These are potential solutions that might hold some real promise — but they are still in R&D, or have very limited real world use, or lack enough independent evidence to judge their potential impact. We will continue to watch these solutions, and update when appropriate.
Nuclear fusion combines two elements in a nuclear reaction to form a larger element and release energy that can be used to generate electricity. Nuclear fusion has been researched since the 1950s, but there have been no nuclear fusion plants built to date. Globally, electricity production mainly relies on fossil fuels, with an increasing portion being generated by renewable sources such as wind and solar. However, wind and solar alone are unable to provide baseload electricity (the minimum amount of electric power delivered to an electrical grid) due to their intermittent nature, and energy storage is required for grid reliability. Advantages of nuclear fusion include reducing reliance on fossil fuels for electricity generation, producing emission-free electricity during operation, being inherently safer than nuclear fission, generating minimal nuclear waste, and providing baseload power. Disadvantages include technical challenges, high costs, and uncertainty around regulations. We conclude that Nuclear Fusion is “Worth Watching” but is currently unproven and extremely expensive.
Based on our analysis, nuclear fusion is a promising alternative form of electricity generation, but it is still at a theoretical stage and will not be ready for large-scale deployment within the next 10–15 years, when it could have the most impact on meeting global climate targets. This potential climate solution is “Worth Watching.”
| Plausible | Could it work? | Yes |
|---|---|---|
| Ready | Is it ready? | No |
| Evidence | Are there data to evaluate it? | Limited |
| Effective | Does it consistently work? | No |
| Impact | Is it big enough to matter? | Yes |
| Risk | Is it risky or harmful? | No |
| Cost | Is it cheap? | No |
Nuclear fusion is the process by which two individual elements are fused together into a single larger element using high pressure and temperature; this reaction releases large amounts of energy. This is the same reaction that happens in stars such as the Sun. The energy from the fusion reaction can then be harnessed to produce electricity without emitting any GHG emissions. Nuclear fusion power plants are best suited for centralized, large-scale generation (between 500 MW and 1.2 GW of electricity output).
Nuclear fusion experiments have been carried out that prove the scientific principle is sound. However, only in recent years have experiments succeeded in producing more energy than was needed to initiate and sustain the fusion reaction. There have been no nuclear fusion power plants built to date, and it is unlikely that nuclear fusion-powered electricity generation will be ready for deployment before 2050.
Nuclear fusion energy offers several advantages as a solution to climate change, including high power density, the ability to deliver “firm” power (i.e., power that can be relied upon to meet demand when needed), and no greenhouse gas emissions. In addition, the most commonly used fuel for nuclear fusion – hydrogen – is readily accessible, there is no risk of a nuclear meltdown, and the process produces relatively little nuclear waste, meaning the risk of nuclear proliferation is almost nonexistent. Some research suggests that nuclear fusion could provide up to 15% of total electricity production either by replacing existing centralized power plants (e.g., oil and gas, coal, nuclear fission) that have reached end-of-life or to satisfy growing demand for electricity as access and electrification increase.
Nuclear fusion is not considered remotely close to being ready to deploy as a climate solution. It faces many technical challenges, including uncertainties related to fusion reactor design and optimal fuel types. The costs for nuclear fusion-produced electricity are highly uncertain and are expected to grow compared to existing estimates. Current estimates for nuclear fusion energy costs exceed US$150/MWh, nearly double the 2020 price per MWh for other energy sources. There are also large uncertainties about the policy environment for nuclear fusion plants, which could hinder both development and deployment. Currently, projections suggest that nuclear fusion reactors could be introduced between 2050 and 2060. This means that even under optimistic conditions, nuclear fusion is unlikely to make a significant contribution to meeting 2050 emissions reduction targets.
Barbarino, M. (2020). A brief history of nuclear fusion. Nature Physics, 16, 890-893. https://www.nature.com/articles/s41567-020-0940-7
Barbarino, M. (2023, August 3). What is nuclear fusion?. IAEA. https://www.iaea.org/newscenter/news/what-is-nuclear-fusion
Foster, J., Lux, H., Knight, S., Wolff, D., & Muldrew, S. I. (2024). Extrapolating costs to commercial fusion power plants. IEEE, 52(9), 3772-3777. https://doi.org/10.1109/TPS.2024.3362428
Kembleton, R. (2019). Nuclear fusion: What of the future. Managing Global Warming, 199-220. https://www.sciencedirect.com/science/article/abs/pii/B9780128141045000053
Lerede, D., Nicoli, M., Savoldi, L., & Trotta, A. (2023). Analysis of the possible contribution of different nuclear fusion technologies to the global energy transition. Energy Strategy Reviews, 49. https://www.sciencedirect.com/science/article/pii/S2211467X23000949
Lindley, B. Roulstone, T., Locatelli, G., & Rooney, M. (2023). Can fusion energy be cost-competitive and commercially viable? An analysis of magnetically confined reactors. Energy Policy, 177. https://www.sciencedirect.com/science/article/abs/pii/S0301421523000964
Lopes Cardozo, N. J., Lange, A. G. G., & Kramer, G. J. (2016). Fusion: Expensive and taking forever?. Journal of Fusion Energy, 35, 94-101. https://link.springer.com/article/10.1007/s10894-015-0012-7
Meschini, S., Laviano, F., Ledda, F., Pettinari, D., Testoni, R., Torsello, D., & Panella, B. (2023). Frontiers, 11. https://www.frontiersin.org/journals/energy-research/articles/10.3389/fenrg.2023.1157394/full
MIT Energy Initiative. (2024). The role of fusion energy in a decarbonized electricity system. Massachusetts Institute of Technology https://energy.mit.edu/wp-content/uploads/2024/09/MITEI_FusionReport_091124_final_COMPLETE-REPORT_fordistribution.pdf
Tokimatsu, K., Fujino, J., Konishi, S., Ogawa, Y., & Yamaji, K. (2003). Role of nuclear fusion in future energy systems and the environment under future uncertainties. Energy Policy, 31(8), 775-797. https://www.sciencedirect.com/science/article/abs/pii/S0301421502001271
Feed additives can reduce enteric methane production in ruminant livestock, such as cattle, goats, and sheep. Most feed additive compounds are still being researched to determine their efficacy and safety; however, at least one product, 3-NOP (3-nitrooxypropanol), has been shown to be effective, has recently been approved for use in several countries, and has experienced some early adoption. However, because of cost and the need to be administered daily, the use of feed additives is currently limited to confined ruminants in high-income countries and is not feasible for the majority of global ruminant livestock. Based on these limitations and current levels of adoption, we conclude that Use Feed Additives is “Worth Watching.”
Based on our analysis, feed additives are a promising technology that could yield globally meaningful reductions in methane emissions. A few, including 3-NOP, are just on the threshold of commercial adoption and may be widely used by confined ruminant producers in the coming years. The current use of feed additives is low, and the effectiveness of most feed additive compounds is not well-documented. Consequently, wide-scale adoption is largely confined to confined livestock in high-income countries. Based on our assessment, Use Feed Additives is “Worth Watching."
| Plausible | Could it work? | Yes |
|---|---|---|
| Ready | Is it ready? | No |
| Evidence | Are there data to evaluate it? | Yes |
| Effective | Does it consistently work? | Yes |
| Impact | Is it big enough to matter? | Yes |
| Risk | Is it risky or harmful? | No |
| Cost | Is it cheap? | Yes |
Feed additives are a diverse group of natural and synthetic compounds that, when fed daily, can reduce enteric methane production in ruminant livestock, including cattle, sheep, and goats. Enteric methane from livestock is the source of 21% of humanity’s methane emissions, or 2.9 Gt CO₂‑eq/yr. Feed additives reduce enteric methane production by suppressing the activity of microbes in the digestive system. 3-NOP (3-nitrooxypropanol) is a synthetic that inhibits an enzyme involved in enteric methane production.
More than 170 different feed additives have been developed and tested so far, but only a few of them have been studied enough to offer predictable outcomes and proper doses. Methane reductions from these well-studied additives typically range from 10-30%. The feed additive 3-NOP, the first compound approved for commercial use, reduces enteric methane by an average of 32.5%. A second feed additive derived from active compounds found in Asparagopsis seaweed has shown promising results in some studies and has recently received regulatory approval in two countries. In addition, because different feed additives use different mechanisms to suppress enteric methane production, it’s possible that multiple additives can be used together to achieve greater methane reductions. The great majority of other additives are not yet ready for widespread adoption due to a lack of understanding of effectiveness, side effects on cattle and humans who consume milk from treated cattle, and other concerns.
Ruminants are a major source of methane emissions, yet ruminant meat and dairy products are in high demand. Therefore, any strategy that can reduce methane emissions per kilogram of meat or milk is potentially very valuable and, if broadly adopted, could yield globally meaningful reductions in methane emissions (>0.1 Gt CO₂‑eq per year). The feed additive 3-NOP, first approved for commercial use in two countries in 2021, is now legal in 55 countries. Research on other feed additives is active and generally well-supported with funding from philanthropic and investment sources. Although current use of feed additives is very low, successful research and pilot studies, increasing regulatory approvals, and strong positive interest from the livestock industry suggest that wider-scale adoption of this emissions reduction technology could occur quickly. In addition to potential emissions reduction benefits, some additives offer other benefits such as increased productivity and parasite control.
Because they must be fed daily as a supplement to a concentrated feed, use of feed additives is limited to ruminants managed under confined conditions. Most of the billions of ruminant animals today are raised or managed in extensive grazing or pastoralist systems, often in small herds in remote areas. This makes use of feed additives infeasible, although some research is underway to develop methane-reducing compounds that could be added to water troughs instead of to feed. Feed additives are also costly. Though they may be cost-effective in terms of dollars per ton of CO₂‑eq reduced, the cost of additives themselves would likely be prohibitive for smallholders and pastoralists in low-income countries. These limitations mean that feed additives, as currently under development, are only suitable for a subset of total ruminant livestock – those that are raised in confinement systems in wealthy countries. The great majority of feed additives are not yet ready for widespread adoption due to a lack of understanding of effectiveness, side effects on cattle and humans who consume milk from treated cattle, and other concerns. There are also other challenges, including regulatory issues, public acceptance, and effects on livestock and human health. There is also concern that feed additives could be used to divert attention from the importance of reducing ruminant meat and milk products in the diets of wealthy countries and reducing food waste of ruminant products.
Almeida, A. K., Hegarty, R. S., & Cowie, A. (2021). Meta-analysis quantifying the potential of dietary additives and rumen modifiers for methane mitigation in ruminant production systems. Animal Nutrition, 7(4), 1219-1230.
Batley, R. J., Chaves, A. V., Johnson, J. B., Naiker, M., Quigley, S. P., Trotter, M. G., & Costa, D. F. (2024). Rapid screening of methane-reducing compounds for deployment in livestock drinking water using in vitro and FTIR-ATR analyses. Methane, 3(4), 533-560.
Canadell, J.G., P.M.S. Monteiro, M.H. Costa, L. Cotrim da Cunha, P.M. Cox, A.V. Eliseev, S. Henson, M. Ishii, S. Jaccard, C. Koven, A. Lohila, P.K. Patra, S. Piao, J. Rogelj, S. Syampungani, S. Zaehle, and K. Zickfeld, 2021: Global Carbon and other Biogeochemical Cycles and Feedbacks. In Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change [Masson-Delmotte, V., P. Zhai, A. Pirani, S.L. Connors, C. P.an, S. Berger, N. Caud, Y. Chen, L. Goldfarb, M.I. Gomis, M. Huang, K. Leitzell, E. Lonnoy, J.B.R. Matthews, T.K. Maycock, T. Waterfield, O. Yelekci, R. Yu, and B. Zhou (eds.)]. Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, pp. 673–816, doi:10.1017/9781009157896.007
Foley, J. (2021) To stop climate change, time is as important as tech. February 20, 2021, Medium. https://globalecoguy.org/to-stop-climate-change-time-is-as-important-as-tech-1be4beb7094a
Hanson, M. (2024) What can we really expect from Elanco’s new Bovaer ®?. Dairy Herd Management, June 24, 2024. https://www.dairyherd.com/news/education/what-can-we-really-expect-elancos-new-bovaerr
Herrmann, M (2023) The rise of the ‘climate-friendly’ cow. April 26, 2023, DeSmog. https://www.desmog.com/2023/04/26/rise-of-the-climate-friendly-cow/
Hodge, I., Quille, P., & O’Connell, S. (2024). A review of potential feed additives intended for carbon footprint reduction through methane abatement in dairy cattle. Animals, 14(4), 568.
Krogsad, K (2024) Dairy cow enteric carbon mitigation calculator. https://view.officeapps.live.com/op/view.aspx?src=https%3A%2F%2Fdairy.osu.edu%2Fsites%2Fdairy%2Ffiles%2Fimce%2FVideos_and_Software%2FDairy%2520Carbon%2520Return%2520Calculator%25202.0.xlsx&wdOrigin=BROWSELINK
Morse, Cameron (2024) Rumin8 achieves first regulatory approval in New Zealand. July 22, 2024 Rumin8.com. https://rumin8.com/rumin8-achieves-first-regulatory-approval-in-new-zealand/
Morse, Cameron (2024) Rumin8 achieves first regulatory approval in Brazil. October 8, 2024 Rumin8.com.
https://rumin8.com/rumin8-achieves-first-regulatory-approval-in-brazil/
Nabuurs, G-J., R. Mrabet, A. Abu Hatab, M. Bustamante, H. Clark, P. Havlík, J. House, C. Mbow, K.N. Ninan, A. Popp, S. Roe, B. Sohngen, S. Towprayoon, 2022: Agriculture, Forestry and Other Land Uses (AFOLU). In IPCC, 2022: Climate Change 2022: Mitigation of Climate Change. Contribution of Working Group III to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change[P.R. Shukla, J. Skea, R. Slade, A. Al Khourdajie, R. van Diemen, D. McCollum, M. Pathak, S. Some, P. Vyas, R. Fradera, M. Belkacemi, A. Hasija, G. Lisboa, S. Luz, J. Malley, (eds.)]. Cambridge University Press, Cambridge, UK and New York, NY, USA. doi: 10.1017/9781009157926.009
Paddision, Laura (2023) Bill Gates backs start-up tackling cow burps and farts. CNN.com, January 24, 2023. https://www.cnn.com/2023/01/24/world/cows-methane-emissions-seaweed-bill-gates-climate-intl/index.html
Roques, S., Martinez-Fernandez, G., Ramayo-Caldas, Y., Popova, M., Denman, S., Meale, S. J., & Morgavi, D. P. (2024). Recent advances in enteric methane mitigation and the long road to sustainable ruminant production. Annual Review of Animal Biosciences, 12(1), 321-343.
Micro wind turbines harness natural wind to generate electricity. They can operate independently or be connected to a centralized electricity grid, and are useful for small-scale commercial, agricultural, and residential applications. Advantages include reducing reliance on fossil fuels for electricity generation, potential expansion of electrification to rural areas, and improvement in energy equity and independence worldwide. Disadvantages include unpredictable and unreliable electricity generation (especially in urban locations), high cost, and noise pollution. We conclude that Deploy Micro Wind Turbines is “Worth Watching.”
Based on our analysis, micro wind turbines are a promising technology for reducing emissions, but given the limited potential for global adoption and variable financial viability, their climate impact is below our threshold for global climate solutions (<0.1 Gt CO₂‑eq/yr). Despite the low climate impact, Deploy Micro Wind Turbines is an important solution for achieving energy equity. Therefore, this potential climate solution is “Worth Watching.”
| Plausible | Could it work? | Yes |
|---|---|---|
| Ready | Is it ready? | Yes |
| Evidence | Are there data to evaluate it? | Yes |
| Effective | Does it consistently work? | Yes |
| Impact | Is it big enough to matter? | No |
| Risk | Is it risky or harmful? | No |
| Cost | Is it cheap? | No |
Micro wind turbines (MWTs) are small-scale turbines that rely on natural wind to generate electricity, charge batteries, or power equipment. Specific definitions for MWTs vary from country to country. Our analysis assessed energy production and GHG emissions reduction potential for wind turbines rated to generate a maximum of 100 kW of electrical power. MWTs are actively used for a variety of applications, including telecommunications, lighting, and agriculture. The total installed capacity for MWTs globally as of 2023 is nearly 1.8 GW or 0.002% of utility-scale onshore wind capacity. MWTs are most commonly used in rural settings.
When connected to a regional or national electricity grid, MWTs can reduce baseline electricity grid emissions by reducing reliance on fossil fuel energy sources. Off-grid MWTs, which accounted for more than 90% of commercial sales in 2019, help electrify industrial and agricultural processes that otherwise may have been powered by fossil fuels, such as diesel or natural gas. Energy production from MWTs is highly dependent on the availability of consistent wind speeds, with the majority of turbines requiring an average wind speed of around 5 m/s to generate electricity. As long as sufficient wind resources are available, MWTs are effective at producing electricity to meet local energy demand and reduce reliance on fossil fuels.
Micro wind turbines reduce reliance on fossil fuels for electricity generation, whether they are connected to an electric grid or isolated for local energy use. For grid-connected systems, more available renewable energy sources reduce the need for fossil fuel-based energy generation to meet demand. MWTs isolated from the electricity grid still reduce the local carbon footprint of a household, farm, or commercial building. Globally, the average household consumes approximately 17,000 kWh of electricity annually. Depending on the size of the turbine, local wind energy can produce 1,000–20,000 kWh/yr. Fluctuations in wind speed throughout the day and year can lead to unreliable power output, but this risk can be mitigated by integrating batteries or hybrid electricity generation systems, such as combining wind and solar photovoltaics (PV). In addition to emissions reduction, MWTs are crucial tools for expanding electricity access worldwide. Since MWTs can operate independently of an electric grid, they can electrify rural areas where transmission lines are nonexistent or challenging to install. For example, many populations in Africa live in remote areas that could be well-served by installing MWTs to power telecommunications and other local electrification needs. Increasing interest in smart energy systems and Internet of Things technologies presents promising future applications for MWTs.
While micro wind turbines show potential for expanding electrification, they have a number of limitations compared to other small-scale renewable energy technologies, like solar photovoltaics. First, real-world performance due to wind speed variability and turbulence at installation sites can be unpredictable and is often substantially lower than manufacturers’ power ratings. Second, life-cycle emissions from manufacturing and installation can be more than five times higher for small-scale wind than for large, multi-MW turbines. Energy payback times – the time period for the MWT to generate enough clean energy to offset the energy used during manufacturing and installation – can be long, sometimes exceeding the 20–25 year lifetime of the turbine. Third, MWTs are expensive, ranging from approximately US$3,000/kW to more than US$10,000/kW. Costs to properly assess wind resources at the potential MWT site can be on the order of US$100,000. Finally, noise pollution and vibration are environmental concerns for the wide-scale adoption of MWTs in urban areas. In addition, MWT performance can be poor in urban and suburban areas because buildings and other obstacles disrupt airflow. There is a general consensus in the scientific community and commercial market that MWTs remain a niche technology due to uncertain economic viability and lack of reliable power generation in suburban and urban areas.
Bianchini, A., Bangga, G., Baring-Gould, I., Croce, A., Cruz, J. I., Damiani, R., Erfort, G., Simao Ferreira, C., Infield, D., Nayeri, C. N., Pechlivanoglou, G., Runacres, M., Schepers, G., Summerville, B., Wood, D., & Orrell, A. (2022). Current status and grand challenges for small wind turbine technology. Wind Energy Science, 7(5), 2003–2037. https://doi.org/10.5194/wes-7-2003-2022
Global Wind Energy Council. (2024). Global Wind Report 2024. https://www.gwec.net/reports/globalwindreport
Ismail, K. A. R., Lino, F. A. M., Baracat, P. A. A., De Almeida, O., Teggar, M., & Laouer, A. (2025). Wind Turbines for Decarbonization and Energy Transition of Buildings and Urban Areas: A Review. Advances in Environmental and Engineering Research, 06(01), 1–59. https://doi.org/10.21926/aeer.2501013
Jurasz, J., Bochenek, B., Wieczorek, J., Jaczewski, A., Kies, A., & Figurski, M. (2025). Energy potential and economic viability of small-scale wind turbines. Energy, 322, 135608. https://doi.org/10.1016/j.energy.2025.135608
Pacific Northwest National Laboratory. (2024). Distributed wind market report: 2024 edition (PNNL-36057). Wind Energy Technologies Office, Office of Energy Efficiency and Renewable Energy of the U.S. Department of Energy. https://www.pnnl.gov/distributed-wind/market-report
Pitsilka E. & Kasiteropoulou D., (2024). Wind turbines farms applications. A mini review. International Journal of Research in Engineering and Science (IJRES), 12(2), 36-41.
Rosato, A., Perrotta, A., & Maffei, L. (2024). Commercial small-scale horizontal and vertical wind turbines: A comprehensive review of geometry, materials, costs and performance. Energies, 17(13), 3125. https://doi.org/10.3390/en17133125
Small-Scale Wind Turbines. (2017). In P. A. B. James & A. S. Bahaj, Wind Energy Engineering (pp. 389–418). Elsevier. https://doi.org/10.1016/b978-0-12-809451-8.00019-9
Taylor, J., Eastwick, C., Lawrence, C., & Wilson, R. (2013). Noise levels and noise perception from small and micro wind turbines. Renewable Energy, 55, 120–127. https://doi.org/10.1016/j.renene.2012.11.031
Tummala, A., Velamati, R. K., Sinha, D. K., Indraja, V., & Krishna, V. H. (2016). A review on small scale wind turbines. Renewable and Sustainable Energy Reviews, 56, 1351–1371. https://doi.org/10.1016/j.rser.2015.12.027
Wang, H., Xiong, B., Zhang, Z., Zhang, H., & Azam, A. (2023). Small wind turbines and their potential for internet of things applications. iScience, 26(9), 107674. https://doi.org/10.1016/j.isci.2023.107674
World Wind Energy Association. (2025). WWEA Annual Report 2024. World Wind Wind Energy Association. https://wwindea.org/AnnualReport2024
Zajicek, L., Drapalik, M., Kral, I., & Liebert, W. (2023). Energy efficiency and environmental impacts of horizontal small wind turbines in Austria. Sustainable Energy Technologies and Assessments, 59, 103411. https://doi.org/10.1016/j.seta.2023.103411
Protect Seafloors is the long-term protection of the seafloor from degradation, which helps preserve existing sediment carbon stocks and avoid CO₂ emissions. Advantages of seafloor protection include the conservation of biodiversity and marine ecosystems, potentially low costs, and the ability for immediate implementation. Disadvantages include uncertainties in the effectiveness of legal protection at preventing degradation and in the amount of CO₂ emissions avoided, as well as the risk of displacement of degradation to non-protected areas and/or an increase in other types of degradation. Given these limitations, we conclude that Seafloor Protection is a climate solution “Worth Watching” until more research can clearly show the carbon benefits of protection.
Based on our analysis, seafloor protection could avoid some CO₂ emissions while preserving critical marine ecosystems from degradation. However, the effectiveness of protection and the magnitude of avoided CO₂ emissions associated with protection are understudied and currently unclear, making this potential climate solution “Worth Watching.”
| Plausible | Could it work? | Yes |
|---|---|---|
| Ready | Is it ready? | No |
| Evidence | Are there data to evaluate it? | Limited |
| Effective | Does it consistently work? | No |
| Impact | Is it big enough to matter? | Yes |
| Risk | Is it risky or harmful? | No |
| Cost | Is it cheap? | Yes |
Protect Seafloors aims to reduce human impacts that can degrade sediment carbon stocks and increase CO₂ emissions. Protection is conferred through legal mechanisms, such as Marine Protected Areas (MPAs), which are managed with the primary goal of conserving nature. The seafloor stores over 2,300 Gt of carbon (~8,400 Gt CO₂‑eq) in the top one meter of sediment. This marine carbon can be stable and remain sequestered for millennia. However, degradation of the seafloor from a range of human activities can disturb bottom sediments, resuspending the carbon and increasing its microbial conversion into CO₂. Currently, degradation of the seafloor primarily results from fishing practices, such as trawling and dredging, which are estimated to occur across 1.3% of the global ocean. Additional sources of degradation include undersea mining, infrastructure development (for offshore wind farms, oil, and gas), and laying telecommunications cables. Estimates of seafloor degradation are highly uncertain due to data limitations and the unpredictable nature of how these activities may expand in the future.
More evidence is needed to confirm whether legal seafloor protection is effective at reducing degradation and the extent to which degradation results in increased CO₂ emissions. While ~8% of the seafloor is currently protected through MPAs, there is mixed evidence that legal protection reduces degradation and CO₂ emissions. For instance, in a review of 49 studies examining the impacts of bottom trawling and dredging on sediment organic carbon stocks, most (61%) showed no change, while nearly a third (29%) showed carbon loss. More recent work suggests that trawling intensity might drive these mixed results, with more heavily trawled areas showing clear reductions in sediment organic carbon. Additionally, the few existing global estimates of CO₂ emissions from trawling and dredging range from 0.03 to 0.58 Gt CO₂/yr, highlighting the need for further research. The effectiveness of MPAs at preventing seafloor degradation is also mixed. In strictly protected areas with enforcement of no-take policies that prevent bottom fishing, MPAs could help minimize degradation and retain seafloor carbon. However, implementation can be challenging, as over half of existing MPAs generally allow high-impact activities. For instance, trawling and dredging occur more frequently in MPAs than in non-protected areas in the territorial waters of Europe.
Advantages of seafloor protection include its potential low cost and its ability to conserve often understudied biodiversity and ecosystems. Human activities, such as trawling and dredging, impact marine organisms on the seafloor, and ecosystem recovery can take years to occur. In the case of undersea mining, ecosystems may never fully recover. Increases in CO₂ emissions along the seafloor from degradation can also enhance local acidification and reduce the ocean's buffering capacity, both of which can affect marine organisms and the carbon sequestration capacity of seawater. Protection can also increase fisheries yields in neighboring waters and reduce other negative impacts of seafloor disturbances. While costs are somewhat uncertain, MPA expenses have been estimated to be an order of magnitude less than the often unseen ecosystem service benefits gained with protection, suggesting MPA expansion could provide cost savings.
Disadvantages of seafloor protection include uncertainties surrounding the effectiveness of preventing degradation and avoiding CO₂ emissions, as well as the potential increased risk of disturbance to other ocean areas. The amount and fate of CO₂ generated due to the degradation of seafloor carbon is complex and understudied. It can take months or even centuries for CO₂ produced at depth to reach the sea surface and atmosphere. Current estimates of CO₂ emissions due to dredging and trawling are widely debated and highly variable due to differing methods and assumptions. Large amounts of organic carbon will inevitably re-settle after seafloor disturbances, with no impact on CO₂, but estimates of just how much remain uncertain. The risk of protection-induced leakage, where a reduction in disturbances, such as trawling and dredging in MPAs, leads to increased fishing effort in other ocean areas, is also potentially high.
Amoroso, R. O., Pitcher, C. R., Rijnsdorp, A. D., McConnaughey, R. A., Parma, A. M., Suuronen, P., ... & Jennings, S. (2018). Bottom trawl fishing footprints on the world’s continental shelves. Proceedings of the National Academy of Sciences, 115(43), E10275-E10282. https://doi.org/10.1073/pnas.1802379115
Atwood, T. B., Witt, A., Mayorga, J., Hammill, E., & Sala, E. (2020). Global patterns in marine sediment carbon stocks. Frontiers in Marine Science, 7, 165. https://doi.org/10.3389/fmars.2020.00165
Atwood, T.B., Sala, E., Mayorga, J. et al. Reply to: Quantifying the carbon benefits of ending bottom trawling. Nature, 617, E3–E5 (2023). https://doi.org/10.1038/s41586-023-06015-6
Atwood, T. B., Romanou, A., DeVries, T., Lerner, P. E., Mayorga, J. S., Bradley, D., ... & Sala, E. (2024). Atmospheric CO₂ emissions and ocean acidification from bottom-trawling. Frontiers in Marine Science, 10, 1125137. https://doi.org/10.3389/fmars.2023.1125137
Balmford, A., Gravestock, P., Hockley, N., McClean, C.J. and Roberts, C.M. (2004). The worldwide costs of marine protected areas. Proceedings of the National Academy of Sciences, 101(26), pp.9694-9697. https://doi.org/10.1073/pnas.0403239101
Burdige, D. J. (2005). Burial of terrestrial organic matter in marine sediments: a re-assessment. Global Biogeochem. Cycles, 19:GB4011. https://doi.org/10.1029/2004GB002368
Burdige, D. J. (2007). Preservation of organic matter in marine sediments: controls, mechanisms, and an imbalance in sediment organic carbon budgets? Chem. Rev., 107, 467–485. https://doi.org/10.1021/cr050347q
Carr, M. E., Friedrichs, M. A. M., Schmeltz, M., Aita, M. N., Antoine, D., Arrigo, K., et al. (2006). A comparison of global estimates of marine primary production from ocean color. Deep-sea Res. II, Top. Stud. Oceanogr., 53, 741–770. https://doi.org/10.1016/j.dsr2.2006.01.028
Clare, M. A., Lichtschlag, A., Paradis, S., & Barlow, N. L. M. (2023). Assessing the impact of the global subsea telecommunications network on sedimentary organic carbon stocks. Nature Communications, 14(1), 2080. https://doi.org/10.1038/s41467-023-37854-6
Dureuil, M., Boerder, K., Burnett, K. A., Froese, R., & Worm, B. (2018). Elevated trawling inside protected areas undermines conservation outcomes in a global fishing hot spot. Science, 362(6421), 1403-1407. https://doi.org/10.1126/science.aau0561
Epstein, G., Middelburg, J. J., Hawkins, J. P., Norris, C. R., & Roberts, C. M. (2022). The impact of mobile demersal fishing on carbon storage in seabed sediments. Global Change Biology, 28(9), 2875-2894. https://doi.org/10.1111/gcb.16105
Estes, E. R., Pockalny, R., D’Hondt, S., Inagaki, F., Morono, Y., Murray, R. W., ... & Hansel, C. M. (2019). Persistent organic matter in oxic subseafloor sediment. Nature Geoscience, 12(2), 126-131. https://doi.org/10.1038/s41561-018-0291-5
Kandasamy, S., & Nagender Nath, B. (2016). Perspectives on the terrestrial organic matter transport and burial along the land-deep sea continuum: caveats in our understanding of biogeochemical processes and future needs. Frontiers in Marine Science, 3, 259. https://doi.org/10.3389/fmars.2016.00259
Muller-Karger, F. E., Varela, R., Thunell, R., Luerssen, R., Hu, C., and Walsh, J. J. (2005). The importance of continental margins in the global carbon cycle. Geophys. Res. Lett., 32:L01602. https://doi.org/10.1029/2004gl021346
Putuhena, H., White, D., Gourvenec, S., & Sturt, F. (2023). Finding space for offshore wind to support net zero: A methodology to assess spatial constraints and future scenarios, illustrated by a UK case study. Renewable and Sustainable Energy Reviews, 182, 113358. https://doi.org/10.1016/j.rser.2023.113358
Sala, E., Mayorga, J., Bradley, D., Cabral, R. B., Atwood, T. B., Auber, A., ... & Lubchenco, J. (2021). Protecting the global ocean for biodiversity, food and climate. Nature, 592(7854), 397-402. https://doi.org/10.1038/s41586-021-03371-z
Sala, E., & Giakoumi, S. (2018). No-take marine reserves are the most effective protected areas in the ocean. ICES Journal of Marine Science, 75(3), 1166-1168. https://doi.org/10.1093/icesjms/fsx059
Siegel, D. A., DeVries, T., Doney, S. C., & Bell, T. (2021). Assessing the sequestration time scales of some ocean-based carbon dioxide reduction strategies. Environmental Research Letters, 16(10), 104003. https://doi.org/10.1088/1748-9326/ac0be0
(TMC, 2022) The Metals Company. (2022). How much seafloor will the nodule collection industry impact? Retrieved April 17, 2025, from https://metals.co/how-much-seafloor-will-the-nodule-collection-industry-impact/
UNEP-WCMC and IUCN (2024). Protected Planet Report 2024. UNEP-WCMC and IUCN: Cambridge, United Kingdom; Gland, Switzerland. https://digitalreport.protectedplanet.net/
Zhang, W., Porz, L., Yilmaz, R., Wallmann, K., Spiegel, T., Neumann, A., ... & Schrum, C. (2024). Long-term carbon storage in shelf sea sediments reduced by intensive bottom trawling. Nature Geoscience, 1-9. https://doi.org/10.1038/s41561-024-01581-4
van de Velde, S. J., Hylén, A., & Meysman, F. J. (2025). Ocean alkalinity destruction by anthropogenic seafloor disturbances generates a hidden CO₂ emission. Science Advances, 11(13), https://doi.org/eadp9112.10.1126/sciadv.adp9112
Watson, S. C., Somerfield, P. J., Lemasson, A. J., Knights, A. M., Edwards-Jones, A., Nunes, J., ... & Beaumont, N. J. (2024). The global impact of offshore wind farms on ecosystem services. Ocean & Coastal Management, 249, 107023. https://doi.org/10.1016/j.ocecoaman.2024.107023
