Sustainable Gas Institute Blog

By Dr Jasmin Cooper

Research Associate, Sustainable Gas Institute 

Methane is a major greenhouse gas and in recent year many companies in the oil and gas value chain have either joined initiatives or set ambitious targets in a bid to curb their emissions e.g. the oil and gas methane partnership (OGMP), the oil and gas climate initiative (OGCI) and methane intensity targets set by major oil and gas companies (GMI, 2020, OGCI, 2018, Shell, 2018, Xu et al., 2020). The quantification of emissions is undoubtably a key component of emission reduction strategies, but there is a high level of uncertainty in the emissions data globally. This is largely because, in comparison to carbon dioxide, there was a lack of interest until the second half of the 2010s when post the Paris Agreement, a spotlight was shone on short-lived climate forcers (e.g. methane, ozone, black carbon) and their role in reducing warming.

The global atmospheric concentration of methane has been increasing since preindustrial times and since the 1980s it has been rising rapidly (Dlugokencky, 2021). The International Energy Agency (IEA) reported in their Methane Tracker that oil and gas methane has been rising since the year 2000, with emissions peaking in 2019 (IEA, 2021b). The impacts of COVID-19 appear to have led to a drop in emissions, because of reductions in oil and gas demand because of slowdowns in industrial and economic activity. However, post COVID-19, it is imperative that 2019 remain the emissions peak if the sector is to contribute towards net-zero ambitions. This is because with methane being a potent greenhouse gas, reductions in emissions can lead to significant climate change and global warming benefits.

In the oil and gas sector, as well as in other sectors, methane emissions are quantified using one (or a combination) of three methods (National Academies of Sciences and Medicine, 2018): engineering calculations (including process modelling/simulation and using equipment specifications), emission factors (coefficient used to calculate emissions) and direct measurement. Out of these three, direct measurement is the most accurate for quantifying emissions and is also the only method which allows for the accounting and identification of emission sources. Data derived from direct measurement are also value inputs in emissions modelling via process simulation, as well as in updating or deriving emission factors. There is a broad spectrum of quantification technologies available, ranging from handheld devices, such as flow meters, to remote devices, such as observation stations and satellites. The measurement capabilities of these technologies also vary along the spectrum, from low level to extremely high emission rates and quick measurements to hours long measurement surveys.

However, quantifying emissions through direct measurement is expensive and time consuming. This, in combination with the lag in methane interest has results in a large proportion of global oil and gas related methane emissions being quantified using generic emission factor data. Major oil and gas countries such as the USA, Norway and Australia quantify their emissions using data derived from measurement campaigns, while others such as Egypt, Malaysia and Bolivia rely on default emission factors. Also, the sections of the oil and gas value chain (upstream, midstream and downstream) vary in how emissions are quantified. In countries which are major gas importers, such as Japan, Italy and Germany, emissions from the midstream and downstream activities are quantified using data derived from measurement surveys, while emissions from any upstream production and processing activities are quantified using either generic emission factors or country specific emission factors derived from expert estimates and industry reports.

Therefore, it is clear that actions need to be taken to homogenise the quality of both the emissions data and the emissions reporting, both between countries and within countries. The IEA launched in January 2021 their regulatory roadmap and toolkit (IEA, 2021a), which aims to provide guidance for policy makers who are looking to develop regulations to tackles their oil and gas methane emissions. A key step in this roadmap is developing an emissions profile.

For this step, accurate emissions data is needed, not just in magnitude of emissions and identifying all emission sources, but also in determining emission patters e.g., constant continuous, intermittent, episodic, inter-daily variable and intra-daily variable. These are important as they will directly impact any abatement measures and strategies developed, as well as any new regulations introduced to curb emissions. Hence, more efforts must be put into measuring emissions in all active oil and gas countries (both producers and consumers). The effectiveness of methane abatement measures will be hindered if the underlying emissions data is poor as either not enough or too many efforts could be put in, or efforts are not targeting the key emission sources.

References

Dlugokencky, E. 2021. Trends in atmospheric methane: Global CH4 monthly means [Online]. Boulder, CO, USA: National Oceanic and Atmospheric Administration/Global monitoring Laboratory (NOAA/GML). Available: https://www.esrl.noaa.gov/gmd/ccgg/trends_ch4/ [Accessed].

GMI. 2020. UNEP: Oil and Gas Methane Partnership Initiative to Manage Methane Emissions from Upstream Oil and Gas Operations [Online]. Global Methane Initiative (GMI). Available: https://globalmethane.org/challenge/ogmp.html [Accessed October 2020].

IEA. 2021a. Driving Down Methane Leaks from the Oil and Gas Industry, Paris, FR; International Energy Agency (IEA). Available:’ https://www.iea.org/reports/driving-down-methane-leaks-from-the-oil-and-gas-industry

IEA. 2021b. Methane Tracker 2021, Paris, FR; International Energy Agency (IEA). Available:’ https://www.iea.org/reports/methane-tracker-2021

National Academies of Sciences, E. & Medicine 2018. Improving Characterization of Anthropogenic Methane Emissions in the United States, Washington, DC, The National Academies Press.

OGCI. 2018. Oil and Gas Climate Initiative sets first collective methane target for member companies [Online]. New York, NY, USA: Oil and Gas Climate Initiative (OGCI). Available: https://oilandgasclimateinitiative.com/oil-and-gas-climate-initiative-sets-first-collective-methane-target-for-member-companies/ [Accessed June 2020].

Shell. 2018. Why shell has set a methane target [Online]. The Hague, NL: Royal Dutch Shell Available: https://www.shell.com/media/speeches-and-articles/2018/why-shell-has-set-a-methane-target.html [Accessed June 2020].

Xu, M., Aizhu, C. & Jacob-Phillips, S. 2020. China’s CNPC targets 50% slash in methane emission intensity by 2025. Reuters, 2 July 2020.

By Dr Jasmin Cooper

Research Associate, SGI

Read How much methane does the oil and gas sector emit? in full

Author: Luke Dubey, Research Assistant, Sustainable Gas Institute

Methane is the second most important greenhouse gas after CO₂. While emissions are far lower than CO₂ it has a far higher global warming potential and so is responsible for 25% of today’s anthropogenic climate forcing (Myhre et al., 2013). Methane is the main constituent of natural gas, which is important due to the increasing use of natural gas as a transition fuel. Measuring and estimating emissions from the natural gas supply chain is difficult due to methane being odourless and colourless, and emissions being widespread and intermittent. Should the emission rate of methane be higher than currently estimated the climate benefits of gas relative to coal could be wiped out.

How are emissions measured

Methane emissions from the natural gas supply chain are currently estimated using either bottom-up methods, such as handheld devices and mobile laboratories, or top-down methods such as aeroplanes and satellites. A current issue is that bottom-up methods tend to estimate lower emission rates than top-down methods, even in the same area, and it is not clear whether one is under or another over-estimating emissions.

Satellites have been used for detecting and measuring methane for 20 years. During this time their technology has improved massively, largely by lowering minimum detection limits and increasing resolution. As their technology has improved, their potential role in the natural gas industry has been realised. It is widely hoped they will be able to provide comprehensive coverage, detecting all emissions in an area (which may sometimes not allow access), while returning daily, providing constant measurements. This is highlighted within the EU’s methane strategy, which promotes the Sentinel 5P satellite as capable of measuring global emissions (European Commission, 2020).  However, there are many reasons why satellites might not be up for the task just yet, while still having immense potential in the future.

Limiting factors of satellites

1.      Cloud cover

Satellites have a few issues that are not widely enough discussed, the first being non-detectable pixels. A pixel is the base unit a satellite reports data in, these range from 60km² for Envisat to 7km² for Sentinel 5P all the way down to 50m² for GHGSat. There are many factors that can cause a no detect in a pixel, such as aerosols, albedo and terrain, but the most important is cloud cover. Spectrometers onboard the satellites are what measure the methane; there are many ways to do this but a common one is using sunlight that is backscattered from the earths surface into the spectrometer. The absorption peaks are then analysed and the total concentration of methane in the column is outputted (Jacob et al., 2016). It is clear then how clouds could interfere with this process, with thin clouds causing too much noise for accurate results and thick clouds completely blocking out the sunlight. Many places that produce gas are cloudy virtually year-round (Russia, Canada), meaning there is no way to measure every day of the year with many areas having at best a couple days coverage per pixel per year. Technology has improved over time and will continue to do so, and new methods of reducing the noise from low cloud coverage have been developed, but there is still a long way to go.

2.      Minimum detection limits

A second issue is the minimum detection limits (MDL) of satellites. The MDL is a consequence of the uncertainty within the satellite’s instruments. This will lower as technology improves, and it is possible to reduce over repeated measurements. However, many of the emissions from natural gas are low level and spread out, such as from wells, meaning satellites are unlikely to be able to discern these from the background noise. The saving grace of the MDL is that emissions from natural gas follow a superemitting profile, where a few high emitting sources are responsible for the majority of emissions (Brandt et al., 2016). These are far more likely to be detected by the current crop of satellites and have been a common use of satellites thus far.

3.      Time of overpass

Another aspect of satellites that does not receive enough, if any, attention is the time of overpass. This is fundamentally important when measuring emissions from intermittent sources prevalent across the natural gas supply chain. Should a large emission occur immediately before an overpass the methane will have no time to disperse, increasing the likelihood it is above the MDL and detected. Should the same emission happen hours before an overpass, there is a long time for winds to disperse the emission into nearby pixels, or even distant pixels if long enough has passed. This results in no detection happening and zero emissions being attributed to the pixel. Conversely, if the emission rate detected in the first scenario was extrapolated up to a daily or yearly average, it would greatly overestimate total emissions. Increasing the number of days measured would reduce this effect, or having several satellites working in tandem, measuring at different times of day would help solve the issue.

Newer satellites

The counter to some of the issues raised is in the newest crop of ‘paid for’ satellites. Where the data is not freely available online, but private institutions pay for access, such as GHGSat. These satellites have far higher resolution and lower MDLs. The higher resolution increases the likelihood of an individual pixel being cloud free (chance of no clouds in one of 10,000 100m² pixels or one 10km² pixel). However, I believe these satellites play a different role, more comparable to an aeroplane than a traditional satellite. These satellites do not have the ability to globally track emissions daily, but target specific facilities. A hope is that these satellites could work in tandem with more traditional satellites, where one would scan the globe and detect an area of interest, and the other then has a more detailed look. All of this being possible rapidly, stopping hidden emissions far quicker than ever before. With the recent launch of GHGSat C (Iris) and the upcoming launch of MethaneSat this seems a very real possibility.

Conclusion

So what’s the role of satellites now and in the future? Currently satellites are useful for research, but uncertainties are too high for commercial use in the most part. However, satellites can currently play a very helpful role in locating superemitters. As technology improves satellites will become more useful, this will be aided by more satellites coming online, working in tandem to mitigate some of the limitations. Satellites have the potential to comprehensively measure emissions globally at the drop of a hat, this potential has received, and deserves, the time and investment fitting of such a game changing climate change technology. I am hopeful in the near future satellites will be the primary way of measuring methane globally.

BRANDT, A. R., HEATH, G. A. & COOLEY, D. 2016. Methane Leaks from Natural Gas Systems Follow Extreme Distributions. Environmental Science & Technology, 50, 12512-12520.

EUROPEAN COMMISSION. 2020. EU Methane Strategy [Online]. Available: https://ec.europa.eu/energy/topics/oil-gas-and-coal/methane-emissions_en#eu-methane-strategy- [Accessed 6/1/21 2021].

JACOB, D. J., TURNER, A. J., MAASAKKERS, J. D., SHENG, J., SUN, K., LIU, X., CHANCE, K., ABEN, I., MCKEEVER, J. & FRANKENBERG, C. 2016. Satellite observations of atmospheric methane and their value for quantifying methane emissions. Atmospheric Chemistry and Physics, 16, 14371-14396.

MYHRE, G., SHINDELL, D., BRÉON, F. M., COLLINS, W., FUGLESTVEDT, J., HUANG, J., KOCH, D., LAMARQUE, J. F., LEE, D., MENDOZA, B., NAKAJIMA, T., ROBOCK, A., STEPHENS, G., TAKEMURA, T. & ZHANG, H. 2013. Anthropogenic and natural radiative forcing. In: STOCKER, T. F., QIN, D., PLATTNER, G. K., TIGNOR, M. M. B., ALLEN, S. K., BOSCHUNG, J., NAUELS, A., XIA, Y., BEX, V. & MIDGLEY, P. M. (eds.). Cambridge, UK: Cambridge University Press.

Author: Luke Dubey, Research Assistant, Sustainable Gas Institute

Read Satellites – The Future of Methane Measurement? in full

Author: Karen L. Mascarenhas 

1. Carbon Capture and Storage (CCS) context

Energy is one of the primary means that supports modern life, either to enable industrialization of goods, the provision of services or even to meet the daily needs of the citizens, such as transportation, housing, work, food and entertainment. Alongside the demand for energy efficiency, changes in the composition of the local and the global energy matrix are increasingly advancing towards cleaner and renewable energy sources, motivated mainly by the planet sustainability and climate change containment.

These concerns are supported by two broad international pacts settled in 2015: the Paris Agreement and the launch of the Sustainable Development Goals by the United Nations.

In Brazil, the transition of the energy matrix requires, initially, a gradual reduction in the use of fossil fuels with a high carbon dioxide (CO₂) footprint, switching to the use of natural gas and, later, biogas, solar, wind and hydrogen as sustainable sources of energy production. While the energy demand is greater than the capacity to supply it through renewable sources, natural gas, as one of the fossil fuels with the lowest emission of greenhouse gases, is seen as an alternative to support this transition, offering the potential to provide cleaner and more affordable energy for a large number of people in the country.

The geological formation of the pre-salt basin on the coast of five Brazilian states enables the extraction of large quantities of oil and natural gas, the latter with a high concentration of CO₂. The pre-salt has specific characteristics that allow the creation of saline cavities capable of storing large amounts of CO₂, avoiding ventilation into the atmosphere. Technologies are being developed to separate methane (CH₄), CO₂ and other gases in caves using a gravimetric method and other innovative technologies, keeping the captured CO₂ without the need to re-inject it, and preventing its release into the atmosphere. These technologies are called Carbon Capture and Storage (CCS), or Carbon Capture Usage and Storage (CCUS) when it also involves the use of carbon for other ends.

Similar technologies adopted in a renewable area, such as the capture of CO₂ released by the fermentation process in the ethanol production, are creating conditions for the capture, use and storage of carbon bioenergy (BECCUS). This technology can evolve to a negative CO₂ footprint process, since the emissions from the processing, distribution and, finally, combustion of ethanol are neutralized through their absorption by the sugarcane plantation. In other words, the cycle becomes sustainable as the plants in the photosynthesis process absorb the gases released by the ethanol production process, and any reminiscent CO₂ can be stored in underground reservoirs or employed as raw material for the production of other high-added-value products.

2. Social challenges in CCS implementation

However, the implementation of projects based on CCS technologies cause changes in the territory, as they imply in the creation or use of underground reservoirs on land (onshore) or underwater in the ocean (offshore), impacting the environment, their living ecosystems and the local community. Besides, CCS, CCUS, and BECCUS are not yet known by other agents outside the specific academic and industry segments that study or manage these technologies. Previous experiences of implementing projects of this nature have demonstrated the relevance of considering the perception and acceptance of government, media, society, other academics and industries not directly related to such technologies. Their reactions can emerge from irrational bias, through strong opinions, even if they have no information about the risks or benefits involved.

Therefore, public perception can be one of the critical barriers to the deployment of CCS projects. Local communities’ opposition has shown to derail demonstration plants in some of the first projects that aimed to store CO₂ onshore as the Barendrecht Project in the Netherlands, and Beeskow in Germany

3. Public perception of CCS technologies in Brazil

In Brazil, studies on public perception related to CCS are still scarce, as only three were identified. The most comprehensive concerns a CCS onshore field study at the Recôncavo Basin in the state of Bahia, an outstanding region of oil exploration.  The qualitative research was conducted with ten communities located in prospective areas for CCS implementation who did not have any knowledge of the concept. The main outcomes show that people that have a previous relationship with oil companies are best equipped to identify benefits or disadvantages, that trust in government and private companies can enhance their support of such projects, and that further investigation is imperative as Brazil is a vast country with great cultural diversity, making it hard to define a national perception of CCS as each region has its singular peculiarities and views.

Public perception studies within developing countries are challenging as the low level of fundamental education impacts on the citizens’ capacity to understand complex concepts like climate change. This tends to be the profile of inhabitants in Brazilian regions where CCS projects could be implemented.

Pioneering studies in public perception in Brazil are under development in the Research Centre for Gas Innovation (RCGI), headquartered at the Polytechnic School of the University of São Paulo, financed by the Research Funding Agency of the State of São Paulo (FAPESP), in partnership with the private company Shell.

The RCGI started its activities in January 2016 and currently has 46 projects focused on innovation, aiming at the sustainable use of natural gas, biogas, hydrogen and the reduction of CO₂ emissions worldwide to contribute towards climate improvement and sustainability.

The initiative to research public perception emerged from the intention of complementing the technical and legal research carried out in the RCGI with the social and human dimensions, in a multidisciplinary approach. This process aims to understand the public perception of all agents, as government representatives, media, academia, industry, NGOs and society, building trustful relationships and supporting the analysis of potential CCS projects in the country.

Author: Karen L. Mascarenhas – Imperial College London, University of São Paulo, Research Centre for Gas Innovation (RCGI)

karenmascarenhas@usp.br

Read The Role of Public Perception in Carbon Capture and Storage (CCS) Projects: Perspectives for Brazil in full