• Methane (CH₄) is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone”.
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

• Methane (CH₄) is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone”.
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

• Methane (CH₄) is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone.”
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

• Methane (CH₄) is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone.”
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

• Methane (CH4) is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone.”
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

• Methane is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone.”
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

• Methane is the second most important anthropogenic greenhouse gas after CO₂ and is responsible for about 30% of global mean temperature increase since the Industrial Revolution (AMAP 2021 full report, IPCC 2021, IEA 2024). Reductions in methane emissions would be effective for short-term cooling of the Earth, as methane is a short-lived constituent of the atmosphere. Methane is also well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. There is high confidence by the IPCC (2021) that “strong, rapid and sustained reductions in methane emissions can limit near-term warming and improve air quality by reducing global surface ozone.”
• Pathways to reduce methane emissions include 1) strengthening methane mitigation policies, 2) reducing leaks and venting in the oil and gas sector, 3) eliminating flaring from oil and gas operations, 4) reducing enteric methane by improving feeding and manure management on farms or other methods, 5) eliminating gas in new construction and phasing out leaky gas stoves, 6) upgrading solid waste and wastewater treatment, and 7) reducing food waste and improving landfill management (Zaelke et al. 2023).
  • The energy sector accounts for about 35% of anthropogenic methane emissions and has the largest potential for abatement in the immediate decades (UNEP and Climate and Clean Air Coalition 2021).
  • The International Energy Association’s Net Zero Emissions by 2050 (NZE) Scenario that limits the global average surface temperature rise to 1.5 °C with no or low overshoot includes a 75% cut in methane emissions from fossil fuel production and use by 2030 (IEA 2024).
• See UNEP and Climate and Clean Air Coalition 2021, 2022, IGSD 2023, and IEA 2024 for more detailed information about methane emissions reductions pathways.

• Methane emissions reduction approaches either emit zero methane emissions or lower current methane emissions. By implementing these technologies, methane emissions will decrease, thereby slowing increases in global mean surface temperature.

• Varies by approach, but likely small spatial footprint
  • Many approaches will have a small spatial footprint and rely on existing infrastructure.

• Mostly on land surface

• Global application
  • Methane is generally well-mixed in the atmosphere, and therefore, methane emissions reductions could happen outside of the Arctic and still make a difference in the Arctic. Methane concentrations are higher in the Northern Hemisphere, although the mechanisms are unclear (Nisbet et al. 2021).

• All year

Impact on

• Unknown

• Global
  • Decrease of 0.28°C to 0.5°C or greater, compared to trajectory with no targeted methane mitigation.
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050 (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023).
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050 compared to trajectory with no targeted methane mitigation.
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030.
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report).

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming.
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022).

Scalability

• Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• < 10 years
  • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term” (IEA 2023).
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease of 0.28°C to 0.5°C or greater, compared to trajectory with no targeted methane mitigation.
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050 (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023).
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050 compared to trajectory with no targeted methane mitigation.
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030.
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report).

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming.
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022).

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• < 10 years
  • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term” (IEA 2023).
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease of 0.28°C to 0.5°C or greater, compared to trajectory with no targeted methane mitigation.
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050 (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023).
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050 compared to trajectory with no targeted methane mitigation.
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030.
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report).

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022)

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• < 10 years
  • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term.” (IEA 2023)
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease 0.28°C - > 0.5°C compared to trajectory with no targeted methane mitigation.
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050 (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023).
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050 compared to trajectory with no targeted methane mitigation.
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030.
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report).

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022)

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• < 10 years
  • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term.” (IEA 2023)
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease 0.28°C - > 0.5°C compared to trajectory with no targeted methane mitigation.
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050. (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023)
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050 compared to trajectory with no targeted methane mitigation.
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report)

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022)

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• < 10 years
  • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term.” (IEA 2023)
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease 0.28°C - > 0.5°C compared to trajectory with no targeted methane mitigation.
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050. (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023)
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050 compared to trajectory with no targeted methane mitigation.
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report)

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022)

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• • < 10 years
    • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term.” (IEA 2023)
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease 0.28°C - > 0.5°C
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050. (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023)
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report)

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022)

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• • < 10 years
    • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021).

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term.” (IEA 2023)
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

Impact on

• Unknown

• Global
  • Decrease 0.28°C - > 0.5°C
    • Temperature decrease of 0.28°C in 2040s with 0.32°C decrease by 2050 (UNEP and Climate and Clean Air Coalition 2021), > 0.5°C by 2100 (Dreyfus et al. 2022).
    • Successful implementation of the Global Methane Pledge would reduce warming by at least 0.2°C by 2050. (Joint US-EU Statement on the Global Methane Pledge, cited by Zaelke et al. 2023)
    • Model simulations show that combining targeted mitigation strategies of methane and black carbon with decarbonization keeps warming below 2.0°C (Dreyfus et al. 2022).
• Arctic region
  • Decrease up to 0.5°C by 2050
    • Decrease in Arctic of 0.5°C by 2050 (0.3°C by 2040s; UNEP and Climate and Clean Air Coalition 2021) if cut emissions by 40-45% by 2030
    • Mitigating short lived climate pollutants, including methane, in addition to decarbonization would reduce the rate of Arctic warming by 2/3 (Zaelke et al. 2023).
    • Maximum feasible reductions of global methane emissions from anthropogenic sources could lead to a reduction in the warming rate of 0.047°C per decade from 2015-2050 relative to current emissions (AMAP 2021). Corresponding temperature decrease of 0.035°C by 2030, 0.164°C by 2050 (AMAP 2021 full report)

• Global
  • Unknown
• Arctic region
  • Unknown

• Direct or indirect impact on sea ice?
  • Indirect via decreases in greenhouse gas concentrations and subsequent decreases in warming
• New or old ice?
  • Both
• Impact on sea ice
  • Reduced risk of losing Arctic summer sea ice (Sun et al. 2022)

Scalability

• Spatially scalable
  • Many approaches will have a small spatial footprint and rely on existing infrastructure and operational footprints.

• Unknown

• • < 10 years
    • 45% of anthropogenic methane emissions from energy production, agriculture, and waste could be cut by 2030 with existing technology (IGSD 2023).

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021)
  • Methane emissions reductions is likely the fastest strategy for temperature reductions (UNEP and Climate and Clean Air Coalition 2021, IGSD 2023)

• Possible within 20 years
  • Methane emissions reductions estimated to have impact within a decade (UNEP and Climate and Clean Air Coalition 2021)

Cost

• About 60% of available targeted measures have mitigation costs less than US $21 per tonne of carbon dioxide equivalent (CO₂e) for GWP₁₀₀ and less than US $7 per tonne of CO₂e for GWP₂₀. Just over 50% of those have negative costs (UNEP and Climate and Clean Air Coalition 2021 in Zaelke et al. 2023).
• For about 85% of approaches for methane emissions reductions the benefits outweigh the costs (UNEP and Climate and Clean Air Coalition 2022).
• “Cutting methane emissions from the energy sector by 75% by 2030 is one of the least cost opportunities to limit global warming in the near term.” (IEA 2023)
  • Estimated costs for cutting methane by 75% from oil and gas operations is $75 billion USD (2% of net income from the oil and gas industry in 2022; IEA 2023).

• Unknown

• Varies depending on technology, but many are 9.
  • See Ocko et al. 2021 for detailed information on readiness across sectors.
• Summary of existing literature and studies
  • 57% of methane emissions are technically feasible to mitigate today, yet only 24% of emissions mitigation are economically feasible with no net cost (Ocko et al. 2021).
  • Implementation of existing technologies could cut 45% of anthropogenic methane emissions by 2030 from energy production, agriculture, and waste (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions monitoring systems exist and are under development, although more are needed. For a summary of methane measurement and monitoring initiatives see IGSD 2023.

• Feasible
  • Many approaches are feasible, while some need major innovation.

• Varies depending on technology, but many are 9
  • See Ocko et al. 2021 for detailed information on readiness across sectors.
• Summary of existing literature and studies
  • 57% of methane emissions are technically feasible to mitigate today, yet only 24% of emissions mitigation are economically feasible with no net cost (Ocko et al. 2021).
  • Implementation of existing technologies could cut 45% of anthropogenic methane emissions by 2030 from energy production, agriculture, and waste (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions monitoring systems exist and are under development, although more are needed. For a summary of methane measurement and monitoring initiatives see IGSD 2023.

• Feasible
  • Many approaches are feasible, while some need major innovation.

• Varies depending on technology, but many are 9
  • See Ocko et al. 2021 for detailed information on readiness across sectors
• Summary of existing literature and studies
  • 57% of methane emissions are technically feasible to mitigate today, yet only 24% of emissions mitigation are economically feasible with no net cost (Ocko et al. 2021).
  • Implementation of existing technologies could cut 45% of anthropogenic methane emissions by 2030 from energy production, agriculture, and waste (UNEP and Climate and Clean Air Coalition 2021).
  • Methane emissions monitoring systems exist and are under development, although more are needed. For a summary of methane measurement and monitoring initiatives see IGSD 2023.

• Feasible
  • Many approaches are feasible, while some need major innovation

• • Varies depending on technology, but many are 9
    • See Ocko et al. 2021 for detailed information on readiness across sectors
  • Summary of existing literature and studies
    • 57% of methane emissions are technically feasible to mitigate today, yet only 24% of emissions mitigation are economically feasible with no net cost (Ocko et al. 2021).
    • Implementation of existing technologies could cut 45% of anthropogenic methane emissions by 2030 from energy production, agriculture, and waste (UNEP and Climate and Clean Air Coalition 2021).
    • Methane emissions monitoring systems exist and are under development, although more are needed. For a summary of methane measurement and monitoring initiatives see IGSD 2023.

• • Feasible
    • Many approaches are feasible, while some need major innovation

• TRL
  • Varies depending on technology, but many are 9
    • See Ocko et al. 2021 for detailed information on readiness across sectors
  • Summary of existing literature and studies
    • 57% of methane emissions are technically feasible to mitigate today, yet only 24% of emissions mitigation are economically feasible with no net cost (Ocko et al. 2021).
    • Implementation of existing technologies could cut 45% of anthropogenic methane emissions by 2030 from energy production, agriculture, and waste (UNEP and Climate and Clean Air Coalition 2021).
    • Methane emissions monitoring systems exist and are under development, although more are needed. For a summary of methane measurement and monitoring initiatives see IGSD 2023.
• Technology feasibility within 10 years
  • Feasible
    • Many approaches are feasible, while some need major innovation

Physical and chemical changes

• Co-benefits
  • Reducing methane also reduces tropospheric ozone levels (Zaelke et al. 2023).
  • Stopping methane leaks from oil and gas reduces non-methane precursors (Zaelke et al. 2023).
  • Improved air quality (Zaelke et al. 2023).
• Risks
  • Unknown

Impacts on species

• Co-benefits
  • Unknown
• Risks
  • Unknown

Impacts on ecosystems

• Co-benefits
  • Unknown
• Risks
  • Unknown

Impacts on society

• Co-benefits
  • Improved air quality (IEA 2023, Zaelke et al. 2023).
    • Reducing methane emissions would prevent approximately 200,000 premature ozone-related deaths (UNEP and Climate and Clean Air Coalition 2022, cited in Zaelke et al. 2023).
    • Reducing methane emissions would avoid approximately $500 billion per year expenses due to non-mortality health impacts (UNEP and Climate and Clean Air Coalition 2022).
  • Reducing methane emissions would avoid the yield loss of approximately 580 million tons of staple crops (UNEP and Climate and Clean Air Coalition 2022).
  • Avoided impacts on forestry and agriculture (UNEP and Climate and Clean Air Coalition 2022).
  • Job creation (IGSD 2023).
• Risks
  • Some efforts to limit methane emissions from livestock or efforts via diet switching could have other environmental impacts (UNEP and Climate and Clean Air Coalition 2021).

Ease of reversibility

• Easy
  • Impacts of methane emissions reductions would be reversed quickly if emissions reductions measures were omitted and emissions returned.

Risk of termination shock

• No risk
  • If emissions reductions measured were halted and emissions were allowed to rise, temperatures could increase rapidly due to the potency of methane and its short lifetime. However, this scenario seems unlikely.

Physical and chemical changes

• Co-benefits
  • Reducing methane also reduces tropospheric ozone levels (Zaelke et al. 2023).
  • Stopping methane leaks from oil and gas reduces non-methane precursors (Zaelke et al. 2023).
  • Improved air quality (Zaelke et al. 2023).
• Risks
  • Unknown

Impacts on species

• Co-benefits
  • Unknown
• Risks
  • Unknown

Impacts on ecosystems

• Co-benefits
  • Unknown
• Risks
  • Unknown

Impacts on society

• Co-benefits
  • Improved air quality (IEA 2023, Zaelke et al. 2023).
    • Reducing methane emissions would prevent approximately 200,000 premature ozone-related deaths (UNEP and Climate and Clean Air Coalition 2022, cited in Zaelke et al. 2023).
    • Reducing methane emissions would avoid approximately $500 billion per year expenses due to non-mortality health impacts (UNEP and Climate and Clean Air Coalition 2022).
  • Reducing methane emissions would avoid the yield loss of approximately 580 million tons of staple crops (UNEP and Climate and Clean Air Coalition 2022).
  • Avoided impacts on forestry and agriculture (UNEP and Climate and Clean Air Coalition 2022).
  • Job creation (IGSD 2023).
• Risks
  • Some efforts to limit methane emissions from livestock or efforts via diet switching could have other environmental impacts (UNEP and Climate and Clean Air Coalition 2021).

Ease of reversibility

• Impacts of methane emissions reductions would be reversed quickly if emissions reductions measures were omitted and emissions returned.

Risk of termination shock

• If emissions reductions measured were halted and emissions were allowed to rise, temperatures could increase rapidly due to the potency of methane and its short lifetime. However, this scenario seems unlikely.

• Co-benefits
  • Reducing methane also reduces tropospheric ozone levels (Zaelke et al. 2023).
  • Stopping methane leaks from oil and gas reduces non-methane precursors (Zaelke et al. 2023).
  • Improved air quality (Zaelke et al. 2023).
• Risks
  • Unknown

• Co-benefits
  • Unknown
• Risks
  • Unknown

• Co-benefits
  • Unknown
• Risks
  • Unknown

• Co-benefits
  • Improved air quality (IEA 2023, Zaelke et al. 2023).
    • Reducing methane emissions would prevent approximately 200,000 premature ozone-related deaths (UNEP and Climate and Clean Air Coalition 2022, cited in Zaelke et al. 2023).
    • Reducing methane emissions would avoid approximately $500 billion per year expenses due to non-mortality health impacts (UNEP and Climate and Clean Air Coalition 2022).
  • Reducing methane emissions would avoid the yield loss of approximately 580 million tons of staple crops (UNEP and Climate and Clean Air Coalition 2022).
  • Avoided impacts on forestry and agriculture (UNEP and Climate and Clean Air Coalition 2022).
  • Job creation (IGSD 2023).
• Risks
  • Some efforts to limit methane emissions from livestock or efforts via diet switching could have other environmental impacts (UNEP and Climate and Clean Air Coalition 2021).

• Impacts of methane emissions reductions would be reversed quickly if emissions reductions measures were omitted and emissions returned.

• If emissions reductions measured were halted and emissions were allowed to rise, temperatures could increase rapidly due to the potency of methane and its short lifetime. However, this scenario seems unlikely.

• Co-benefits
  • Reducing methane also reduces tropospheric ozone levels (Zaelke et al. 2023).
  • Stopping methane leaks from oil and gas reduces non-methane precursors (Zaelke et al. 2023).
  • Improved air quality (Zaelke et al. 2023).
• Risks
  • Unknown

• Co-benefits
  • Unknown
• Risks
  • Unknown

• Co-benefits
  • Unknown
• Risks
  • Unknown

• Co-benefits
  • Improved air quality (IEA 2023, Zaelke et al. 2023).
    • Reducing methane emissions would prevent approximately 200,000 premature ozone-related deaths (UNEP and Climate and Clean Air Coalition 2022, cited in Zaelke et al. 2023)
    • Reducing methane emissions would avoid approximately $500 billion per year expenses due to non-mortality health impacts (UNEP and Climate and Clean Air Coalition 2022)
  • Reducing methane emissions would avoid the yield loss of approximately 580 million tons of staple crops (UNEP and Climate and Clean Air Coalition 2022)
  • Avoided impacts on forestry and agriculture (UNEP and Climate and Clean Air Coalition 2022)
  • Job creation (IGSD 2023)
• Risks
  • Some efforts to limit methane emissions from livestock or efforts via diet switching could have other environmental impacts (UNEP and Climate and Clean Air Coalition 2021)

• Impacts of methane emissions reductions would be reversed quickly if emissions reductions measures were omitted and emissions returned

• If emissions reductions measured were halted and emissions were allowed to rise, temperatures could increase rapidly due to the potency of methane and its short lifetime. However, this scenario seems unlikely.

• National
  • Action on methane is occurring at the national and subnational level, strengthened by international pledges, such as the Global Methane Pledge.

• International
  • International collaboration is critical for action on methane. For a summary of public and private international organizations and initiatives see IGSD 2023.
  • Around 150 countries have signed on to the Global Methane Pledge. This voluntary agreement has a collective goal of reducing global methane emissions by at least 30% below 2020 levels by 2030. Implementation of the pledge would decrease temperatures by at least 0.2°C by 2050. The Global Methane Pledge forms a foundation to create a global methane agreement, with the Montreal Protocol providing a framework structure and approach (IGSD 2023).
  • See IGSD 2023 for a summary of potential international governance pathways including The Global Methane Pledge and Glasgow Climate Pact, the Gothenburg Protocol to the Convention on Long-Range Transboundary Air Pollution, the US-China Joint Glasgow Declaration on Enhancing Climate Action in the 2020s, and the Montreal Protocol.
  • Action on methane is severely underfunded (IGSD 2023). The Global Methane Hub is an international coordinated approach trying to strengthen methane mitigation funding.
• Several countries have released or are building national methane action plans, and some oil and gas companies have also set methane targets (IEA 2023). For a summary of country-specific methane mitigation measures see IGSD 2023.
• Across international and national governance mechanisms, verification of methane action is lacking (Nisbet et al. 2021).

• Here we define justice related to approaches to slow the loss of Arctic sea ice through distributive justice, procedural justice, and restorative justice. Following COMEST (2023), we consider questions of ethics through a justice lens. Note that this is not an exhaustive list of justice dimensions and as the field advances, so will the related considerations and dimensions.
• Distributive justice
  • Action on methane is severely underfunded (IGSD 2023) and funding is not distributed equally across sectors or geographies.
  • Methane monitoring systems are not distributed appropriately geographically (Nisbet et al. 2021).
• Procedural justice
  • Opportunities for participation in governance of emissions reductions have increased over time. Localized actions can enable participation but can be limited by resource and capacity constraints (IPCC 2022).
  • Each individual emissions reductions pathway will have specific procedural justice concerns, which will also vary by region and country.
• Restorative justice
  • Each individual emissions reductions pathway will have specific restorative justice concerns, which will also vary by region and country.

• A 2023 public opinion poll commissioned by the Global Methane Hub conducted in 17 countries reports that 82% of respondents support methane mitigation (GMH 2024).

• Unknown

• National
  • Action on methane is occurring at the national and subnational level, strengthened by international pledges, such as the Global Methane Pledge.

• International
  • International collaboration is critical for action on methane. For a summary of public and private international organizations and initiatives see IGSD 2023.
  • Around 150 countries have signed on to the Global Methane Pledge. This voluntary agreement has a collective goal of reducing global methane emissions by at least 30% below 2020 levels by 2030. Implementation of the pledge would decrease temperatures by at least 0.2°C by 2050. The Global Methane Pledge forms a foundation to create a global methane agreement, with the Montreal Protocol providing a framework structure and approach (IGSD 2023).
  • See IGSD 2023 for a summary of potential international governance pathways including The Global Methane Pledge and Glasgow Climate Pact, the Gothenburg Protocol to the Convention on Long-Range Transboundary Air Pollution, the US-China Joint Glasgow Declaration on Enhancing Climate Action in the 2020s, and the Montreal Protocol.
  • Action on methane is severely underfunded (IGSD 2023). The Global Methane Hub is an international coordinated approach trying to strengthen methane mitigation funding.
• Several countries have released or are building national methane action plans, and some oil and gas companies have also set methane targets (IEA 2023). For a summary of country-specific methane mitigation measures see IGSD 2023.
• Across international and national governance mechanisms, verification of methane action is lacking (Nisbet et al. 2021).

• Here we define justice related to approaches to slow the loss of Arctic sea ice through distributive justice, procedural justice, and restorative justice. Following COMEST (2023), we consider questions of ethics through a justice lens. Note that this is not an exhaustive list of justice dimensions and as the field advances, so will the related considerations and dimensions.
• Distributive justice
  • Action on methane is severely underfunded (IGSD 2023) and funding is not distributed equally across sectors or geographies.
  • Methane monitoring systems are not distributed appropriately geographically (Nisbet et al. 2021)
• Procedural justice
  • Opportunities for participation in governance of emissions reductions have increased over time. Localized actions can enable participation but can be limited by resource and capacity constraints (IPCC 2022).
  • Each individual emissions reductions pathway will have specific procedural justice concerns, which will also vary by region and country.
• Restorative justice
  • Each individual emissions reductions pathway will have specific restorative justice concerns, which will also vary by region and country.

• A 2023 public opinion poll commissioned by the Global Methane Hub conducted in 17 countries reports that 82% of respondents support methane mitigation (GMH 2024).

• Unknown

• National
  • Action on methane is occurring at the national and subnational level, strengthened by international pledges, such as the Global Methane Pledge.

• International
  • International collaboration is critical for action on methane. For a summary of public and private international organizations and initiatives see IGSD 2023.
  • Around 150 countries have signed on to the Global Methane Pledge. This voluntary agreement has a collective goal of reducing global methane emissions by at least 30% below 2020 levels by 2030. Implementation of the pledge would decrease temperatures by at least 0.2°C by 2050. The Global Methane Pledge forms a foundation to create a global methane agreement, with the Montreal Protocol providing a framework structure and approach (IGSD 2023).
  • See IGSD 2023 for a summary of potential international governance pathways including The Global Methane Pledge and Glasgow Climate Pact, the Gothenburg Protocol to the Convention on Long-Range Transboundary Air Pollution, the US-China Joint Glasgow Declaration on Enhancing Climate Action in the 2020s, and the Montreal Protocol.
  • Action on methane is severely underfunded (IGSD 2023). The Global Methane Hub is an international coordinated approach trying to strengthen methane mitigation funding.
• Several countries have released or are building national methane action plans, and some oil and gas companies have also set methane targets (IEA 2023). For a summary of country-specific methane mitigation measures see IGSD 2023.
• Across international and national governance mechanisms, verification of methane action is lacking (Nisbet et al. 2021).

• Here we define justice related to approaches to slow the loss of Arctic sea ice through distributive justice, procedural justice, and restorative justice. Following COMEST (2023), we consider questions of ethics through a justice lens. Note that this is not an exhaustive list of justice dimensions and as the field advances, so will the related considerations and dimensions.
• Distributive justice
  • Action on methane is severely underfunded (IGSD 2023) and funding is not distributed equally across sectors or geographies.
  • Methane monitoring systems are not distributed appropriately geographically (Nisbet et al. 2021)
• Procedural justice
  • Opportunities for participation in governance of emissions reductions have increased over time. Localized actions can enable participation but can be limited by resource and capacity constraints (IPCC 2022).
  • Each individual emissions reductions pathway will have specific procedural justice concerns, which will also vary by region and country.
• Restorative justice
  • Each individual emissions reductions pathway will have specific restorative justice concerns, which will also vary by region and country.

• A 2023 public opinion poll commissioned by the Global Methane Hub conducted in 17 countries reports that 82% of respondents support methane mitigation (GMH 2024).

• Unknown

• National
  • Action on methane is occurring at the national and subnational level, strengthened by international pledges, such as the Global Methane Pledge.

• International
  • International collaboration is critical for action on methane. For a summary of public and private international organizations and initiatives see IGSD 2023.
  • Around 150 countries have signed on to the Global Methane Pledge. This voluntary agreement has a collective goal of reducing global methane emissions by at least 30% below 2020 levels by 2030. Implementation of the pledge would decrease temperatures by at least 0.2°C by 2050. The Global Methane Pledge forms a foundation to create a global methane agreement, with the Montreal Protocol providing a framework structure and approach (IGSD 2023).
  • See IGSD 2023 for a summary of potential international governance pathways including The Global Methane Pledge and Glasgow Climate Pact, the Gothenburg Protocol to the Convention on Long-Range Transboundary Air Pollution, the US-China Joint Glasgow Declaration on Enhancing Climate Action in the 2020s, and the Montreal Protocol.
  • Action on methane is severely underfunded (IGSD 2023). The Global Methane Hub is an international coordinated approach trying to strengthen methane mitigation funding.
• Several countries have released or are building national methane action plans, and some oil and gas companies have also set methane targets (IEA 2023). For a summary of country-specific methane mitigation measures see IGSD 2023.
• Across international and national governance mechanisms, verification of methane action is lacking (Nisbet et al. 2021).

• Distributive justice
  • Action on methane is severely underfunded (IGSD 2023) and funding is not distributed equally across sectors or geographies.
  • Methane monitoring systems are not distributed appropriately geographically (Nisbet et al. 2021)
• Procedural justice
  • Opportunities for participation in governance of emissions reductions have increased over time. Localized actions can enable participation but can be limited by resource and capacity constraints (IPCC 2022).
  • Each individual emissions reductions pathway will have specific procedural justice concerns, which will also vary by region and country.
• Restorative justice
  • Each individual emissions reductions pathway will have specific restorative justice concerns, which will also vary by region and country.

• A 2023 public opinion poll commissioned by the Global Methane Hub conducted in 17 countries reports that 82% of respondents support methane mitigation (GMH 2024).

• Unknown