Where is carbon capture, utilization and storage happening? For cross-cutting considerations, see our What Is Carbon Removal? fact sheet.So, where does that carbon dioxide go? Most likely, carbon dioxide will be stored underground in locations such as depleted oil and gas reservoirs, deep saline formations and un-minable coal beds.Finance: mechanisms such as cost-sharing can promote global benefits by helping to manage local costs of BECCS projects.Agricultural policy: creative agricultural policies and processes can support sustainable biomass production and sourcing on large scales.Life cycle analysis: processes and standards need to be developed for ensuring that BECCS operations sequester more carbon than their supply chains emit.Research, development and demonstration (RD&D): support and guidance for RD&D is needed to promote sustainable bio-feedstocks and supply chains and reliable methods of carbon storage or utilization.Efforts to combine the two technologies remain limited: besides various pilot projects and small-scale BECCS projects at various kinds of facilities (e.g., waste-to-energy, ethanol, cement, electrical generation, etc.), the American agribusiness firm Archer Daniels Midland operates a commercial facility in Decatur, Illinois the British electrical power generation company Drax has converted a large coal-fired power plant in North Yorkshire to run on wood pellets, with plans to add carbon capture and storage and Toshiba is adding carbon capture and storage to its Mikawa biomass-fired power plant in Japan. The other component technology for BECCS, carbon capture and sequestration, is relatively well understood, but, for economic reasons, it has mostly struggled to move beyond demonstration projects for saline sequestration and limited commercial projects that use CO 2 in enhanced oil recovery. Technological Readinessīioenergy and biofuels are already widely used. National Academy of Sciences estimates a global potential to sequester 3.4–5.2 GtCO 2 per year via BECCS without large adverse impacts.Ĭost estimates vary widely, with one recent expert assessment projecting costs of US$100–200 per ton of CO 2 sequestered and another projecting costs of US$20–100 per ton. Such projections have been met with intense skepticism, partly because of land-use requirements. Scenarios compiled by the Intergovernmental Panel on Climate Change (IPCC) suggest that limiting warming to 1.5☌ or 2☌ at the end of the century could involve sequestering roughly 5–10 billion metric tons of CO 2 (GtCO 2) per year via BECCS by 2100. A recent expert assessment estimates potential sequestration rates of 0.5–5 billion metric tons of CO 2 per year in 2050 with the possibility of much higher rates by 2100. Potential Scale and CostsĮstimates for the potential scale of BECCS vary widely. Smaller scale applications using agricultural residues or marginal agricultural land generally pose fewer risks. Many of these issues would arise only from very large-scale adoption of BECCS. Concerns about geologic storage: transporting and injecting CO 2 into geological reservoirs raises concerns about pipelines, CO 2 leakage, seismic activity, and water pollution.Air pollution: combustion of biomass and biofuels creates local air pollution.Soil carbon loss: land conversion for growing biomass could release carbon stored in soils or existing biomass.Increased fertilizer use: fertilizer for growing biomass could further stress nitrogen-saturated ecosystems.Water resources: growing dedicated bioenergy crops would increase demand for water.Biodiversity loss: land conversion for growing biomass could alter habitats and threaten biodiversity. Displacement: moving communities for land conversion threatens livelihoods, human rights, and social identity.Food security: devoting large areas of land to bioenergy crops could raise food prices.Energy: BECCS produces energy, potentially including carbon-negative fuels for hard-to-decarbonize sectors.However, care must be taken to ensure that emissions from the growing, harvesting, transporting, and processing of the biomass do not outweigh the captured carbon, and that the storage of captured carbon is reliable over long timescales. That is, BECCS could serve to draw down the concentration of carbon dioxide (CO 2) in the atmosphere. Because the biomass draws carbon from the atmosphere as it grows, BECCS can be a negative emissions technology when it is implemented well. Biomass (organic material) is converted into heat, electricity, or liquid or gas fuels (the “bioenergy” step), and the carbon emissions from this bioenergy conversion are captured and stored in geological formations or embedded in long-lasting products (the “carbon capture and storage” step). Bioenergy with carbon capture and storage (BECCS) is a carbon removal technique that depends on two technologies.
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