Remove Carbon Industrial Carbon Removal Carbon Removal & Storage

Deploy Direct Air Capture

An image of large fans used for direct air capture of carbon dioxide

Direct air capture (DAC) is an industrial process that captures CO₂ from the air and then injects it deep underground for permanent, geologic storage. This process is energy-intensive. Therefore, DAC can only be effective for net carbon removal if it does not generate high levels of emissions during the process. This requires that DAC be powered by zero- or low-carbon energy sources and that the captured carbon is permanently stored rather than used for emission-generating applications. Unlike the situation for many other carbon removal methods, the amounts of CO₂ captured and stored using DAC can be reliably measured, which is an advantage in the carbon marketplace. However, the effectiveness of DAC has been extremely low so far. DAC is also expensive, up to US$1,000/t CO₂ removed and stored. Substantial funding to support DAC development has come from fossil-fuel interests or their government proxies, which view carbon capture as a strategy to extend society’s use of fossil fuels. Therefore, there is a risk that DAC could be used to delay or avoid emissions reductions and perpetuate or even expand fossil-fuel production and use. Based on this risk, as well as the functional and financial challenges for scaling this technology to remove globally meaningful amounts of CO₂, we conclude that DAC is “Not Recommended” as a climate solution.

Last updated September 18, 2025

What is our assessment?

Based on the difficulty of capturing low concentrations of CO₂ from the air and the associated technological, energy consumption, and financial challenges facing DAC, it is unlikely that this climate technology can be scaled up to remove globally meaningful amounts of CO₂. Furthermore, based on the current financial and policy support for DAC from fossil-fuel interests, there is a clear risk that the technology will be used to enable and perpetuate the production and use of fossil fuels, which is antithetical to solving the climate crisis. Therefore, we conclude that deployment of DAC is “Not Recommended” as a climate solution.

Plausible	Could it work?	Yes
Ready	Is it ready?	No
Evidence	Are there data to evaluate it?	Yes
Effective	Does it consistently work?	No
Impact	Is it big enough to matter?	No
Risk	Is it risky or harmful?	Yes
Cost	Is it cheap?	No

What is it?

DAC is a suite of engineered technologies that remove CO₂ directly from the atmosphere, concentrate it, and then inject it underground for permanent storage. CO₂ is captured from the atmosphere by moving large volumes of air, usually with large fans, past a reactive material that selectively binds CO₂, either a solid sorbent (referred to as solid-DAC or S-DAC) or a liquid solvent (referred to as liquid-DAC or L-DAC). The captured CO₂ is recovered from the reactive material by applying heat, pressure, or chemical reactions, and collected and compressed for transportation and storage. The concentrated CO₂ is then injected deep underground into geological formations, such as saline aquifers or basalt formations, where it can be permanently stored.

Does it work?

The technology and chemistry for the selective capture of CO₂ from air are effective, although the CO₂ capture efficiency varies with the reactive material and other factors. A variety of solid and liquid reactive materials have been developed, along with material-specific processes for recovering captured CO₂ and regenerating the sorbents. This process is very energy-intensive and, for liquid-DAC, water-intensive. To capture and recover 1 t CO₂, solid-DAC uses about 1,100 kWh, while liquid-DAC uses about 2,500 kWh and consumes as much as 7 t of water. Most of the energy for DAC (70–90%) is used to generate heat for recovery of the captured CO₂ and regeneration of the sorbent material. Liquid-DAC requires temperatures up to about 900 °C (1,652 °F), while solid-DAC requires temperatures of only about 100 °C (212 °F). Because the process is so energy intensive, DAC achieves net carbon removal – capturing and sequestering more CO₂ than it emits – only if it is powered by zero or low-carbon energy sources and/or uses waste heat. For example, recent reporting showed that the amount of CO₂ captured and stored by Climeworks, the largest commercial DAC company currently in operation, was insufficient to offset the facility’s operational GHG emissions. CO₂ captured by a DAC facility can also be used for other purposes, such as enhanced oil recovery or production of algae biofuels. However, life cycle analyses conducted by the National Energy Technology Laboratory show that these pathways do not result in net carbon removal due to the emissions from production and/or use of these other products. Therefore, in addition to its requirements for zero or low-carbon energy, DAC can only be an effective method for net carbon removal if the CO₂ it captures is permanently stored deep underground. With appropriate pre-injection site selection, geologic testing, and post-injection monitoring, underground storage of CO₂ is safe and effectively permanent.

Why are we excited about it?

Unlike some other carbon removal technologies and practices, a DAC facility has a relatively small footprint and can be located anywhere there is sufficient low-carbon energy and infrastructure and capacity to transport or store captured CO₂. In addition, the amount of CO₂ removed from the atmosphere can be directly measured by monitoring the flow and concentration of captured CO₂ at the point of storage. Compared to many other carbon removal approaches, this method provides a higher level of confidence in the amount of CO₂ being removed for investors and carbon credit purchasers. The geological sequestration of captured CO₂ has high permanence, effectively removing CO₂ from the atmosphere for thousands of years with a low risk of reversal. There are numerous research and pilot projects underway to improve CO₂ capture efficiency, reduce energy use, and reduce costs, which may improve the effectiveness and cost of this technology.

Why are we concerned?

The concentration of CO₂ in the atmosphere is small, currently about 420 parts per million, or about 0.04%. This means that a DAC facility must process huge amounts of air – more than 1,600 t by one estimate – and consume more energy than a typical U.S. household uses in a month to capture 1 t CO₂. Scaled up to remove a globally meaningful amount of CO₂ (>0.1 Gt CO₂ /yr), DAC would consume more energy than the annual energy consumption of 10 million U.S. households. In addition, removing and storing CO₂ using DAC is very expensive, costing up to US$1,000/t CO₂ stored. This is more than twice the cost per t for all other commercially available carbon removal technologies and practices.

For these reasons, the technical and financial feasibility of scaling DAC to remove globally meaningful amounts of CO₂ from the atmosphere is low. Despite these challenges, as of September 2025, more than 30 companies have sold more than 2.4 million t of future carbon removal credits. However, less than 1,300 t CO₂ has actually been removed so far – or only 0.05% of these promised credits. To put this in perspective, despite spending billions of dollars, DAC has removed about as much CO₂ as would be saved by keeping 250-300 cars off the road for a single year.

There is also an opportunity cost for DAC. Even if a DAC facility is powered by solar, wind, geothermal, or nuclear energy, that carbon-free energy could have been used to displace coal- and gas-powered electricity instead, reducing emissions by far more than a DAC facility can capture and store. Similarly, the large amounts of public and private sector funding going to DAC could be more cost-effective and carbon-effective if used for other, more effective actions to cut emissions or remove CO₂. There is also the risk that DAC will be used to delay or avoid emissions reduction actions or for greenwashing by fossil fuel companies and other emitters. Substantial amounts of the funding supporting the development of DAC are coming from fossil fuel companies, which have publicly stated that they view carbon capture as a strategy to extend society’s use of fossil fuels. Finally, unlike most other emissions reduction or carbon removal actions, DAC provides no obvious other benefits to nature or human well-being.

References

Alexandersson, B. O. P and Grettisson, V. (2025) Climeworks’ capture fails to cover its own emissions. Heimildin. Link to source: https://heimildin.is/grein/24581/

Bashir, A., Ali, M., Patil, S., Aljawad, M. S., Mahmoud, M., Al-Shehri, D., Hoteit, H., & Kamal, M. S. (2024). Comprehensive review of CO2 geological storage: Exploring principles, mechanisms, and prospects. Earth-Science Reviews, 249, 104672. Link to source: https://www.sciencedirect.com/science/article/pii/S0012825223003616

Bindl, M., Edwards, M. R., & Cui, R. Y. (2025). Risks of relying on uncertain carbon dioxide removal in climate policy. Nature Communications, 16(1), 5958. Link to source: https://www.nature.com/articles/s41467-025-61106-4

Bisotti, F., Hoff, K. A., Mathisen, A., & Hovland, J. (2023). Direct air capture (DAC) deployment: National context cannot be neglected. A case study applied to Norway. Chemical Engineering Science, 282, 119313. Link to source: https://www.sciencedirect.com/science/article/pii/S0009250923008692

Calma, J. (2023) To capture CO2 in the US, climate tech startups partner with oil and gas. The Verge. Link to source: https://www.theverge.com/2023/4/21/23690040/climeworks-direct-air-carbon-capture-oil-gas

CDR.fyi. (2025) Keep Calm and Remove On - CDR.fyi 2024 Year in Review Link to source: https://www.cdr.fyi/blog/2024-year-in-review

Chatterjee, S., & Huang, K. W. (2019). Unrealistic energy and materials requirement for direct air capture in deep mitigation pathways. Nat. Commun. 11, 3287. Link to source: https://www.nature.com/articles/s41467-020-17203-7

Chen, S. (2025) Energy and water use for DAC. Carbon180. Link to source: https://carbon180.org/blog/energy-and-water-use-for-dac/#:~:text=To%20estimate%20the%20amount%20of%20energy%20consumed%20by,%3D%20%28Energy%20per%20tCO2%29%20%2A%20%28Total%20DAC%20capacity%29

Eke, V., Sahu, T., Ghuman, K. K., Freire-Gormaly, M., & O'Brien, P. G. (2025). A comprehensive review of life cycle assessments of direct air capture and carbon dioxide storage. Sustainable Production and Consumption. Link to source: https://www.sciencedirect.com/science/article/pii/S2352550925000399

Gulden, L. E., & Harvey, C. (2025). Tracing sources of funds used to lobby the US government about carbon capture, use, and storage. Environmental Science & Policy, 171, 104171. Link to source: https://www.sciencedirect.com/science/article/pii/S146290112500187X

Hager, B. & MIT Climate Portal Writing Team (2024) What is the risk that CO2 stored underground after carbon capture will escape again? MIT Climate Portal. Link to source: https://climate.mit.edu/ask-mit/what-risk-co2-stored-underground-after-carbon-capture-will-escape-again

Hiar, C. (2023) Oil companies want to remove carbon from the air — using taxpayer dollars. Climatewire, E&E News. Link to source: https://www.eenews.net/articles/oil-companies-want-to-remove-carbon-from-the-air-using-taxpayer-dollars/

International Energy Agency (no date) Direct Air Capture. Website. Link to source: https://www.iea.org/energy-system/carbon-capture-utilisation-and-storage/direct-air-capture

Isometric (2025) Direct Air Capture explained: Understanding the process, benefits and cost of DAC. Link to source: https://isometric.com/writing-articles/direct-air-capture-explained

Jacobson, M. Z. (2019). The health and climate impacts of carbon capture and direct air capture. Energy & Environmental Science, 12(12), 3567-3574. Link to source: https://web.stanford.edu/group/efmh/jacobson/Articles/Others/19-CCS-DAC.pdf

Jacobson, M. Z., Fu, D., Sambor, D. J., & Muhlbauer, A. (2025). Energy, health, and climate costs of carbon-capture and direct-air-capture versus 100%-wind-water-solar climate policies in 149 countries. Environmental Science & Technology, 59(6), 3034-3045. https://pubs.acs.org/doi/10.1021/acs.est.4c10686?ref=pdf

Lebling, K., Leslie-Bole, H., Byrum, Z., Wilcox, J. & Riedl, D. (2025) 6 Things to Know About Direct Air Capture. World Resources Institute. Link to source: https://www.wri.org/insights/direct-air-capture-resource-considerations-and-costs-carbon-removal

Mackler, S., Fishman, X., & Broberg, D. (2021). A policy agenda for gigaton-scale carbon management. The Electricity Journal, 34(7), 106999. Link to source: https://www.sciencedirect.com/science/article/pii/S1040619021000907

Maloney, C. B. and Khanna, R. (2022). Memorandum: Investigation of Fossil Fuel Industry Disinformation. U.S. House of Representatives, Committee on Oversight and Reform. Link to source: https://oversightdemocrats.house.gov/sites/evo-subsites/democrats-oversight.house.gov/files/2022.09.14%20FINAL%20COR%20Supplemental%20Memo.pdf

Martin, P. (2023) Why Direct Air Capture Sucks (and not in a good way!). LinkedIn.Link to source: https://www.linkedin.com/pulse/why-direct-air-capture-sucks-good-way-paul-martin/

Milman, O. (2023) The world’s biggest carbon capture facility is being built in Texas. Will it work? The Guardian. Link to source: https://www.theguardian.com/environment/2023/sep/12/carbon-capture-texas-worlds-biggest-will-it-work

National Academies of Sciences, Medicine, Division on Earth, Life Studies, Ocean Studies Board, Board on Chemical Sciences, ... & Reliable Sequestration. (2019). Negative emissions technologies and reliable sequestration: A research agenda. Link to source: https://nap.nationalacademies.org/read/25259/chapter/7#203

OPIS and CDR.fyi. (2025) Bridging the Gap: Durable CDR Market Pricing Survey: Purchaser and Supplier Expectations in 2025 and 2030. Link to source: https://www.cdr.fyi/reports/pricing-survey-jan-2025.pdf

Ozkan, M. (2025). Atmospheric alchemy: The energy and cost dynamics of direct air carbon capture. MRS Energy & Sustainability, 12(1), 46-61. Link to source: https://link.springer.com/content/pdf/10.1557/s43581-024-00091-5.pdf

Pett-Ridge, J., Ammar, H., & Aui, A. (2023). Roads to Removal. Options for Carbon Dioxide Removal in the United States. Chapter 7. Direct Air Capture with Storage (DACS) and Renewable Energy. Link to source: https://roads2removal.org/wp-content/uploads/07_RtR_Direct-Air-Capture.pdf

Scott, M. and T. Slavin (2023) Fossil-fuel industry embrace raises alarm bells over direct air capture. Reuters. Link to source: https://www.reuters.com/sustainability/climate-energy/fossil-fuel-industry-embrace-raises-alarm-bells-over-direct-air-capture-2023-10-10/

Skone, T. J. (2021) Life Cycle Greenhouse Gas Analysis of Direct Air Capture Systems. National Energy Technology Laboratory. Link to source: https://netl.doe.gov/sites/default/files/netl-file/21DAC_Skone.pdf

Terlouw, T., Treyer, K., Bauer, C., & Mazzotti, M. (2021). Life cycle assessment of direct air carbon capture and storage with low-carbon energy sources. Environmental science & technology, 55(16), 11397-11411. Link to source: https://pubs.acs.org/doi/10.1021/acs.est.1c03263

U. S. Department of Energy, Fossil Energy and Carbon Management (2024) Direct Air Capture Explained. https://www.energy.gov/sites/default/files/2024-08/Direct%20Air%20Capture%20Factsheet_August%202024.pdf

Wang, J., Li, S., Deng, S., Zeng, X., Li, K., Liu, J., ... & Lei, L. (2023). Energetic and life cycle assessment of direct air capture: a review. Sustainable Production and Consumption, 36, 1-16. Link to source: https://www.sciencedirect.com/science/article/abs/pii/S2352550922003384

World Resources Institute. (no date) U.S. Climate Policy Resource Center, Direct Air Capture. Link to source: https://www.wri.org/us-climate-policy-implementation/sectors/direct-air-capture

Young, J., McQueen, N., Charalambous, C., Foteinis, S., Hawrot, O., Ojeda, M., ... & Van Der Spek, M. (2023). The cost of direct air capture and storage can be reduced via strategic deployment but is unlikely to fall below stated cost targets. One Earth 6, 899–917. Link to source: https://www.sciencedirect.com/science/article/pii/S2590332223003007?ref=pdf_download&fr=RR-2&rr=96c1a3aebb261758

Credits

Lead Fellows

Jonathan Foley, Ph.D.
Christina Swanson, Ph.D.

Internal Reviewer

Sarah Gleeson, Ph.D.

Methodology

Comments / Questions

Greenhouse gas quantity expressed relative to CO₂ with the same warming impact over 100 years, calculated by multiplying emissions by the 100-yr GWP for the emitted gases.
Greenhouse gas quantity expressed relative to CO₂ with the same warming impact over 20 years, calculated by multiplying emissions by the 20-yr GWP for the emitted gases.
8th World Congress on Conservation Agriculture
Reducing greenhouse gas concentrations in the atmosphere by preventing or reducing emissions.
The process of increasing acidity.
The extent to which emissions reduction or carbon removal is above and beyond what would have occurred without implementing a particular action or solution.
An upper limit on solution adoption based on physical or technical constraints, not including economic or policy barriers. This level is unlikely to be reached and will not be exceeded.
The quantity and metric to measure implementation for a particular solution that is used as the reference unit for calculations within that solution.
A composting method in which organic waste is processed in freestanding piles that can be aerated actively with forced air or passively by internal convection.
The interactions of aerodynamic forces and flexible structures, often including the stucture's control system.
A process in which microbes break down organic materials in the presence of oxygen. This process converts food and green waste into nutrient-rich compost.
Farming practices that work to create socially and ecologically sustainable food production.
Addition of trees and shrubs to crop or animal farming systems.
Spread out the cost of an asset over its useful lifetime.
A crop that live one year or less from planting to harvest; also called annual.
aerated static piles
black carbon
Made from material of biological origin, such as plants, animals, or other organisms.
A renewable energy source generated from organic matter from plants and/or algae.
An energy source composed primarily of methane and CO₂ that is produced by microorganisms when organic matter decomposes in the absence of oxygen.
Carbon stored in biological matter, including soil, plants, fungi, and plant products (e.g., wood, paper, biofuels). This carbon is sequestered from the atmosphere but can be released through decomposition or burning.
Living or dead renewable matter from plants or animals, not including organic material transformed into fossil fuels. Peat, in early decay stages, is partially renewable biomass.
Biogas refined to the same quality as natural gas. CO₂ and impurities are removed, and the biomethane can be distributed and used in existing natural gas technologies.
A type of carbon sequestration that captures carbon from CO₂ via photosynthesis and stores it in soils, sediments, and biomass, distinct from sequestration through chemical or industrial pathways.
A climate pollutant, also called soot, produced from incomplete combustion of organic matter, either naturally (wildfires) or from human activities (biomass or fossil fuel burning).
A secure, decentralized way of digitally tracking transactions that could be used to improve the transparency and efficiency of carbon markets.
High-latitude (>50°N or >50°S) climate regions characterized by short growing seasons and cold temperatures.
The components of a building that physically separate the indoors from the outdoor environment.
Businesses involved in the sale and/or distribution of solution-related equipment and technology, and businesses that want to support adoption of the solution.
A chemical reaction involving heating a solid to a high temperature; to make cement clinker, limestone is calcined into lime in a process that requires high heat and produces CO₂.
The ratio of the actual electricity an energy technology generates over a period of time to the maximum it could have produced if it operated at full capacity continuously.
A four-wheeled passenger vehicle.
Average number of people traveling in a car per trip.
Technologies that collect CO₂ before it enters the atmosphere, preventing emissions at their source. Collected CO₂ can be used onsite or in new products, or stored long term to prevent release.
A greenhouse gas that is naturally found in the atmosphere. Its atmospheric concentration has been increasing due to human activities, leading to warming and climate impacts.
Total GHG emissions resulting from a particular action, material, technology, or sector.
Amount of GHG emissions released per activity or unit of production.
A marketplace where carbon credits are purchased and sold. One carbon credit represents activities that avoid, reduce, or remove one metric ton of GHG emissions.
A colorless, odorless gas released during the incomplete combustion of fuels containing carbon. Carbon monoxide can harm health and be fatal at high concentrations.
The time it takes for the emissions reduction from a measure to equal the emissions invested in implementing the measure.
Activities or technologies that pull CO₂ out of the atmosphere, including enhancing natural carbon sinks and deploying engineered sinks.
Long-term storage of carbon in soils, sediment, biomass, oceans, and geologic formations after removal of CO₂ from the atmosphere or CO₂ capture from industrial and power generation processes.
carbon capture and storage
carbon capture, utilization, and storage
A binding ingredient in concrete responsible for most of concrete’s life-cycle emissions. Cement is made primarily of clinker mixed with other mineral components.
chlorofluorocarbon
methane
Energy sources that have little to no negative environmental or climate impacts during operation relative to fossil fuel–based energy sources.
Gases or particles that have a planet-warming effect when released to the atmosphere. Some climate pollutants also cause other forms of environmental damage.
A binding ingredient in cement responsible for most of the life-cycle emissions from cement and concrete production.
A waste management process where waste is made into the same original product, preserving quality and value so materials can be reused multiple times while keeping resources in continuous use.
carbon monoxide
Neighbors, volunteer organizations, hobbyists and interest groups, online communities, early adopters, individuals sharing a home, and private citizens seeking to support the solution.
A solution that potentially lowers the benefit of another solution through reduced effectiveness, higher costs, reduced or delayed adoption, or diminished global climate impact.
A farming system that combines reduced tillage, cover crops, and crop rotations.
A risk-sharing financial agreement in which two parties (e.g., renewable generator, government) guarantee a fixed price (e.g., electricity price). If market prices fluctuate, one party pays the other the difference.
carbon dioxide
A measure standardizing the warming effects of greenhouse gases relative to CO₂. CO₂-eq is calculated as quantity (metric tons) of a particular gas multiplied by its GWP.
carbon dioxide equivalent
Plant materials left over after a harvest, such as stalks, leaves, and seed husks.
A granular material made by crushing broken or waste glass.
direct air capture
Financial agreements in which government creditors forgive a portion of debt in exchange for specific conservation commitments.
The process of cutting greenhouse gas emissions (primarily CO₂) from a particular sector or activity.
An industrial process that removes printing ink from used or waste paper fibers, creating clean pulp that can be turned into new paper products.
A solution that works slower than gradual solutions and is expected to take longer to reach its full potential.
Microbial conversion of nitrate into inert nitrogen gas under low-oxygen conditions, which produces the greenhouse gas nitrous oxide as an intermediate compound.
Greenhouse gas emissions produced as a direct result of the use of a technology or practice.
A window consisting of two glass panes separated by a sealed gap and typically filled with air or an inert gas to improve the heat flow resistance.
A waste management system that transforms waste into different products of lower quality and value, making materials harder to recycle again and limiting reuse.
Ability of a solution to reduce emissions or remove carbon, expressed in CO₂-eq per installed adoption unit. Effectiveness is quantified per year when the adoption unit is cumulative over time.
A process that uses electric current to drive a reaction, such as using electricity to split water molecules into hydrogen and oxygen.
Greenhouse gas emissions accrued over the lifetime of a material or product, including as it is produced, transported, used, and disposed of.
Solutions that work faster than gradual solutions, front-loading their impact in the near term.
Methane produced by microbes in the digestive tracts of ruminant livestock, such as cattle, sheep and goats.
U.S. Environmental Protection Agency
expanded polystyrene
environmental, social, and governance
exchange-traded fund
A process triggered by an overabundance of nutrients in water, particularly nitrogen and phosphorus, that stimulates excessive plant and algae growth and can harm aquatic organisms.
Electric vehicle
An ecological process that releases water into the atmosphere as a gas from soil and ice (evaporation) and plants (transpiration).
The scientific literature that supports our assessment of a solution's effectiveness.
A group of human-made molecules that contain fluorine atoms. They are potent greenhouse gases with GWPs that can be hundreds to thousands times higher than CO₂.
Food, agriculture, land, and ocean
Food and Agriculture Organization of the United Nations
feed conversion ratio
The efficiency with which an animal converts feed into increased body mass, measured as the ratio of the weight of the feed given to weight gain. Lower FCR means less feed for the same growth.
Raw material inputs for manufacturing, processing, and managing waste.
Containing or consisting of iron.
A measure of fishing activity over time and area, commonly measured by number of trips, vessel time, or gear deployed.
food loss and waste
Food discarded during pre-consumer supply chain stages, including production, harvest, and processing.
Food discarded during pre-consumer supply chain stages, including production, harvest, and processing, along with food discarded wt the retail and consumer stages of the supply chain.
Food discarded at the retail and consumer stages of the supply chain.
Combustible materials found in Earth's crust that can be burned for energy, including oil, natural gas, and coal. They are formed from decayed organisms through prehistoric geological processes.
Unintentional leaks of gases or vapor into the atmosphere.
Unintentional leaks of gases or vapor into the atmosphere.
A group of countries representing the majority of the world's population, trade, and GDP. There are 19 member countries plus the European Union and the African Union
greenhouse gas
gigajoule or billion joules
The glass layers or panes in a window.
A measure of how effectively a gas traps heat in the atmosphere relative to CO₂. GWP converts greenhouse gases into CO₂-eq emissions based on their 20- or 100-year impacts.
A solution that has a steady impact on the atmosphere. Effectiveness is expected to be constant over time rather than having a higher impact in the near or long term.
A fixed income debt instrument focused on sustainable projects. Green bonds work in the same manner as traditional bonds and may be issued by corporations, financial institutions, and governments.
Biomass discarded during landscaping and gardening.
A gas that traps heat in the atmosphere, contributing to climate change.
The makeup of electricity generation on a power grid, showing the share contributed by various energy sources (e.g., coal, natural gas, nuclear, wind, solar, hydro) relative to total electricity production.
metric gigatons or billion metric tons
global warming potential
hectare
household air pollution
hydrochlorofluorocarbon
Number of years a person is expected to live without disability or other limitations that restrict basic functioning and activity.
A unit of land area comprising 10,000 square meters, roughly equal to 2.5 acres.
Hybrid electric car
hydrofluorocarbon
hydrofluoroolefin
hydrofluoroolefin
Particles and gases released from use of polluting fuels and technologies such as biomass cookstoves that cause poor air quality in and around the home.
heating, ventilation, air conditioning, and refrigeration
Organic compounds that contain hydrogen and carbon.
Human-made F-gases that contain hydrogen, fluorine, and carbon. They typically have short atmospheric lifetimes and GWPs hundreds or thousands times higher than CO₂.
Human-made F-gases that contain hydrogen, fluorine, and carbon, with at least one double bond. They have low GWPs and can be climate-friendly alternatives to HFC refrigerants.
Hydrogen is a gas that can be a fuel, feedstock, or means of storing energy. It generates water instead of GHG when burned, but the process of producing it can emit high levels of GHGs.
Hydrogen is a gas that can be a fuel, feedstock, or means of storing energy. It generates water instead of GHG when burned, but the process of producing it can emit high levels of GHGs.
A recycling process that separates fibers from contaminants for reuse. Paper or cardboard is mixed with water to break down fibrous materials into pulp.
internal combustion engine
Aerobic decomposition of organic waste in a sealed container or bin/bay system.
Greenhouse gas emissions produced as a result of a technology or practice but not directly from its use.
Device used to power vehicles by the intake, compression, combustion, and exhaust of fuel that drives moving parts.
The annual discount rate that balances net cash flows for a project over time. Also called IRR, internal rate of return is used to estimate profitability of potential investments.
Individuals or institutions willing to lend money in search of a return on their investment.
Intergovernmental Panel on Climate Change
Indigenous peoples’ land
Integrated pest management.
internal rate of return
International Union for Conservation of Nature
The most comprehensive global list of species threatened with extinction, maintained by the International Union for Conservation of Nature.
International agreement adopted in 2016 to phase down the use of high-GWP HFC F-gases over the time frame 2019–2047.
A measure of energy equivalent to the energy delivered by 1,000 watts of power over one hour.
kiloton or one thousand metric tons
kilowatt-hour
A land-holding system, e.g. ownership, leasing, or renting. Secure land tenure means farmers or other land users will maintain access to and use of the land in future years.
Gases, mainly methane and CO₂, created by the decomposition of organic matter in the absence of oxygen.
levelized cost of electricity
leak detection and repair
Regular monitoring for fugitive methane leaks throughout oil and gas, coal, and landfill sector infrastructure and the modification or replacement of leaking equipment.
Relocation of emissions-causing activities outside of a mitigation project area rather than a true reduction in emissions.
The rate at which solution costs decrease as adoption increases, based on production efficiencies, technological improvements, or other factors.
Percent decrease in costs per doubling of adoption.
A metric describing the expected break-even cost of generating electricity per megawatt-hour ($/MWh), combining costs related to capital, operation, and fuel (if used) and dividing by total output over the generator's lifetime.
landfill gas
Greenhouse gas emissions from the sourcing, production, use, and disposal of a technology or practice.
The total weight of an organism before any meat processing.
low- and middle-income countries
liquefied petroleum gas
land use change
A measure of the amount of light produced by a light source per energy input.
live weight
marginal abatement cost curve
Livestock grazing practices that strategically manage livestock density, grazing intensity, and timing. Also called improved grazing, these practices have environmental, soil health, and climate benefits, including enhanced soil carbon sequestration.
A tool to measure and compare the financial cost and abatement benefit of individual actions based on the initial and operating costs, revenue, and emission reduction potential.
Defined by the International Union for Conservation of Nature as: "A clearly defined geographical space, recognised, dedicated and managed, through legal or other effective means, to achieve the long-term conservation of nature with associated ecosystem services and cultural values." References to PAs here also include other effective area-based conservation measures defined by the IUCN.
A facility that receives recyclable waste from residential, commercial, and industrial sources; separates, processes, and prepares them; and then sells them to manufacturers for reuse in new products.
A measure of energy equivalent to the energy delivered by one million watts of power over one hour.
A greenhouse gas with a short lifetime and high GWP that can be produced through a variety of mechanisms including the breakdown of organic matter.
A measure of mass equivalent to 1,000 kilograms (~2,200 lbs).
million hectares
Soils mostly composed of inorganic materials formed through the breakdown of rocks. Most soils are mineral soils, and they generally have less than 20% organic matter by weight.
A localized electricity system that independently generates and distributes power. Typically serving limited geographic areas, mini-grids can operate in isolation or interconnected with the main grid.
Reducing the concentration of greenhouse gases in the atmosphere by cutting emissions or removing CO₂.
megajoule or one million joules
Percent of trips made by different passenger and freight transportation modes.
Marine Protected Area
materials recovery facility
Municipal solid waste
megaton or million metric tons
Materials discarded from residential and commercial sectors, including organic waste, glass, metals, plastics, paper, and cardboard.
Megawatt-hour
micro wind turbine
square meter kelvins per watt (a measure of thermal resistance, also called R-value)
The enclosed housing at the top of a wind turbine tower that contains the main mechanical and electrical components of the turbine.
A commitment from a country to reduce national emissions and/or sequester carbon in alignment with global climate goals under the Paris Agreement, including plans for adapting to climate impacts.
A gaseous form of hydrocarbons consisting mainly of methane.
Chemicals found in nature that are used for cooling and heating, such as CO₂, ammonia, and some hydrocarbons. They have low GWPs and are ozone friendly, making them climate-friendly refrigerants.
Microbial conversion of ammonia or ammonium to nitrite and then to nitrate under aerobic conditions.
A group of air pollutant molecules composed of nitrogen and oxygen, including NO and NO₂.
A greenhouse gas produced during fossil fuel combustion and agricultural and industrial processes. N₂O is hundreds of times more potent than CO₂ at trapping atmospheric heat, and it depletes stratospheric ozone.
Metals or alloys that do not contain significant amounts of iron.
Social welfare organizations, civic leagues, social clubs, labor organizations, business associations, and other not-for-profit organizations.
A material or energy source that relies on resources that are finite or not naturally replenished at the rate of consumption, including fossil fuels like coal, oil, and natural gas.
nitrogen oxides
nitrous oxide
The process of increasing the acidity of seawater, primarily caused by absorption of CO₂ from the atmosphere.
An agreement between a seller who will produce future goods and a purchaser who commits to buying them, often used as project financing for producers prior to manufacturing.
Waste made of plant or animal matter, including food waste and green waste.
organic waste
Protected Area
Productive use of wet or rewetted peatlands that does not disturb the peat layer, such as for hunting, gathering, and growing wetland-adapted crops for food, fiber, and energy.
A legally protected area that lacks effective enforcement or management, resulting in minimal to no conservation benefit.
Airborne particles composed of solids and liquids.
A measure of transporting one passenger over a distance of one kilometer.
Incentive payments to landowners or managers to conserve natural resources and promote healthy ecological functions or ecosystem services.
Small, hardened pieces of plastic made from cooled resin that can be melted to make new plastic products.
The longevity of any greenhouse gas emission reductions or removals. Solution impacts are considered permanent if the risk of reversing the positive climate impacts is low within 100 years.
Payments for ecosystem services
A mixture of hydrocarbons, small amounts of other organic compounds, and trace amounts of metals used to produce products such as fuels or plastics.
Per- and polyfluoroalkyl substances, a class of synthetic chemicals that do not degrade easily in the environment. They can pollute the environment and can have negative impacts on human health.
Reduce the use of a material or practice over time.
Eliminate the use of a material or practice over time.
Plug-in hybrid electric car
Private, national, or multilateral organizations dedicated to providing aid through in-kind or financial donations.
An atmospheric reaction among sunlight, VOCs, and nitrogen oxide that leads to ground-level ozone formation. Ground-level ozone, a component of smog, harms human health and the environment.
The process by which sunlight is converted into electricity. When light hits certain materials, such as those in solar panels, it mobilizes electrons, creating an electric current.
polyisocyanurate
The adjustment of turbine blade angles around their long axis in which a control system rotates blades slightly forward or backward to regulate wind capture and optimize electricity generation.
passenger kilometer
particulate matter
Particulate matter 2.5 micrometers or less in diameter that can harm human health when inhaled.
Elected officials and their staff, bureaucrats, civil servants, regulators, attorneys, and government affairs professionals.
System in a vehicle that generates power and delivers it to the wheels. It typically includes an engine and/or motor, transmission, driveshaft, and differential.
Purchase Power Agreement.
People who most directly interface with a solution and/or determine whether the solution is used and/or available.
A substance that is the starting material for a chemical reaction that forms a different substance.
Extraction of naturally occurring resources from the Earth, including mining, logging, and oil and gas refining. These resources can be used in raw or minimally processed forms to produce materials.
The process of converting inorganic matter, including carbon dioxide, into organic matter (biomass), primarily by photosynthetic organisms such as plants and algae.
Defined by the International Union for the Conservation of Nature as "A clearly defined geographical space, recognised, dedicated and managed, through legal or other effective means, to achieve the long-term conservation of nature with associated ecosystem services and cultural values". References to PAs here also include other effective area-based conservation measures defined by the IUCN.
A process that separates and breaks down wood and other raw materials into fibers that form pulp, the base ingredient for making paper products.
polyurethane
Long-term contract between a company (the buyer) and a renewable energy producer (the seller).
photovoltaic
research and development
A situation in which improvements in efficiency or savings lead to consumers increasing consumption, partially or fully offsetting or exceeding the emissions or cost benefits.
renewable energy certificate
Chemical or mixture used for cooling and heating in refrigeration, air conditioning, and heat pump equipment. Refrigerants absorb and release heat as they move between states under changing pressure.
The amount of refrigerant needed for a particular refrigeration, air conditioning, or heat pump system.
A group of approaches to farming and ranching that emphasizes enhancing the health of soil by restoring its carbon content and providing other benefits to the farm and surrounding ecosystem.
A solution that can increase the beneficial impact of another solution through increased effectiveness, lower costs, improved adoption, enhanced global climate impact, and/or other benefits to people and nature.
A material or energy source that relies on naturally occuring and replenishing resources such as plant matter, wind, or sunlight.
A market-based instrument that tracks ownership of renewable energy generation.
The moldable form of raw plastic material, created by melting down waste or virgin plastics and serving as the building block for creating new plastic goods.
A class of animals with complex stomachs that can digest grass. Most grazing livestock are ruminants including cows, sheep, and goats along with several other species.
sustainable aviation fuel
A wetland ecosystem regularly flooded by tides and containing salt-tolerant plants, such as grasses and herbs.
Very large or small numbers are formatted in scientific notation. A positive exponent multiplies the number by powers of ten; a negative exponent divides the number by powers of ten.
Seasonal coefficient of performance
Sustainable Development Goals
Average units of heat energy released for every unit of electrical energy consumed, used to measure heat pump efficiency.
A practice in which multiple utility companies own and operate high-voltage power lines, sharing both costs and benefits.
A window consisting of one glass pane without any additional insulating layers.
Small-scale family farmers and other food producers, often with limited resources, usually in the tropics. The average size of a smallholder farm is two hectares (about five acres).
soil organic carbon
Carbon stored in soils, including both organic (from decomposing plants and microbes) and inorganic (from carbonate-containing minerals).
Carbon stored in soils in organic forms (from decomposing plants and microbes). Soil organic carbon makes up roughly half of soil organic matter by weight.
Biologically derived matter in soils, including living, dead, and decayed plant and microbial tissues. Soil organic matter is roughly half carbon on a dry-weight basis.
soil organic matter
A substance that takes up another liquid or gas substance, either by absorbtion or adsorption.
sulfur oxides
sulfur dioxide
The rate at which a climate solution physically affects the atmosphere after being deployed. At Project Drawdown, we use three categories: emergency brake (fastest impact), gradual, or delayed (slowest impact).
Climate regions between latitudes 23.4° to 35° above and below the equator characterized by warm summers and mild winters.
A polluting gas produced primarily from burning fossil fuels and industrial processes that directly harms the environment and human health.
A group of gases containing sulfur and oxygen that predominantly come from burning fossil fuels. They contribute to air pollution, acid rain, and respiratory health issues.
Processes, people, and resources involved in producing and delivering a product from supplier to end customer, including material acquisition.
Sport utility vehicle
metric ton
metric tons
Technology developers, including founders, designers, inventors, R&D staff, and creators seeking to overcome technical or practical challenges.
Climate regions between 35° to 50° above and below the equator characterized by moderate mean annual temperatures and distinct seasons, with warm summers and cold winters.
A measure of energy equivalent to the energy delivered by one trillion watts of power over one hour.
trifluoroacetic acid
trifluoroacetic acid
A measure of how well a material prevents heat flow, often called R-value or RSI-value for insulation. A higher R-value means better thermal performance.
Individuals with an established audience for their work, including public figures, experts, journalists, and educators.
Charges for disposal of materials paid to facility operators. Fees can be charged per ton of waste disposed or based on economic indicators such as the Consumer Price Index.
A window consisting of three panes of glass separated by two insulating inert gas-filled layers, providing more heat flow resistance than single or double glazing.
Low-latitude (23.4°S to 23.4°N) climate regions near the Equator characterized by year-round high temperatures and distinct wet and dry seasons.
Terawatt, equal to 1,000 gigawatts
terawatt-hour
United Nations
United Nations Environment Programme
Self-propelled machine for transporting passengers or freight on roads.
A measure of one vehicle traveling a distance of one kilometer.
Aerobic decomposition of organic waste by earthworms and microorganisms.
vehicle kilometer
volatile organic compound
Gases made of organic, carbon-based molecules that are readily released into the air from other solid or liquid materials. Some VOCs are greenhouse gases or can harm human health.
watt (a measure of power or energy transfer.)
Landscape waste, storm debris, wood processing residues, and recovered post-consumer wood.
A measure of power equal to one joule per second.
Aerobic decomposition of organic waste in long, narrow rows called windrows. Windrows are generally twice as long as they are wide.
A subset of forest ecosystems that may have sparser canopy cover, smaller-stature trees, and/or trees characterized by basal branching rather than a single main stem.
extruded polystyrene
The rotation of the nacelle (the enclosed housing at the top of a wind turbine tower that contains the main mechanical and electrical components of the turbine) so that the rotor blades are always facing directly into the wind.
year