Characterization of the Dominant Stages at Which Gas Flaring Is Introduced: Impacts and Policy Options to Ameliorate Them
Abstract
:1. Introduction
Perspective and Issues Addressed
2. Rationale, Methods, Contributions
2.1. Quality of Life and the Three Pillars of Sustainability
2.2. The Concept of the Time of Intervention and the Motivation of the Study
2.3. The Area of Study
3. Impacts of Gas Flaring on the Environment
3.1. Thermal Effects
3.2. Carbon Emissions
3.3. Quality of Rain and Ground Water
4. Impacts of Gas Flaring on the Society
4.1. The Quality of Aquatic Life and Fishing Yield
4.2. The Recorded Noise Levels in the Area
4.3. Crop Production
4.4. Health Impacts
5. The Economic Impacts of Gas Flaring
5.1. Costs Due to Corrosion
5.2. Gas Flaring Costs
6. Dominant Stages at Which Gas Flaring Is Introduced
Pathways to Gas Flaring and Relationships with the Flaring Stages
7. Policies to Eliminate Gas Flaring
7.1. Present State of Gas Flaring and Prevention Policies
7.2. Preventive Policy Measures at the Design Stage of the Oil Field Facility (Pre-Flaring Stage)
Adequate Pre-Flare Legislation Is Required, and Implementation Is Necessary
- The permissions to flare should be an explicit part of the proposed associated gas legislation described in (1.) above. Presently, these are handled by three different departments: the Department of Petroleum Resources (DPR), the Federal Environment Protection Agency, and the Environment Impact Assessment unit [75].
- It should be required that an oil exploration/production operator seeking a permit to operate should show evidence of associated gas utilization options (covering the routine, non-routine, and safety flaring pathways (see Table 2)) at the design stage, and, if the permit is granted, incorporate the appropriate gas utilization measures during the exploration, construction, and utilization phases of the facility. The Norwegian Petroleum Directorate has successfully applied a similar approach [76].
- The siting of new oil production facilities should be subject to restrictions in terms of distance to existing habitations based on evidence from the number of studies so far indicating the societal effects of gas flaring. This is to mitigate the health impacts.
7.3. Policy Options at Existing Oil Production Facilities (Flaring Stage)
Strengthen and Implement Existing Legislation
- Strengthen the Flare Gas (Prevention of Waste and Pollution) Regulations, 2018 [80], which is an update of the Associated Gas Reinjection Act of 1979 (which has a gas re-injection clause), with the flare penalties updated, to accommodate the nature of existing oil production facilities; existing facilities should be made to adopt currently feasible anti-flare measures.
- Establish a realistic flare-out deadline agreed upon with the stakeholders. It is best to identify key points and risks associated with the implementation of the desired gas utilization programs with the stakeholders, so that these can be tackled in a realistically timely way. Previous flare-out deadlines in 1984, 2004, and 2008 have all been missed [81], possibly because the stakeholders were not consulted in setting the targets, and they may have been unrealistic. The last flare-out deadline, for 2020 [31,81], was not met, because of this historical approach to establishing gas flare-out policies.
- Review the current flaring penalties with the oil companies, to possibly increase them each year, using the annual consumer inflation figure or some other agreed-upon escalator. Even though it was reviewed in 2018 for the first time since 1998, if all the oil companies were penalized at the upper limit of the new tariff (USD 2 per 1000 ft3 of gas flared [80]) and these were collected at the same proportion as reported previously [75], the total amount would add up to just over USD 9.7 million. Given that a gas-to-liquid plant could cost over GBP 2 billion to build [1] and mini-gas-to-liquid plants might require an investment of up to USD 140 million [65], it is still much cheaper to pay the penalties to flare gas than to utilize the flared gas.
- Involve smaller gas utilization operators in the gas flare management and incorporate policies (1 to 3) above in the arrangements. The Nigerian Gas Flare Commercialization Programme was set up to carry out and strengthen this type of policy [31] but it does not incorporate these three (1 to 3) measures enumerated above. Smaller gas utilization operators range from gas collection, storage, and distribution companies to operators of small to medium-sized power plants used in industries and residential estates.
- Strengthen the Department of Petroleum Resources [or similar departments] to train their personnel to measure, monitor, and report gas flares and enforce gas flare legislation and guidelines more effectively. This will enhance the monitoring of flares through the three stages of gas flare introduction and persistence (Figure 5). There has been uncertainty in the past about the actual number of gas flare sites in the region [82]. This makes policy decisions more difficult and less suitable.
7.4. Policy Options for the Affected Communities (Post-Flaring Stage)
7.4.1. Evacuation from Habitations Close to Gas Flare Sites
7.4.2. Improve National Macro-Economic Planning and Management, and Back This with Resource Allocation
7.4.3. Water Treatment
7.4.4. Corroding Roofs
7.4.5. Health Care
7.4.6. Education
7.5. The Science–Policy Gap Needs to Be Closed (Pre-Flaring, Flaring, Post-Flaring Stages)
- Increase the funding for scientific research on the impacts of gas flaring on the environment, the society, and the economy of the Niger Delta region. Engage academic experts in these areas. For example, although much of the retarding influence of gas flares on plant growth may be due to increases in soil temperature, there are indications that chemical products of the flares have impacts, such as sulfuric acid, which is responsible for acid rain, and carbon dioxide and methane, which are responsible for the greenhouse effect; chemicals also affect the surrounding vegetation, as some studies have pointed out [84]. An analysis of the composition of gas flare emissions and the impacts of polycyclic aromatic hydrocarbons (PAHs) will provide significant insight into the broader impacts of gas flaring. Studies should be intensified with respect to this to fully characterize the synergistic effects of the various pollutants emitted by the flares.The health and environmental (water, soil, air) effects should be rigorously studied by research institutions. The safe limits of habitation, farming, and fishing with regard to the distance to flare points must be determined scientifically. For example, an oil company had previously commissioned a study to disprove the link between acid rain and corroding roofs before this link was confirmed in a scientific study [63].To start with, a specific funding pool dedicated to these studies can involve funding calls over a period of 5 years, with each call addressing particular topics of need; something similar to the European Commission’s Horizon framework of funding calls could work [85].
- Data quality and management must be improved. Researchers and other stakeholders report inconsistent data; the variability makes interpretation difficult. For instance, the Nigerian Gas Flare Commercialization Programme, while putting out tenders for the utilization of gas from flare points, discovered that there were 38 more flare points than were previously known [34]; this complicated the commercialization process. Global surveys of natural gas flaring are now reliant on the use of VIIRS satellite-based sensors, which can detect and measure radiant emissions from gas flares from which the flared gas volume can then be estimated ([30], and Figure 4B). However, there are concerns that the increasing use of enclosed combustors, which enclose the flares in oil production facilities, might impede flare detection using VIIRS sensors [86]; thus, there might be gaps in the available data. Therefore, increased funding for staff training and the latest technological tools for acquiring gas flaring data are needed for effective data collection and management. There should be access to the flare gas data by personnel from other government agencies, and academic researchers. For instance, the 2018 flare gas guidelines appear to restrict the gas flare data for commercial reasons [80]. Emerging data collection issues, such as those due to enclosed flares in oil production facilities [86] must be understood. These gas flare data should also be compared with global trends, and the comparison could partly inform policy decisions.
7.6. Discussion and Limitations of the Study
8. Conclusions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
Correction Statement
References
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Area of Impact | Impacts of Gas Flaring |
---|---|
Environment | High concentrations of airborne pollutants [53,54,55,56]. Rainwater acidification [43,44,45,46,47]. Soil degradation [37,38]. Contributes to millions of metric tons of CO2 released per year [39]. Loss of biodiversity [43,46,49]. |
Society | Reductions in crop yield—less food security [37,43,68]. Charring of vegetation due to the heat—less food security [37,39]. Respiratory diseases, with occurrence more frequent the closer the inhabitants are to the gas flare point [43,53,54,55,56,60]. |
Economy | Loss of earnings for households due to reductions in crop yields [69]. Loss of earnings for households due to reductions in fishing yields [43]. Loss of earnings for the government due to flared gas [21,65,66,67,68,69,70,71,72,73,74,75,76]. Economic losses for individuals and industries due to increased maintenance of infrastructure [43,63,64]. |
How Does the Gas Flaring Occur? | Examples | Temporal Impact If Unresolved. Relationship to the Flaring Stages in Figure 5. |
---|---|---|
Routine gas flaring at an oil production facility during normal operations due to the unavailability of measures to utilize the gas in any form. Continuous. |
| Long-term impact on air quality, rainwater quality, soil quality, crop yields, respiratory diseases, and economic costs. Flaring and post-flaring stages. Pervasive impacts (Figure 5). |
Non-routine gas flaring. Intermittent. Short duration. Planned or unplanned. |
| Short-term, and possibly medium-term, impact on air quality, rainwater quality, soil quality, crop yields, respiratory diseases, and economic costs. Pre-flaring, flaring, and post-flaring stages. Mostly localized (Figure 5). |
Safety flaring of gas to enable the safe operation of an oil production facility. Emergency or planned. |
| Short-term, and possibly medium-term, impact on air quality, rainwater quality, soil quality, crop yields, respiratory diseases, and economic costs. Flaring, and post-flaring stages. Mostly localized (Figure 5). |
What Stage of the Flaring Process? | Strategy | Policy Options |
---|---|---|
Pre-flaring stage. The planning stage of the oil exploration/production facility. The facility is not in operation, yet. | Prevent gas flaring. | Associated gas utilization or prevention measures must be part of oil exploration/production plant design before a permit is given. |
Flaring stage. Oil exploration/production facility in operation. Gas flaring impacts are not yet pervasive. | Improve inspections at exploration/production facilities. Utilize the gas flared. | Strengthen the Department of Petroleum Resources to better monitor, measure, and report gas flares. Review the flaring penalties. Incorporate the smaller gas utilization operators into the gas flare management policies, including the recent gas flare commercialization program. |
Post-flaring stage. Oil exploration/production facility in operation for long enough for the gas flaring impacts to be pervasive. | Minimize the impacts of gas flaring on human health. Funded by the oil production tax currently in operation. | Relocate inhabitants from pervasively affected areas. Prohibit farming or fishing in pervasively affected areas. |
At all the flaring stages. Science and data quality. | Bridge the science–policy gap. Improve the data quality. Improve data management. | Fund comprehensive scientific studies on gas flaring. Strengthen the Department of Petroleum Resources to better acquire gas flaring data and manage and share the data with other national and international agencies. |
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Emekwuru, N. Characterization of the Dominant Stages at Which Gas Flaring Is Introduced: Impacts and Policy Options to Ameliorate Them. Environments 2024, 11, 158. https://doi.org/10.3390/environments11070158
Emekwuru N. Characterization of the Dominant Stages at Which Gas Flaring Is Introduced: Impacts and Policy Options to Ameliorate Them. Environments. 2024; 11(7):158. https://doi.org/10.3390/environments11070158
Chicago/Turabian StyleEmekwuru, Nwabueze. 2024. "Characterization of the Dominant Stages at Which Gas Flaring Is Introduced: Impacts and Policy Options to Ameliorate Them" Environments 11, no. 7: 158. https://doi.org/10.3390/environments11070158
APA StyleEmekwuru, N. (2024). Characterization of the Dominant Stages at Which Gas Flaring Is Introduced: Impacts and Policy Options to Ameliorate Them. Environments, 11(7), 158. https://doi.org/10.3390/environments11070158