Methane tracker

Reducing methane emissions from oil and gas operations

Oil and gas producers that can demonstrate that they are taking strong action to reduce methane emissions can credibly argue that their resources should be preferred over higher-emission options. It is crucial for the oil and gas industry to be proactive in limiting, in all ways possible, the environmental impact of oil and gas supply, and for policy makers to recognise this is a pivotal element of global energy transitions.


Overview


Oil and natural gas will be part of the energy system for decades to come – even under ambitious efforts to reduce greenhouse gas emissions in line with the Paris Agreement. As part of today’s energy transitions, it is therefore vital to reduce the immediate environmental impacts associated with producing and consuming these fuels. Reducing methane emissions is a powerful and cost-effective way to act, providing an essential complement to action on reducing CO2.

Methane and climate change

The concentration of methane in the atmosphere is currently around two-and-half times greater than pre-industrial levels and is increasing steadily. This rise has important implications for climate change.

Estimates of methane emissions are subject to a high degree of uncertainty, but the most recent comprehensive estimate suggests that annual global methane emissions are around 570 million tonnes (Mt). This includes emissions from natural sources (around 40% of emissions), and those originating from human activity (the remaining 60% - known as anthropogenic emissions).

The largest source of anthropogenic methane emissions is agriculture, responsible for around a quarter of the total, closely followed by the energy sector, which includes emissions from coal, oil, natural gas and biofuels.

Sources of methane emissions

	Anthropogenic sources	Natural sources
Wetlands		30
Agriculture	24	
Fossil fuels	20	
Waste	11	
Other		9
Biofuels	3	
Biomass burning	3	
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Note: Other natural sources includes: fresh waters, geologic seepage, wild animals, termites, wildfires, permafrost and vegetation Source: Saunois et al. (2016)

Methane has important implications for climate change, particularly in the near term.

Two key characteristics determine the impact of different greenhouse gases on the climate: the length of time they remain in the atmosphere and their ability to absorb energy. Methane has a much shorter atmospheric lifetime than CO2 (around 12 years compared with centuries for CO2) but it is a much more potent greenhouse gas, absorbing much more energy while it exists in the atmosphere.

There are various ways to combine these factors to estimate the effect on global warming; the most common is the global warming potential (GWP). This can be used to express a tonne of a greenhouse-gas emitted in CO2 equivalent terms, in order to provide a single measure of total greenhouse-gas emissions (in CO2-eq).

The Intergovernmental Panel on Climate Change (IPCC) has indicated a GWP for methane between 84-87 when considering its impact over a 20-year timeframe (GWP20) and between 28-36 when considering its impact over a 100-year timeframe (GWP100). This means that one tonne of methane can considered to be equivalent to 28 to 36 tonnes of CO2 if looking at its impact over 100 years.

In addition to its climate impacts, methane also affects air quality because it is an ingredient in the formation of ground level (tropospheric) ozone, a dangerous air pollutant.

Why focus on methane emissions from oil and gas?

It is important to tackle all sources of methane emissions arising from human activity, but there are reasons to focus on emissions from oil and gas operations.

First, although emissions also come from coal and bioenergy, oil and gas operations are likely the largest source of emissions from the energy sector.

Second, our analysis shows clear scope to reduce them cost-effectively. Unlike CO2, methane – the main component of natural gas – has commercial value: the additional methane captured can often be monetised directly, and this is typically easier in the oil and gas sectors than elsewhere in the energy sector. This means that emissions reductions could result in economic savings or be carried out at low cost.

Our scenario projections also suggest that oil and, particularly, natural gas will play important roles in the energy system for decades to come, even under strong decarbonisation scenarios such as the IEA’s Sustainable Development Scenario.

Gas can play an important supporting role in energy transitions by replacing more polluting fuels; it may also deliver services that are difficult to provide cost-effectively with low-carbon alternatives, such as peak winter heating, seasonal storage, or high temperature heat for industry. However, fulfilling this role requires that adverse social and environmental impacts are minimised: immediate and major reductions in methane emissions are central to this.

Global methane emissions from oil and gas operations

	Methane emissions
2000	62.72
2001	62.85
2002	63.34
2003	65.31
2004	68.94
2005	70.73
2006	72.25
2007	73.73
2008	75.15
2009	72.11
2010	75.55
2011	73.00
2012	76.83
2013	75.75
2014	75.39
2015	76.01
2016	76.69
2017	78.90
2020	64.61
2025	39.85
2030	19.40
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A compelling case for action

The World Energy Outlook 2017 produced detailed new estimates for methane emissions from oil and gas operations, which form the basis for the detailed data available in this methane tracker. We also developed first-of-a-kind global marginal methane abatement cost curves. These curves describe the reduction potentials as well as the costs and revenues of measures to mitigate methane emissions globally.

Marginal abatement cost curve for oil- and gas-related methane emissions globally

Using this analysis, we estimate that it is technically possible to avoid around three quarters of today’s methane emissions from global oil and gas operations. Even more significantly, around 40-50% of current methane emissions could be avoided at no net cost.

If a high share of current emissions can be mitigated using measures that will pay for themselves from the methane recovered, why have these not already been widely adopted?

Possible reasons include:

  • a lack of awareness about emission levels or the cost-effectiveness of abatement
  • competition for capital within companies with a variety of investment opportunities
  • insufficiently quick payback periods to clear the threshold for investment
  • the possibility of split incentives (where the owner of the equipment does not directly benefit from reducing leaks or the owner of the gas doesn’t see its full value).

The benefit to overcoming these hurdles would be enormous. Implementing only the abatement measures that have positive net present values in the WEO’s New Policies Scenario would reduce the temperature rise in 2100 by 0.07 °C compared with a trajectory that has no explicit reductions.

This may not sound like much, but it is immense in climate terms. To yield the same reduction in the temperature rise by reducing CO2 emissions would require emitting 160 billion fewer tonnes of CO2 over the rest of the century. This is broadly equivalent to the CO2 emissions that would be saved by immediately shutting down 60% of the world’s coal-fired power plants that are in operation today and replacing them with zero-emissions generation.

Action is also essential in the Sustainable Development Scenario. We incorporate even more stringent reductions in oil and gas methane emissions in this scenario, as failing to do so would require even faster reductions in CO2. Alongside the rapid declines in CO2 emissions in the Sustainable Development Scenario, and therefore reductions in fossil-fuel consumption, it remains critical to tackle methane emissions as well.

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