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Oil and gas reserves and resource quantification

January 23, 2023

Oil and gas reserves denote discovered quantities of crude oil and natural gas (oil or gas fields) that can be profitably produced/recovered from an approved development. Oil and gas reserves tied to approved operational plans filed on the day of reserves reporting are also sensitive to fluctuating global market pricing. The remaining resource estimates (after the reserves have been accounted) are likely sub-commercial and may still be under appraisal with the potential to be technically recoverable once commercially established. Natural gas is frequently associated with oil directly and gas reserves are commonly quoted in barrels of oil equivalent (BoE). Consequently both oil and gas reserves, as well as resource estimates, follow the same reporting guidelines, and are referred to collectively hereinafter as oil & gas.[1]

Flaring a flow test, the first outward indication of a new oil or gas discovery, which has the potential to qualify for reserves assessment

Quantification

 
An oil well in Canada

Detailed classification schemes have been devized by industry specialists to quantify volumes of oil & gas accumulated underground (known as "subsurface"). These schemes provide management and investors with the means to make quantitative and relative comparisons between assets,[a] before underwriting the significant cost of exploring for, developing and extracting those accumulations.[2] Classification schemes are used to categorize the uncertainty in volume estimates of the recoverable oil & gas and the chance that they exist in reality (or risk that they do not) depending on the resource maturity.[b] Potential subsurface oil & gas accumulations identified during exploration are classified and reported as prospective resources. Resources are re-classified as reserves following appraisal, at the point when a sufficient accumulation of commercial oil and/or gas are proven by drilling, with authorized and funded development plans to begin production within a recommended five years.[3] Reserve estimates are required by authorities and companies, and are primarily made to support operational or investment decision-making by companies or organisations involved in the business of developing and producing oil & gas. Reserve volumes are necessary to determine the financial status of the company, which may be obliged to report those estimates to shareholders and "resource holders"[c] at the various stages of resource maturation.[d][4] Currently, the most widely accepted classification and reporting methodology is the 2018 petroleum resources management system (PRMS), which summarizes a consistent approach to estimating oil & gas quantities within a comprehensive classification framework, jointly developed by the Society of Petroleum Engineers (SPE), the World Petroleum Council (WPC), the American Association of Petroleum Geologists (AAPG), the Society of Petroleum Evaluation Engineers (SPEE) and the Society of Economic Geologists (SEG).[e][5] Public companies that register securities in the U.S. market must report proved reserves under the Securities and Exchange Commission (SEC) reporting requirements which shares many elements with PRMS.[f] Attempts have also been made to standardize more generalized methodologies for the reporting of national or basin level oil & gas resource assessments.[6]

Reserves and resource reporting

An oil or gas resource refers to known (discovered fields) or potential accumulations of oil and/or gas (i.e undiscovered prospects and leads) in the subsurface of the Earth's crust. All reserve and resource estimates involve uncertainty in volume estimates (expressed below as Low, Mid or High uncertainty), as well as a risk or chance to exist in reality,[g] depending on the level of appraisal or resource maturity that governs the amount of reliable geologic and engineering data available and the interpretation of those data.[h]

TABLE I:Classification summary featuring volumes uncertainty (low, mid or high) with increasing chance for an accumulation to exist and be commercial upwards reflecting greater resource maturity
RESOURCE CLASS LOW MID HIGH
Reserves 1P 2P 3P
Contingent Resources 1C 2C 3C
Prospective Resources 1U 2U 3U

Estimating and monitoring of reserves provides an insight into, for example, a company’s future production and a country’s oil & gas supply potential. As such, reserves are an important means of expressing value and longevity of resources.

In the PRMS, the terms ‘Resources’ and ‘Reserves’ have distinct and specific meaning with respect to oil & gas accumulations and hydrocarbon exploration in general. However, the level of rigor required in applying these terms varies depending on the resource maturity which informs reporting requirements.[i] Oil & gas reserves are resources that are, or are reasonably certain to be, commercial (i.e. profitable). Reserves are the main asset of an oil & gas company; booking is the process by which they are added to the balance sheet. Contingent and prospective resource estimates are much more speculative and are not booked with the same degree of rigor, generally for internal company use only, reflecting a more limited data set and assessment maturity. If published externally, these volumes add to the perception of asset value, which in turn can influence oil & gas company share or stock value.[7] The PRMS provides a framework for a consistent approach to the estimation process to comply with reporting requirements of particularly, listed companies.[8][j] Energy companies may employ specialist, independent, reserve valuation consultants to provide third party reports as part of SEC filings for either reserves or resource booking.[citation needed]

Reserves

Reserves reporting of discovered accumulations is regulated by tight controls for informed investment decisions to quantify differing degrees of uncertainty in recoverable volumes. Reserves are defined in three sub-categories according to the system used in the PRMS: Proven (1P), Probable and Possible. Reserves defined as Probable and Possible are incremental (or additional) discovered volumes based on geological and/or engineering criteria similar to those used in estimating Proven reserves. Though not classified as contingent, some technical, contractual, or regulatory uncertainties preclude such reserves being classified as Proven. The most accepted definitions of these are based on those originally approved by the SPE and the WPC in 1997, requiring that reserves are discovered, recoverable, commercial and remaining based on rules governing the classification into sub-categories and the declared development project plans applied.[9] Probable and Possible reserves may be used internally by oil companies and government agencies for future planning purposes but are not routinely or uniformly compiled.

Proven reserves

Main article: Proven reserves

Proven reserves are discovered volumes claimed to have a reasonable certainty of being recoverable under existing economic and political conditions, and with existing technology. Industry specialists refer to this category as "P90" (that is, having a 90% certainty of producing or exceeding the P90 volume on the probability distribution).[k] Proven reserves are also known in the industry as 1P.[10][11] Proven reserves may be referred to as proven developed (PD) or as proven undeveloped (PUD).[11][12] PD reserves are reserves that can be produced with existing wells and perforations, or from additional reservoirs where minimal additional investment (operating expense) is required (e.g. opening a set of perforations already installed).[12] PUD reserves require additional capital investment (e.g., drilling new wells) to bring the oil and/or gas to the surface.[10][12]

Accounting for production is an important exercise for businesses. Produced oil or gas that has been brought to surface (production) and sold on international markets or refined in-country are no longer reserves and are removed from the booking and company balance sheets. Until January 2010, "1P" proven reserves were the only type the U.S. SEC allowed oil companies to report to investors. Companies listed on U.S. stock exchanges may be called upon to verify their claims confidentially, but many governments and national oil companies do not disclose verifying data publicly. Since January 2010 the SEC now allows companies to also provide additional optional information declaring 2P (both proven and probable) and 3P (proven plus probable plus possible)[l] with discretionary verification by qualified third party consultants, though many companies choose to use 2P and 3P estimates only for internal purposes.[10]

Probable and Possible reserves

 
An example of a Volume Uncertainty Distribution, with the P10, P50 and P90 volumes indicated (created using a probabilistic calculation method)

Probable additional reserves are attributed to known accumulations and the probabilistic, cumulative sum of proven and probable reserves (with a probability of P50), also referred to in the industry as "2P" (Proven plus Probable)[13] The P50 designation means that there should be at least a 50% chance that the actual volumes recovered will be equal to or will exceed the 2P estimate.

Possible additional reserves are attributed to known accumulations that have a lower chance of being recovered than probable reserves.[1] Reasons for assigning a lower probability to recovering Possible reserves include varying interpretations of geology, uncertainty due to reserve infill (associated with variability in seepage towards a production well from adjacent areas) and projected reserves based on future recovery methods. The probabilistic, cumulative sum of proven, probable and possible reserves is referred to in the industry as "3P" (proven plus probable plus possible) where there is a 10% chance of delivering or exceeding the P10 volume.(ibid)

Resource estimates

Resource estimates are undiscovered volumes, or volumes that have not yet been drilled and flowed to surface. A non-reserve resource, by definition, does not have to be technically or commercially recoverable and can be represented by a single, or an aggregate of multiple potential accumulations, e.g. an estimated geological basin resource.[14]

 
Schematic graph illustrating petroleum volumes and probabilities. Curves represent categories of oil in assessment. There is a 95% chance i.e., probability, (P95 and often referred to in the industry as F95) of at least volume V1 of economically recoverable oil, and there is a 5% chance (P05 or F05) of at least volume V2 of economically recoverable oil.[15]

There are two non-reserve resource categories:

Contingent resources

Once a discovery has been made, prospective resources can be reclassified as contingent resources. Contingent resources are those accumulations or fields that are not yet considered mature enough for commercial development, where development is contingent on one or more conditions changing.[m] The uncertainty in the estimates for recoverable oil & gas volumes is expressed in a probability distribution and is sub-classified based on project maturity and/or economic status (1C, 2C, 3C, ibid) and in addition are assigned a risk, or chance, to exist in reality (POS or COS).[g]

Prospective resources

Prospective resources, being undiscovered, have the widest range in volume uncertainties and carry the highest risk or chance to be present in reality (POS or COS).[g] At the exploration stage (before discovery) they are categorized by the wide range of volume uncertainties (typically P90-P50-P10).[16] In the PRMS the range of volumes is classified by the abbreviations 1U, 2U and 3U again reflecting the degrees of uncertainty.[n] Companies are commonly not required to report publicly their views of prospective resources but may choose to do so voluntarily.[o][17]

Estimation techniques

The total estimated quantity (volumes) of oil and/or gas contained in a subsurface reservoir, is called oil or gas initially in place (STOIIP or GIIP respectively).[12] However, only a fraction of in place oil & gas can be brought to the surface (recoverable),[p] and it is only this producible fraction that is considered to be either reserves or a resource of any kind.[18] The ratio between in place and recoverable volumes is known as the recovery factor (RF), which is determined by a combination of subsurface geology and the technology applied to extraction.[13] When reporting oil & gas volumes, in order to avoid confusion, it should be clarified whether they are in place or recoverable volumes.

The appropriate technique for resource estimations is determined by resource maturity. There are three main categories of technique, which are used through resource maturation to differing degrees: analog (substitution), volumetric (static) and performance-based (dynamic), which are combined to help fill gaps in knowledge or data. Both probabilistic and deterministic calculation methods are commonly used to calculate resource volumes, with deterministic methods predominantly applied to reserves estimation (low uncertainty) and probabilistic methods applied to general resource estimation (high uncertainty).[19]

TABLE II:Estimation techniques applied with decreasing resource maturity to the right
Method Technique 1P 2P 3P 1C 2C 3C 1U 2U 3U
Analog YTF (No segment production)
YTF (With segment production)
Volumetric Deterministic
Probabilistic models
Static reservoir models
Performance-based Dynamic reservoir simulation
Material balance
Decline curve analysis
Unconventional reservoir Pilot (rate transient)

The combination of geological, geophysical and technical engineering constraints means that the quantification of volumes is usually undertaken by integrated technical, and commercial teams composed primarily of geoscientists and subsurface engineers, surface engineers and economists. Because the geology of the subsurface cannot be examined directly, indirect techniques must be used to estimate the size and recoverability of the resource. While new technologies have increased the accuracy of these estimation techniques, significant uncertainties still remain, which are expressed as a range of potential recoverable oil & gas quantities using probabilistic methods.[q] In general, most early estimates of the reserves of an oil or gas field (rather than resource estimates) are conservative and tend to grow with time.[20] This may be due to the availability of more data and/or the improved matching between predicted and actual production performance.

Appropriate external reporting of resources and reserves is required from publicly traded companies, and is an accounting process governed by strict definitions and categorisation administered by authorities regulating the stock market and complying with governmental legal requirements.[21] Other national or industry bodies may voluntarily report resources and reserves but are not required to follow the same strict definitions and controls.[22]

Analog (YTF) method

Analogs are applied to prospective resources in areas where there are little, or sometimes no, existing data available to inform analysts about the likely potential of an opportunity or play segment.[1] Analog-only techniques are called yet-to-find (YTF), and involve identifying areas containing producing assets that are geologically similar to those being estimated and substituting data to match what is known about a segment.[14][r] The opportunity segment can be scaled to any level depending on the specific interest of the analyst, whether at a global, country, basin, structural domain, play, license or reservoir level.[s][23] YTF is conceptual and is commonly used as a method for scoping potential in frontier areas where there is no oil or gas production or where new play concepts are being introduced with perceived potential. However, analog content can also be substituted for any subsurface parameters where there are gaps in data in more mature reserves or resource settings (below).[24]

Volumetric method

Oil & gas Volumes can be calculated using a volume equation:

Recoverable volume = Gross Rock Volume * Net/Gross * Porosity * Oil or Gas Saturation * Volume Factor * Recovery Factor[citation needed]

... where the gross rock volume describes the entire rock unit containing oil and/or gas, the Net/Gross discounts non-reservoir portions of the reservoir interval, the porosity describes the percentage of that net reservoir representing effective pore space (discounting reservoir matrix), the hydrocarbon saturation describes how much of the pore space is occupied by oil and/or gas (mixed with water), the volume factor defines the volume of oil (and dissolved gas) at reservoir pressure and temperature required to produce one stock tank barrel of oil at the surface and the recovery factor is expressed as the ratio between in-place and recoverable volumes. Deterministic volumes are calculated when single values are used as input parameters to this equation, which could include analog content. Probabilistic volumes are calculations when uncertainty distributions are applied as input to all or some of the terms of the equation (see also Copula (probability theory)), which preserve dependencies between parameters. These geostatistical methods are most commonly applied to prospective resources that still need to be tested by the drill bit. Contingent resources are also characterized by volumetric methods with analog content and uncertainty distributions before significant production has occurred, where spatial distribution information may be preserved in a static reservoir model.[1] Static models and dynamic flow models can be populated with analog reservoir performance data to increase the confidence in forecasting as the amount and quality of static geoscientific and dynamic reservoir performance data increase.[25]

Performance-based methods

Once production has commenced, production rates and pressure data allow a degree of prediction on reservoir performance, which was previously characterized by substituting analog data. Analog data can still be substituted for expected reservoir performance where specific dynamic data may be missing, representing a "best technical" outcome.[24]

Reservoir simulation

Main article: Reservoir simulation

Reservoir simulation is an area of reservoir engineering in which computer models are used to predict the flow of fluids (typically, oil, water, and gas) through porous media. The amount of oil & gas recoverable from a conventional reservoir is assessed by accurately characterising the static recoverable volumes and history matching that to dynamic flow.[t] Reservoir performance is important because the recovery changes as the physical environment of the reservoir adjusts with every molecule extracted; the longer a reservoir has been flowing, the more accurate the prediction of remaining reserves. Dynamic simulations are commonly used by analysts to update reserves volumes, particularly in large complex reservoirs. Daily production can be matched against production forecasts to establish the accuracy of simulation models based on actual volumes of recovered oil or gas. Unlike analogs or volumetric methods above, the degree of confidence in the estimates (or the range of outcomes) increases as the amount and quality of geological, engineering and production performance data increase. These must then be compared with previous estimates, whether derived from analog, volumetric or static reservoir modelling before reserves can be adjusted and booked.[25]

Materials balance method

The materials balance method for an oil or gas field uses an equation that relates the volume of oil, water and gas that has been produced from a reservoir and the change in reservoir pressure to calculate the remaining oil & gas. It assumes that, as fluids from the reservoir are produced, there will be a change in the reservoir pressure that depends on the remaining volume of oil & gas. The method requires extensive pressure-volume-temperature analysis and an accurate pressure history of the field. It requires some production to occur (typically 5% to 10% of ultimate recovery), unless reliable pressure history can be used from a field with similar rock and fluid characteristics.[13]

Production decline curve method

 
Example of a production decline curve for an individual well

The decline curve method is an extrapolation of known production data to fit a decline curve and estimate future oil & gas production. The three most common forms of decline curves are exponential, hyperbolic, and harmonic. It is assumed that the production will decline on a reasonably smooth curve, and so allowances must be made for wells shut in and production restrictions. The curve can be expressed mathematically or plotted on a graph to estimate future production. It has the advantage of (implicitly) conflating all reservoir characteristics. It requires a sufficient production history to establish a statistically significant trend, ideally when production is not curtailed by regulatory or other artificial conditions.[13]

Reserves growth

Experience shows that initial estimates of the size of newly discovered oil & gas fields are usually too low. As years pass, successive estimates of the ultimate recovery of fields tend to increase. The term reserve growth refers to the typical increases (but narrowing range) of estimated ultimate recovery that occur as oil & gas fields are developed and produced.[20] Many oil-producing nations do not reveal their reservoir engineering field data and instead provide unaudited claims for their oil reserves. The numbers disclosed by some national governments are suspected of being manipulated for political reasons.[26][27] In order to achieve international goals for decarbonisation, the International Energy Agency said in 2021 that countries should no longer expand exploration or invest in projects to expand reserves to meet climate goals set by the Paris Agreement.[28]

Unconventional reservoirs

Main article: Unconventional (oil & gas) reservoir

The categories and estimation techniques framed by the PRMS above apply to conventional reservoirs, where oil & gas accumulations are controlled by hydrodynamic interactions between the buoyancy of oil & gas in water versus capillary forces.[1] Oil or gas in unconventional reservoirs are much more tightly bound to rock matrices in excess of capillary forces and therefore require different approaches to both extraction and resource estimation. Unconventional reservoirs or accumulations also require different means of identification and include coalbed methane (CBM), basin-centered gas (low permeability), low permeability tight gas (including shale gas) and tight oil (including shale oil), gas hydrates, natural bitumen (very high viscosity oil), and oil shale (kerogen) deposits. Ultra low permeability reservoirs exhibit a half slope on a log-plot of flow-rates against time believed to be caused by drainage from matrix surfaces into adjoining fractures.[29] Such reservoirs are commonly believed to be regionally pervasive that may be interrupted by regulatory or ownership boundaries with the potential for large oil & gas volumes, which are very hard to verify. Non-unique flow characteristics in unconventional accumulations means that commercial viability depends on the technology applied to extraction. Extrapolations from a single control point, and thereby resource estimation, are dependent on nearby producing analogs with evidence of economic viability. Under these circumstances, pilot projects may be needed to define reserves.[1] Any other resource estimates are likely to be analog-only derived YTF volumes, which are speculative.

See also

Energy and resources:

References & Notes

  1. ^ a b c d e f SPE (2018). Petroleum Resource Management System (revised June 2018) (1.01 ed.). Society of Petroleum Engineers. p. 52. ISBN 978-1-61399-660-7.
  2. ^ McMichael, Claude L; Young, E.D. (2001). "Reserve Recognition Under Production-Sharing and Other Nontraditional Agreements" (PDF). SPE.org. Society of Petroleum Engineers. pp. 111–130. Retrieved 18 May 2022.
  3. ^ SPE (2018), Op. Cit., p7
  4. ^ Ross, James G. (2001). "Petroleum Resources Classification and Definitions" (PDF). SPE.org. Society of Petroleum Engineers. pp. 7–11. Retrieved 18 May 2022.
  5. ^ UNECE (2019). "Global Resource Classification Systems for Oil and Gas" (PDF). United Nations Economic Commission for Europe (UNECE). United Nations Economic Commission for Europe. Retrieved 28 April 2022.
  6. ^ USGS. "World Oil and Gas Resource Assessments". United States Geological Society. USGS. Retrieved 30 April 2022.
  7. ^ McMichael and Young (2001), Op. Cit., p112
  8. ^ UNECE (2021). "United Nations Resource Management System: An overview of concepts, objectives and requirements" (PDF). Sustainable Development Goals. United Nations Economic Commission for Europe. Retrieved 28 April 2022.
  9. ^ "Petroleum Reserves Definitions" (PDF). Petroleum Resources Management System. Society of Petroleum Engineers. 1997. Retrieved 20 April 2008.
  10. ^ a b c "Glossary of Terms Used in Petroleum Reserves/Resources" (PDF). Society of Petroleum Engineers. 2005. Retrieved 20 April 2008.
  11. ^ a b Wright, Charlotte J.; Rebecca A Gallun (2008). Fundamentals of Oil & Gas Accounting (5 ed.). PenWell Books. p. 750. ISBN 978-1-59370-137-6.
  12. ^ a b c d Hyne, Norman J. (2001). Nontechnical Guide to Petroleum Geology, Exploration, Drilling and Production. PennWell Corporation. pp. 431–449. ISBN 9780878148233.
  13. ^ a b c d Lyons, William C. (2005). Standard Handbook Of Petroleum & Natural Gas Engineering. Gulf Professional Publishing. pp. 5–6. ISBN 9780750677851.
  14. ^ a b Quirk, DG; Howe, MJ; Archer, SG (July 2017). "A Combined Deterministic-Probabilistic Method of Estimating Undiscovered Hydrocarbon Resources". Journal of Petroleum Geology. 40 (3): 217-248. Bibcode:2017JPetG..40..217Q. doi:10.1111/jpg.12674. S2CID 134783844.
  15. ^ "Petroleum Resources Management System". Society of Petroleum Engineers. 2007. Retrieved 20 April 2008.
  16. ^ SPE (2018), Op. Cit., p3
  17. ^ Securities and Exchange Commission. "MODERNIZATION OF OIL AND GAS REPORTING" (PDF). SEC rules. US Gov. Retrieved 19 June 2022.
  18. ^ SPE (2018), Op. Cit., p iv
  19. ^ SPEE (June 2019). "Annual Survey of Parameters Used in Property Evaluation". SPEE. Society of Petroleum Evaluators Engineers. p. 46. Retrieved 30 June 2022.
  20. ^ a b David F. Morehouse (1997). "The Intricate Puzzle of Oil and Gas Reserves Growth" (PDF). U.S. Energy Information Administration. (PDF) from the original on 6 August 2010. Retrieved 19 August 2014.
  21. ^ Ross (2001), Op. Cit., p4
  22. ^ Bebbington, Jan; Schneider, Thomas; Stevenson, Lorna; Fox, Alison (January 2020). "Fossil fuel reserves and resources reporting and unburnable carbon: Investigating conflicting accounts". Critical Perspectives on Accounting. 66: 102083. doi:10.1016/j.cpa.2019.04.004. S2CID 155591371. Retrieved 20 June 2022.
  23. ^ Schenk. "An Estimate of Undiscovered Conventional Oil and Gas Resources of the World, 2012" (PDF). World Petroleum Resources Project. USGS. Retrieved 1 July 2022.
  24. ^ a b Jones, A.D.; Denelle, F.R.; Lee, W.J.; MacDonald, D.G.; Seiller, B.J. (19 July 2016). "The Use of Reservoir Simulation in Deterministic Proved-Reserves Estimation". SPE Reservoir Evaluation & Engineering. 19 (3): 358–366. doi:10.2118/170669-PA. Retrieved 5 July 2022.
  25. ^ a b SPE (2011). Guidelines for Application of the Petroleum Resources Management System. Society of Petroleum Engineers. p. 222.
  26. ^ "Proven Oil Reserves". moneyterms.co.uk. 2008. Retrieved 17 April 2008.
  27. ^ The Asylum, Leah McGrath Goodman, 2011, Harper Collins
  28. ^ Chestney, Nina (18 May 2021). "End new oil, gas and coal funding to reach net zero, says IEA". Reuters. Retrieved 8 June 2022.
  29. ^ Bello, Rasheed O.; Wattenbarger, Robert A. (16 June 2008). CIPC/SPE Gas Technology Symposium 2008 Joint Conference: Rate Transient Analysis in Naturally Fractured Shale Gas Reservoirs. Calgary: SPE. doi:10.2118/114591-MS. ISBN 978-1-55563-179-6. Retrieved 7 July 2022.

Notes

  1. ^ a term commonly used to identify discoveries or producing fields
  2. ^ i.e. whether proven (low uncertainty) or unproven (high uncertainty)
  3. ^ resource holders are the legal owners of subsurface oil & gas resources and are commonly represented by the Governments of the day who own the mineral rights for oil and/or gas extraction
  4. ^ usually only proved reserves are reported
  5. ^ the definitions and guidelines contained in this article must not be construed as modifying the interpretation or application of any existing regulatory reporting requirements
  6. ^ The SEC reserves have a western / capitalistic emphasis on reporting the subset of in place oil & gas resources that are expected, with high confidence, to be extracted and converted into cash in a project that is going to yield a profit. The Russian and Chinese reserve systems have an emphasis on creating an inventory of oil & gas in place that have a potential of future exploitation to meet their national needs. Profitable extraction is convenient and appreciated, but not always a requirement for their national interests.
  7. ^ a b c expressed as a Possibility of Success (POS) sometimes called the COS or Chance of Success
  8. ^ Estimates for recoverable oil & gas volumes are expressed as a probability distribution with range of uncertainty from L, M , H and further sub-classified below based on project maturity and/or economic status (e.g 1C, 2C, 3C). In addition, each reserve class carries a risk, or chance to exist in reality (POS or COS) which is based on the amount and quality of available evidence. Naturally the highest chance (lowest risk) is associated with proven reserves (fields with wells and production tests) and the lowest chance (highest risk) is associated with undrilled prospects and leads where data is more sparse
  9. ^ e.g. internal reporting or external, public announcements and balance sheet disclosure to shareholders
  10. ^ PRMS, in effect, bridges the gap between western capitalist standards for reserves reporting regulated by SEC and those that serve local national interests. It provides a framework to create an inventory of resources that have the potential of becoming profitable by the implementation of development projects. Rather than focusing on in-place volumes, it is focused on the volumes that may ultimately be extracted.
  11. ^ The probabilities associated with the 1P, 2P and 3P reserve categories represent the chance to deliver or exceed the volumes declared. Perhaps counterintuitively these probabilities or chances decrease as the stated volumes increase and as such correspond to a decreasing confidence that the higher volumes can be delivered.
  12. ^ NOTE: SEC discourages the aggregation of estimates
  13. ^ e.g. stock market price, financial investment, technical innovations, market innovation or fiscal easing
  14. ^ uncertainty is expressed as a probabilistic range, which includes the chance or risk that hydrocarbons are absent. The combined most likely risked volume outcome, or chance-weighted mean, is called expectation
  15. ^ SEC does not allow reporting of undiscovered resources
  16. ^ the technically recoverable volume at a given set of market conditions is called the ultimate recovery (UR) or Estimated ultimate recovery (EUR)
  17. ^ reserves are frequently reported as a single Field or prospect or lead volume are defined by a single probability distribution the shape of which defines the most likely volume outcome and the volume uncertainty range (for example P50, P90, P10). Portfolio volumes similarly are estimated by combining individual probability distributions taking into account interdependencies between portfolio elements (i.e not a simple addition of ‘most likely volume’)
  18. ^ the argument being “if it works in this part of the world, then why not here?”
  19. ^ the larger the segment, the greater the degree of speculation
  20. ^ conventional reservoirs are characterised by buoyancy of oil, gas and water, estimated using Darcy flow in subsurface, which contrasts with unconventional reservoirs dominated by capillary forces

External links

  • Energy Supply page on the Global Education Project website, including many charts and graphs on the world's energy supply and use
  • Oil reserves (most recent) by country

January 23, 2023
reserves, resource, quantification, reserves, denote, discovered, quantities, crude, natural, fields, that, profitably, produced, recovered, from, approved, development, reserves, tied, approved, operational, plans, filed, reserves, reporting, also, sensitive,. Oil and gas reserves denote discovered quantities of crude oil and natural gas oil or gas fields that can be profitably produced recovered from an approved development Oil and gas reserves tied to approved operational plans filed on the day of reserves reporting are also sensitive to fluctuating global market pricing The remaining resource estimates after the reserves have been accounted are likely sub commercial and may still be under appraisal with the potential to be technically recoverable once commercially established Natural gas is frequently associated with oil directly and gas reserves are commonly quoted in barrels of oil equivalent BoE Consequently both oil and gas reserves as well as resource estimates follow the same reporting guidelines and are referred to collectively hereinafter as oil amp gas 1 Flaring a flow test the first outward indication of a new oil or gas discovery which has the potential to qualify for reserves assessment Contents 1 Quantification 2 Reserves and resource reporting 2 1 Reserves 2 1 1 Proven reserves 2 1 2 Probable and Possible reserves 2 2 Resource estimates 2 2 1 Contingent resources 2 2 2 Prospective resources 3 Estimation techniques 3 1 Analog YTF method 3 2 Volumetric method 3 3 Performance based methods 3 3 1 Reservoir simulation 3 3 2 Materials balance method 3 3 3 Production decline curve method 3 4 Reserves growth 4 Unconventional reservoirs 5 See also 6 References amp Notes 6 1 Notes 7 External linksQuantification Edit An oil well in Canada Detailed classification schemes have been devized by industry specialists to quantify volumes of oil amp gas accumulated underground known as subsurface These schemes provide management and investors with the means to make quantitative and relative comparisons between assets a before underwriting the significant cost of exploring for developing and extracting those accumulations 2 Classification schemes are used to categorize the uncertainty in volume estimates of the recoverable oil amp gas and the chance that they exist in reality or risk that they do not depending on the resource maturity b Potential subsurface oil amp gas accumulations identified during exploration are classified and reported as prospective resources Resources are re classified as reserves following appraisal at the point when a sufficient accumulation of commercial oil and or gas are proven by drilling with authorized and funded development plans to begin production within a recommended five years 3 Reserve estimates are required by authorities and companies and are primarily made to support operational or investment decision making by companies or organisations involved in the business of developing and producing oil amp gas Reserve volumes are necessary to determine the financial status of the company which may be obliged to report those estimates to shareholders and resource holders c at the various stages of resource maturation d 4 Currently the most widely accepted classification and reporting methodology is the 2018 petroleum resources management system PRMS which summarizes a consistent approach to estimating oil amp gas quantities within a comprehensive classification framework jointly developed by the Society of Petroleum Engineers SPE the World Petroleum Council WPC the American Association of Petroleum Geologists AAPG the Society of Petroleum Evaluation Engineers SPEE and the Society of Economic Geologists SEG e 5 Public companies that register securities in the U S market must report proved reserves under the Securities and Exchange Commission SEC reporting requirements which shares many elements with PRMS f Attempts have also been made to standardize more generalized methodologies for the reporting of national or basin level oil amp gas resource assessments 6 Reserves and resource reporting EditAn oil or gas resource refers to known discovered fields or potential accumulations of oil and or gas i e undiscovered prospects and leads in the subsurface of the Earth s crust All reserve and resource estimates involve uncertainty in volume estimates expressed below as Low Mid or High uncertainty as well as a risk or chance to exist in reality g depending on the level of appraisal or resource maturity that governs the amount of reliable geologic and engineering data available and the interpretation of those data h TABLE I Classification summary featuring volumes uncertainty low mid or high with increasing chance for an accumulation to exist and be commercial upwards reflecting greater resource maturity RESOURCE CLASS LOW MID HIGHReserves 1P 2P 3PContingent Resources 1C 2C 3CProspective Resources 1U 2U 3UEstimating and monitoring of reserves provides an insight into for example a company s future production and a country s oil amp gas supply potential As such reserves are an important means of expressing value and longevity of resources In the PRMS the terms Resources and Reserves have distinct and specific meaning with respect to oil amp gas accumulations and hydrocarbon exploration in general However the level of rigor required in applying these terms varies depending on the resource maturity which informs reporting requirements i Oil amp gas reserves are resources that are or are reasonably certain to be commercial i e profitable Reserves are the main asset of an oil amp gas company booking is the process by which they are added to the balance sheet Contingent and prospective resource estimates are much more speculative and are not booked with the same degree of rigor generally for internal company use only reflecting a more limited data set and assessment maturity If published externally these volumes add to the perception of asset value which in turn can influence oil amp gas company share or stock value 7 The PRMS provides a framework for a consistent approach to the estimation process to comply with reporting requirements of particularly listed companies 8 j Energy companies may employ specialist independent reserve valuation consultants to provide third party reports as part of SEC filings for either reserves or resource booking citation needed Reserves Edit Reserves reporting of discovered accumulations is regulated by tight controls for informed investment decisions to quantify differing degrees of uncertainty in recoverable volumes Reserves are defined in three sub categories according to the system used in the PRMS Proven 1P Probable and Possible Reserves defined as Probable and Possible are incremental or additional discovered volumes based on geological and or engineering criteria similar to those used in estimating Proven reserves Though not classified as contingent some technical contractual or regulatory uncertainties preclude such reserves being classified as Proven The most accepted definitions of these are based on those originally approved by the SPE and the WPC in 1997 requiring that reserves are discovered recoverable commercial and remaining based on rules governing the classification into sub categories and the declared development project plans applied 9 Probable and Possible reserves may be used internally by oil companies and government agencies for future planning purposes but are not routinely or uniformly compiled Proven reserves Edit Main article Proven reserves Proven reserves are discovered volumes claimed to have a reasonable certainty of being recoverable under existing economic and political conditions and with existing technology Industry specialists refer to this category as P90 that is having a 90 certainty of producing or exceeding the P90 volume on the probability distribution k Proven reserves are also known in the industry as 1P 10 11 Proven reserves may be referred to as proven developed PD or as proven undeveloped PUD 11 12 PD reserves are reserves that can be produced with existing wells and perforations or from additional reservoirs where minimal additional investment operating expense is required e g opening a set of perforations already installed 12 PUD reserves require additional capital investment e g drilling new wells to bring the oil and or gas to the surface 10 12 Accounting for production is an important exercise for businesses Produced oil or gas that has been brought to surface production and sold on international markets or refined in country are no longer reserves and are removed from the booking and company balance sheets Until January 2010 1P proven reserves were the only type the U S SEC allowed oil companies to report to investors Companies listed on U S stock exchanges may be called upon to verify their claims confidentially but many governments and national oil companies do not disclose verifying data publicly Since January 2010 the SEC now allows companies to also provide additional optional information declaring 2P both proven and probable and 3P proven plus probable plus possible l with discretionary verification by qualified third party consultants though many companies choose to use 2P and 3P estimates only for internal purposes 10 Probable and Possible reserves Edit An example of a Volume Uncertainty Distribution with the P10 P50 and P90 volumes indicated created using a probabilistic calculation method Probable additional reserves are attributed to known accumulations and the probabilistic cumulative sum of proven and probable reserves with a probability of P50 also referred to in the industry as 2P Proven plus Probable 13 The P50 designation means that there should be at least a 50 chance that the actual volumes recovered will be equal to or will exceed the 2P estimate Possible additional reserves are attributed to known accumulations that have a lower chance of being recovered than probable reserves 1 Reasons for assigning a lower probability to recovering Possible reserves include varying interpretations of geology uncertainty due to reserve infill associated with variability in seepage towards a production well from adjacent areas and projected reserves based on future recovery methods The probabilistic cumulative sum of proven probable and possible reserves is referred to in the industry as 3P proven plus probable plus possible where there is a 10 chance of delivering or exceeding the P10 volume ibid Resource estimates EditResource estimates are undiscovered volumes or volumes that have not yet been drilled and flowed to surface A non reserve resource by definition does not have to be technically or commercially recoverable and can be represented by a single or an aggregate of multiple potential accumulations e g an estimated geological basin resource 14 Schematic graph illustrating petroleum volumes and probabilities Curves represent categories of oil in assessment There is a 95 chance i e probability P95 and often referred to in the industry as F95 of at least volume V1 of economically recoverable oil and there is a 5 chance P05 or F05 of at least volume V2 of economically recoverable oil 15 There are two non reserve resource categories Contingent resources Edit Once a discovery has been made prospective resources can be reclassified as contingent resources Contingent resources are those accumulations or fields that are not yet considered mature enough for commercial development where development is contingent on one or more conditions changing m The uncertainty in the estimates for recoverable oil amp gas volumes is expressed in a probability distribution and is sub classified based on project maturity and or economic status 1C 2C 3C ibid and in addition are assigned a risk or chance to exist in reality POS or COS g Prospective resources Edit Prospective resources being undiscovered have the widest range in volume uncertainties and carry the highest risk or chance to be present in reality POS or COS g At the exploration stage before discovery they are categorized by the wide range of volume uncertainties typically P90 P50 P10 16 In the PRMS the range of volumes is classified by the abbreviations 1U 2U and 3U again reflecting the degrees of uncertainty n Companies are commonly not required to report publicly their views of prospective resources but may choose to do so voluntarily o 17 Estimation techniques EditThe total estimated quantity volumes of oil and or gas contained in a subsurface reservoir is called oil or gas initially in place STOIIP or GIIP respectively 12 However only a fraction of in place oil amp gas can be brought to the surface recoverable p and it is only this producible fraction that is considered to be either reserves or a resource of any kind 18 The ratio between in place and recoverable volumes is known as the recovery factor RF which is determined by a combination of subsurface geology and the technology applied to extraction 13 When reporting oil amp gas volumes in order to avoid confusion it should be clarified whether they are in place or recoverable volumes The appropriate technique for resource estimations is determined by resource maturity There are three main categories of technique which are used through resource maturation to differing degrees analog substitution volumetric static and performance based dynamic which are combined to help fill gaps in knowledge or data Both probabilistic and deterministic calculation methods are commonly used to calculate resource volumes with deterministic methods predominantly applied to reserves estimation low uncertainty and probabilistic methods applied to general resource estimation high uncertainty 19 TABLE II Estimation techniques applied with decreasing resource maturity to the right Method Technique 1P 2P 3P 1C 2C 3C 1U 2U 3UAnalog YTF No segment production YTF With segment production Volumetric Deterministic Probabilistic models Static reservoir models Performance based Dynamic reservoir simulation Material balance Decline curve analysis Unconventional reservoir Pilot rate transient The combination of geological geophysical and technical engineering constraints means that the quantification of volumes is usually undertaken by integrated technical and commercial teams composed primarily of geoscientists and subsurface engineers surface engineers and economists Because the geology of the subsurface cannot be examined directly indirect techniques must be used to estimate the size and recoverability of the resource While new technologies have increased the accuracy of these estimation techniques significant uncertainties still remain which are expressed as a range of potential recoverable oil amp gas quantities using probabilistic methods q In general most early estimates of the reserves of an oil or gas field rather than resource estimates are conservative and tend to grow with time 20 This may be due to the availability of more data and or the improved matching between predicted and actual production performance Appropriate external reporting of resources and reserves is required from publicly traded companies and is an accounting process governed by strict definitions and categorisation administered by authorities regulating the stock market and complying with governmental legal requirements 21 Other national or industry bodies may voluntarily report resources and reserves but are not required to follow the same strict definitions and controls 22 Analog YTF method Edit Analogs are applied to prospective resources in areas where there are little or sometimes no existing data available to inform analysts about the likely potential of an opportunity or play segment 1 Analog only techniques are called yet to find YTF and involve identifying areas containing producing assets that are geologically similar to those being estimated and substituting data to match what is known about a segment 14 r The opportunity segment can be scaled to any level depending on the specific interest of the analyst whether at a global country basin structural domain play license or reservoir level s 23 YTF is conceptual and is commonly used as a method for scoping potential in frontier areas where there is no oil or gas production or where new play concepts are being introduced with perceived potential However analog content can also be substituted for any subsurface parameters where there are gaps in data in more mature reserves or resource settings below 24 Volumetric method Edit Oil amp gas Volumes can be calculated using a volume equation Recoverable volume Gross Rock Volume Net Gross Porosity Oil or Gas Saturation Volume Factor Recovery Factor citation needed where the gross rock volume describes the entire rock unit containing oil and or gas the Net Gross discounts non reservoir portions of the reservoir interval the porosity describes the percentage of that net reservoir representing effective pore space discounting reservoir matrix the hydrocarbon saturation describes how much of the pore space is occupied by oil and or gas mixed with water the volume factor defines the volume of oil and dissolved gas at reservoir pressure and temperature required to produce one stock tank barrel of oil at the surface and the recovery factor is expressed as the ratio between in place and recoverable volumes Deterministic volumes are calculated when single values are used as input parameters to this equation which could include analog content Probabilistic volumes are calculations when uncertainty distributions are applied as input to all or some of the terms of the equation see also Copula probability theory which preserve dependencies between parameters These geostatistical methods are most commonly applied to prospective resources that still need to be tested by the drill bit Contingent resources are also characterized by volumetric methods with analog content and uncertainty distributions before significant production has occurred where spatial distribution information may be preserved in a static reservoir model 1 Static models and dynamic flow models can be populated with analog reservoir performance data to increase the confidence in forecasting as the amount and quality of static geoscientific and dynamic reservoir performance data increase 25 Performance based methods Edit Once production has commenced production rates and pressure data allow a degree of prediction on reservoir performance which was previously characterized by substituting analog data Analog data can still be substituted for expected reservoir performance where specific dynamic data may be missing representing a best technical outcome 24 Reservoir simulation Edit Main article Reservoir simulation Reservoir simulation is an area of reservoir engineering in which computer models are used to predict the flow of fluids typically oil water and gas through porous media The amount of oil amp gas recoverable from a conventional reservoir is assessed by accurately characterising the static recoverable volumes and history matching that to dynamic flow t Reservoir performance is important because the recovery changes as the physical environment of the reservoir adjusts with every molecule extracted the longer a reservoir has been flowing the more accurate the prediction of remaining reserves Dynamic simulations are commonly used by analysts to update reserves volumes particularly in large complex reservoirs Daily production can be matched against production forecasts to establish the accuracy of simulation models based on actual volumes of recovered oil or gas Unlike analogs or volumetric methods above the degree of confidence in the estimates or the range of outcomes increases as the amount and quality of geological engineering and production performance data increase These must then be compared with previous estimates whether derived from analog volumetric or static reservoir modelling before reserves can be adjusted and booked 25 Materials balance method Edit The materials balance method for an oil or gas field uses an equation that relates the volume of oil water and gas that has been produced from a reservoir and the change in reservoir pressure to calculate the remaining oil amp gas It assumes that as fluids from the reservoir are produced there will be a change in the reservoir pressure that depends on the remaining volume of oil amp gas The method requires extensive pressure volume temperature analysis and an accurate pressure history of the field It requires some production to occur typically 5 to 10 of ultimate recovery unless reliable pressure history can be used from a field with similar rock and fluid characteristics 13 Production decline curve method Edit Example of a production decline curve for an individual well The decline curve method is an extrapolation of known production data to fit a decline curve and estimate future oil amp gas production The three most common forms of decline curves are exponential hyperbolic and harmonic It is assumed that the production will decline on a reasonably smooth curve and so allowances must be made for wells shut in and production restrictions The curve can be expressed mathematically or plotted on a graph to estimate future production It has the advantage of implicitly conflating all reservoir characteristics It requires a sufficient production history to establish a statistically significant trend ideally when production is not curtailed by regulatory or other artificial conditions 13 Reserves growth Edit Experience shows that initial estimates of the size of newly discovered oil amp gas fields are usually too low As years pass successive estimates of the ultimate recovery of fields tend to increase The term reserve growth refers to the typical increases but narrowing range of estimated ultimate recovery that occur as oil amp gas fields are developed and produced 20 Many oil producing nations do not reveal their reservoir engineering field data and instead provide unaudited claims for their oil reserves The numbers disclosed by some national governments are suspected of being manipulated for political reasons 26 27 In order to achieve international goals for decarbonisation the International Energy Agency said in 2021 that countries should no longer expand exploration or invest in projects to expand reserves to meet climate goals set by the Paris Agreement 28 Unconventional reservoirs EditMain article Unconventional oil amp gas reservoir The categories and estimation techniques framed by the PRMS above apply to conventional reservoirs where oil amp gas accumulations are controlled by hydrodynamic interactions between the buoyancy of oil amp gas in water versus capillary forces 1 Oil or gas in unconventional reservoirs are much more tightly bound to rock matrices in excess of capillary forces and therefore require different approaches to both extraction and resource estimation Unconventional reservoirs or accumulations also require different means of identification and include coalbed methane CBM basin centered gas low permeability low permeability tight gas including shale gas and tight oil including shale oil gas hydrates natural bitumen very high viscosity oil and oil shale kerogen deposits Ultra low permeability reservoirs exhibit a half slope on a log plot of flow rates against time believed to be caused by drainage from matrix surfaces into adjoining fractures 29 Such reservoirs are commonly believed to be regionally pervasive that may be interrupted by regulatory or ownership boundaries with the potential for large oil amp gas volumes which are very hard to verify Non unique flow characteristics in unconventional accumulations means that commercial viability depends on the technology applied to extraction Extrapolations from a single control point and thereby resource estimation are dependent on nearby producing analogs with evidence of economic viability Under these circumstances pilot projects may be needed to define reserves 1 Any other resource estimates are likely to be analog only derived YTF volumes which are speculative See also Edit Energy portalExtraction of petroleum Oil in place Decline curve analysis Uncertainty Probability density function Copula probability theory Global strategic petroleum reserves Oil exploration Peak oil Petroleum Industry Strategic Petroleum Reserve List of acronyms in oil and gas exploration and production List of natural gas fields List of oil fields List of oilfield service companies Petroleum play Stranded gas reserve Estimated ultimate recoveryEnergy and resources Proven reserves Resource curse Energy security List of countries by proven oil reserves World energy resources and consumption Natural gas List of countries by natural gas proven reserves global strategic petroleum reservesReferences amp Notes Edit a b c d e f SPE 2018 Petroleum Resource Management System revised June 2018 1 01 ed Society of Petroleum Engineers p 52 ISBN 978 1 61399 660 7 McMichael Claude L Young E D 2001 Reserve Recognition Under Production Sharing and Other Nontraditional Agreements PDF SPE org Society of Petroleum Engineers pp 111 130 Retrieved 18 May 2022 SPE 2018 Op Cit p7 Ross James G 2001 Petroleum Resources Classification and Definitions PDF SPE org Society of Petroleum Engineers pp 7 11 Retrieved 18 May 2022 UNECE 2019 Global Resource Classification Systems for Oil and Gas PDF United Nations Economic Commission for Europe UNECE United Nations Economic Commission for Europe Retrieved 28 April 2022 USGS World Oil and Gas Resource Assessments United States Geological Society USGS Retrieved 30 April 2022 McMichael and Young 2001 Op Cit p112 UNECE 2021 United Nations Resource Management System An overview of concepts objectives and requirements PDF Sustainable Development Goals United Nations Economic Commission for Europe Retrieved 28 April 2022 Petroleum Reserves Definitions PDF Petroleum Resources Management System Society of Petroleum Engineers 1997 Retrieved 20 April 2008 a b c Glossary of Terms Used in Petroleum Reserves Resources PDF Society of Petroleum Engineers 2005 Retrieved 20 April 2008 a b Wright Charlotte J Rebecca A Gallun 2008 Fundamentals of Oil amp Gas Accounting 5 ed PenWell Books p 750 ISBN 978 1 59370 137 6 a b c d Hyne Norman J 2001 Nontechnical Guide to Petroleum Geology Exploration Drilling and Production PennWell Corporation pp 431 449 ISBN 9780878148233 a b c d Lyons William C 2005 Standard Handbook Of Petroleum amp Natural Gas Engineering Gulf Professional Publishing pp 5 6 ISBN 9780750677851 a b Quirk DG Howe MJ Archer SG July 2017 A Combined Deterministic Probabilistic Method of Estimating Undiscovered Hydrocarbon Resources Journal of Petroleum Geology 40 3 217 248 Bibcode 2017JPetG 40 217Q doi 10 1111 jpg 12674 S2CID 134783844 Petroleum Resources Management System Society of Petroleum Engineers 2007 Retrieved 20 April 2008 SPE 2018 Op Cit p3 Securities and Exchange Commission MODERNIZATION OF OIL AND GAS REPORTING PDF SEC rules US Gov Retrieved 19 June 2022 SPE 2018 Op Cit p iv SPEE June 2019 Annual Survey of Parameters Used in Property Evaluation SPEE Society of Petroleum Evaluators Engineers p 46 Retrieved 30 June 2022 a b David F Morehouse 1997 The Intricate Puzzle of Oil and Gas Reserves Growth PDF U S Energy Information Administration Archived PDF from the original on 6 August 2010 Retrieved 19 August 2014 Ross 2001 Op Cit p4 Bebbington Jan Schneider Thomas Stevenson Lorna Fox Alison January 2020 Fossil fuel reserves and resources reporting and unburnable carbon Investigating conflicting accounts Critical Perspectives on Accounting 66 102083 doi 10 1016 j cpa 2019 04 004 S2CID 155591371 Retrieved 20 June 2022 Schenk An Estimate of Undiscovered Conventional Oil and Gas Resources of the World 2012 PDF World Petroleum Resources Project USGS Retrieved 1 July 2022 a b Jones A D Denelle F R Lee W J MacDonald D G Seiller B J 19 July 2016 The Use of Reservoir Simulation in Deterministic Proved Reserves Estimation SPE Reservoir Evaluation amp Engineering 19 3 358 366 doi 10 2118 170669 PA Retrieved 5 July 2022 a b SPE 2011 Guidelines for Application of the Petroleum Resources Management System Society of Petroleum Engineers p 222 Proven Oil Reserves moneyterms co uk 2008 Retrieved 17 April 2008 The Asylum Leah McGrath Goodman 2011 Harper Collins Chestney Nina 18 May 2021 End new oil gas and coal funding to reach net zero says IEA Reuters Retrieved 8 June 2022 Bello Rasheed O Wattenbarger Robert A 16 June 2008 CIPC SPE Gas Technology Symposium 2008 Joint Conference Rate Transient Analysis in Naturally Fractured Shale Gas Reservoirs Calgary SPE doi 10 2118 114591 MS ISBN 978 1 55563 179 6 Retrieved 7 July 2022 Notes Edit a term commonly used to identify discoveries or producing fields i e whether proven low uncertainty or unproven high uncertainty resource holders are the legal owners of subsurface oil amp gas resources and are commonly represented by the Governments of the day who own the mineral rights for oil and or gas extraction usually only proved reserves are reported the definitions and guidelines contained in this article must not be construed as modifying the interpretation or application of any existing regulatory reporting requirements The SEC reserves have a western capitalistic emphasis on reporting the subset of in place oil amp gas resources that are expected with high confidence to be extracted and converted into cash in a project that is going to yield a profit The Russian and Chinese reserve systems have an emphasis on creating an inventory of oil amp gas in place that have a potential of future exploitation to meet their national needs Profitable extraction is convenient and appreciated but not always a requirement for their national interests a b c expressed as a Possibility of Success POS sometimes called the COS or Chance of Success Estimates for recoverable oil amp gas volumes are expressed as a probability distribution with range of uncertainty from L M H and further sub classified below based on project maturity and or economic status e g 1C 2C 3C In addition each reserve class carries a risk or chance to exist in reality POS or COS which is based on the amount and quality of available evidence Naturally the highest chance lowest risk is associated with proven reserves fields with wells and production tests and the lowest chance highest risk is associated with undrilled prospects and leads where data is more sparse e g internal reporting or external public announcements and balance sheet disclosure to shareholders PRMS in effect bridges the gap between western capitalist standards for reserves reporting regulated by SEC and those that serve local national interests It provides a framework to create an inventory of resources that have the potential of becoming profitable by the implementation of development projects Rather than focusing on in place volumes it is focused on the volumes that may ultimately be extracted The probabilities associated with the 1P 2P and 3P reserve categories represent the chance to deliver or exceed the volumes declared Perhaps counterintuitively these probabilities or chances decrease as the stated volumes increase and as such correspond to a decreasing confidence that the higher volumes can be delivered NOTE SEC discourages the aggregation of estimates e g stock market price financial investment technical innovations market innovation or fiscal easing uncertainty is expressed as a probabilistic range which includes the chance or risk that hydrocarbons are absent The combined most likely risked volume outcome or chance weighted mean is called expectation SEC does not allow reporting of undiscovered resources the technically recoverable volume at a given set of market conditions is called the ultimate recovery UR or Estimated ultimate recovery EUR reserves are frequently reported as a single Field or prospect or lead volume are defined by a single probability distribution the shape of which defines the most likely volume outcome and the volume uncertainty range for example P50 P90 P10 Portfolio volumes similarly are estimated by combining individual probability distributions taking into account interdependencies between portfolio elements i e not a simple addition of most likely volume the argument being if it works in this part of the world then why not here the larger the segment the greater the degree of speculation conventional reservoirs are characterised by buoyancy of oil gas and water estimated using Darcy flow in subsurface which contrasts with unconventional reservoirs dominated by capillary forcesExternal links EditEnergy Supply page on the Global Education Project website including many charts and graphs on the world s energy supply and use Oil reserves most recent by country Retrieved from https en wikipedia org w index php title Oil and gas reserves and resource quantification amp oldid 1127318633, wikipedia, wiki, book, books, library,

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