by 2050.

Global food demand could double by that time as well. Depending on continued yield improvements, US agricultural land could expand significantly to keep up with increasing calorie demand.

At the same time, technological breakthroughs could allow for doing a lot more on less land. Algae production on low-productivity land or offshore could create sizable biomass supply if costs can be brought down. Dietary shifts toward plant-based meat alternatives could significantly reduce pasture needs around the planet while increasing access to protein for low-income households. Increasing crop yields and root mass can increase soil carbon storage while also meeting food demands.

So, while there will be many challenges to responsibly utilizing landscapes, there is also great potential, particularly with the right investments in research, demonstration, and deployment.

Recommendations for Responsible Land Carbon Management

Putting in place the right combination of research and deployment incentives is key for achieving the scale of negative emissions needed. The report identifies a critical set of policies needed now:

  • The building blocks for accurate carbon accounting across mitigation strategies, to allow for appropriately choosing mitigation options and achieving maximum “bang-for-buck”
  • Research programs to support carbon sequestration breakthrough opportunities, a number of which are described in the report, including algae, agricultural rotational strategies, yield increases, and more.
  • Tracking and safeguards for impacts on social and environmental factors, like food costs, land and housing costs, conservation, and nutrient pollution.
  • Carbon price-based incentives for increasing carbon sequestration—this is a necessary condition for any progress and can be implemented concurrently with the interventions above to begin the process of learning by doing and continue to bring down costs over time.

Responsible land use and land management is the next great frontier of climate policy, and warrants careful planning in the coming years to make sure future climate mitigation policy optimally utilize this important US resource.

Download Negative Emissions and Land-Based Carbon Sequestration: Implications for Climate and Energy Scenarios