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An Analysis of U.S. and World Oil Production Patterns
Using Hubbert-Style Curves

Albert A. Bartlett
Department of Physics
University of Colorado at Boulder, 80309-0390


Mathematical Geology, Vol. 32, No 1, 2000


A quantitative analytical method, using a spreadsheet, has been developed which allows the determination of values of the three parameters that characterize the Hubbert-style Gaussian error curve that best fits the conventional oil production data both for the U.S. and the world.  The three parameters are: the total area under the Gaussian which represents the estimated ultimate ( oil ) recovery ( EUR), the date of the maximum of the curve, and the half-width of the curve.  The “best fit” is determined by adjusting the values of the three parameters to minimize the root-mean-square deviation ( RMSD ) between the data and the Gaussian.  The sensitivity of the fit to changes in values of the parameters is indicated by an exploration of the rate at which the RMSD increases as values of the three parameters are varied from the values that give the best fit.  The results of the analysis are as follows: (1) the size of the U.S. estimated ultimate recovery  ( EUR ) of oil is suggested to be  0.222 x 1012  barrels ( 0.222 trillion bbl ) of which approximately three-fourths appears to have been produced through 1995;  (2) if the world  EUR  is  2.0 x 1012 bbl, ( 2.0 trillion bbl )  a little less than half of this oil has been produced through 1995, and the maximum of world oil production is indicated to be in 2004;  (3)  each increase of one billion barrels in the size of the world EUR beyond the value of  2.0 x 1012  bbl can be expected to result in a delay of approximately 5.5 days in the date of maximum production; (4) alternate production scenarios are presented for world EURs of  3.0  and 4.0  x 1012 bbl.

Key Words: Petroleum,  Energy,  Gaussian, Logistic Curve, Peak Production, Estimated Ultimate Recovery, Reserves-to-Production Ratio


One of the best known products of the work of M. King Hubbert is the “Hubbert curve”  (Hubbert, 1974)  which empirically approximates the full cycle of the growth, peaking, and subsequent decline to zero of the “production” [ ( quantity / year )  vs. year ]  of a finite non-renewable resource.  The main central portion of a representative Hubbert-style curve is shown by the solid line of Figure 1.

This analysis is the result of asking the questions:

  1. What is the maximum amount of information one can gain from analytical comparisons of a Hubbert-style curve with data on historical oil production for the U.S. and for the world?
  2. How sensitive are the results of this analysis to changes in important parameters?
  3. How do the results of the analysis compare with the results of geological studies of the probable EUR?


                In his original work Hubbert fitted production data to the derivative of the Logistic curve, which is similar in shape to the Gaussian curve. ( Hubbert, 1982 )   The analysis described here was done with both curves to allow comparison of the results.  The differences in the results were smaller than the root mean square deviations of the fits, so that the results did not indicate a clear preference for either curve.  Both curves are widely understood, but the Gaussian curve was used because the analysis seemed simpler in execution and interpretation.

                No attempt was made to explore other similar curves to see if one could find a curve that gave a significantly improved fit to the data, nor was there any attempt to find improved fits by using superposition of several Gaussian curves representing the production patterns of several different regions or provinces.


                An analytical method will be outlined which allows one to determine the values of the three parameters of the Hubbert curve that gives the “best fit” to the historical data of oil production in the U.S. and world. 

                This method assumes that the complete curve of production vs. time of a non-renewable resource such as oil  ( the Hubbert curve )  can be represented by a Gaussian error curve ( Gaussian ) which is characterized by three parameters:

  1. The area under the Gaussian is the size Q of the EUR,  ( U.S. or world ), expressed in barrels, ( bbl ) ;
  2. The time  tM  is the date ( year ) of the peak of the Gaussian;
  3. The parameter  S  , ( years ) is a measure of the width of the Gaussian.

                Logic suggests that it is best to express quantities of oil in the SI units of cubic meters or joules of energy.  However in the lingua franca of the world oil business, the “barrel” ( bbl ) is the standard unit of quantity.  The following conversion factors may be used to convert barrels to cubic meters or to convert barrels of oil to joules of energy.

                One barrel has the volume of  0.15899...  cubic meters.

                One barrel of oil has an energy content of approximately 5.9 x 109 joules.

                Production data have only approximately followed the Gaussian pattern in the past.  However, as Hubbert pointed out, over the long run, production of oil started initially at zero, will rise to one or more maxima and then, at some time in the future, will return to zero.  Because of these characteristics, the Gaussian can always be used as an approximate representation of the curve of production vs. time of oil or of any non-renewable resource. The actual production curves will be modified by economic, geological, political, technological, and other factors, which may result in a deterioration of the quality of the fit ( an increase in the RMSD ) between the data and the Gaussian, but the role of these important factors is limited to changing the quality of this fit.

As applied to oil, the method does the following:

  1. Uses the following data:
    1. the history of the production ( bbl / y ) of oil vs. time;
    2. the geologically estimated  EUR,  Q ;
  2. Uses all of the available annual oil production data, or a subset of the data;  the longer the time span covered by the data, the greater may be the precision of the fit between the Gaussian and the data.
  3. Is quantitative and analytical, using the accepted mathematical criterion that the Gaussian that is the “best fit” to the data is the one for which the root-mean-square deviation  ( RMSD )  between the historical data and the Gaussian has a minimum value;
  4. Is mathematically reproducible;
  5. Is easily updated as more production data become available;
  6. Produces numerical values ( primary values ) of the three parameters of the particular Gaussian that is the best fit to the data; this Gaussian is the “primary Gaussian.”
  7. Allows one to explore the “goodness” of the fit of the Gaussian to the data by determining how rapidly the RMSD of the best fit deteriorates ( increases )  with changes in any of the three parameters from their primary values;
  8. Can be used to determine “best fit” values for two of the parameters of the Gaussian, along with the associated RMSD, when the third parameter is given an arbitrary numerical value other than its “best fit” ( primary ) value.  The Gaussians calculated from these values of the three parameters are “secondary Gaussians.”
  9. Can be used to determine a  “best fit value” for one of the parameters of the Gaussian, along with the value of the associated RMSD, when the second and third parameters are given arbitrary values other than their primary values.    
  10. ( Except for the numerical value of  Q  ) is completely decoupled from theory, judgment, or speculation about the future consequences of complex geological, technological, economic, or political factors that can affect annual production.

This decoupling  (10)  need not be of concern because all of these factors were present and operating in the real-world data that Hubbert used when he recognized that the production curve had an approximately Gaussian shape.  These factors affect the quality of the fit between the Gaussian and the historical data.


Let us define quantities:

t      =   date  ( year )

tM     =   the date of the maximum of the Gaussian Hubbert curve

P      =   the production of oil in barrels per year, ( bbl / y )

Q     =      the estimated amount of oil remaining in the ground. ( bbl )

Q   =   the integrated total production ( bbl ) as the time  t  approaches infinity.  This is called the “Estimated Ultimate Recovery,” or EUR.

W     =  the full-width at half-height of the Gaussian

W     =  [ ( 8 ln 2 ) 0.5 S ]  =  2.355 . . . S where  S  is a convenient width parameter


                As it is applied to the oil analysis, the Gaussian curve for the annual production  vs.  time is given by: P  =  -  dQ / dt  =  [Q / ( S (2 p) 1/2 )]  exp [ - ( tM - t )2 / ( 2 S 2) ]

This equation for   P   contains the three parameters:  Q  ,  tM   and S  .


                One seeks the values of the three parameters that characterize the particular Gaussian which is the best fit to a set of historical oil production data.  First, one assumes reasonable approximate values of the three parameters and uses the spreadsheet  (Microsoft Excel 5.0 ) to calculate the year-by-year values of the Gaussian that is prescribed by these assumed values.  The root mean square deviation  ( RMSD ) between the assumed Gaussian and the historical data points is then calculated and is displayed.

                The values of the three parameters of the Gaussian are then varied systematically until the  RMSD  is found empirically to have a minimum value.  The Gaussian characterized by this minimum  RMSD  is the “primary Gaussian” which gives the best fit to the data.  The values of the three parameters that yield the primary Gaussian are then the “primary values” of these parameters.


                Figure 1 shows the plot of the U.S. oil production data ( USEIA, 1995 ) along with the primary Gaussian.   Table 1 tabulates the results of the analysis.

                The analysis suggests that approximately three fourths ( 77 % ) of the EUR, ( Q =  222.2 x 109 bbl )  in the  50  states had been produced by the end of  1995.

                This EUR gives a best fit that is significantly larger than the value found by Hubbert ( 1982 ) who based his analysis on U.S. production data for the lower  48  states through 1980.  Hubbert’s EUR was 161.8 x 109 bbl. ( p. 90 )


                Hubbert gave little detailed discussion of the magnitudes of the analytical uncertainties in the quantities he derived from his curve fitting.  The method used here allows the quantitative exploration of these uncertainties.

                The overall quality of the fit between the data and the primary Gaussian is indicated by the fact  ( Table 1 )  that the  RMSD  between the primary Gaussian and the data is  3.2 %  of the height of the Gaussian maximum. 

                To explore the sensitivity of the fit of the data to the primary Gaussian, one can give two of the three parameters their primary values of  Table 1, and then one can systematically change the value of the third parameter to explore how the RMSD changes with changes in the third parameter.  For example, when the parameters  S  and  t  have their primary values, how sensitive is the  RMSD  to changes in the parameter  Q  ( the EUR )?

The answer to this question is shown in the upper curve of  Figure 2, where one sees that increasing  Q  by  8.1 % , from its primary value of 222.2 x 109 bbl  to  240 x 109 bbl, causes the  RMSD  to increase approximately quadratically from  0.103 x  109  to  0.175 x 109  bbl / y , an increase of approximately 70 % .

                A second investigation is to give one parameter a value other than its primary value and then vary the values of the other two parameters until one finds a secondary minimum RMSD.  To illustrate: if one changes the value of Q from its primary value to 240 x 109 bbl, what is the RMSD  if S and tM are then varied from their primary values until a new minimum RMSD is found?  When this is done, the resulting secondary minimum is characterized by tM = 1977.5 and S = 29.7 y. The  RMSD is 0.1183 x 109 bbl / y , which is a point on the lower curve of  Figure 2 for Q = 240 x 109 bbl.

                Figure 3 shows the data, the primary Gaussian, and the secondary Gaussian that is the best fit to the data for an assumed value of the EUR, of  250 x 109  bbl.

                The results of a detailed exploration of the date of the peak of oil production in the U.S. as a function of the assumed size of Q is shown in Figure 4.   The slope of a chord between the ends of the plotted curve suggests that the date of peak production in the  U.S.  is delayed about 39 days for every billion barrels of new oil that is added to the estimated size of the EUR of the U.S.   The historical data show that the peak production of oil in the U.S. was in 1970 with a smaller peak following in 1984.


                If the three parameters are set at their primary values ( minimum RMSD ), and if then the assumed date of the peak  ( tM )  is moved from 1975.6 to 1980, the  RMSD  is found to increase by about  80 % .  If the three parameters are set at their primary values, and if then the assumed value of S is increased from 27.56 years to 30.00 years, the RMSD is found to increase by about 52 %.


                The data for world oil production ( USEIA, 1995 ) and the primary Gaussian that best fits the data are shown in Figure 5.

                The value of the EUR that gives the minimum RMSD for world oil is  1.115 x 1012 bbl, which is much smaller than the value ( 2.0 x 1012 bbl ) that Hubbert used in 1972.  This discrepancy points out a limitation of this analysis.  In contrast to the case of U.S. oil, the world data do not yet show a long and persistent downturn in production.  As a consequence, a wider range of values of the EUR can give plausible fits to the data.  This is illustrated in Figure 6.  For assumed values of the EUR that are less than the primary value, the RMSD rises very rapidly, but for values of the EUR that are greater than the primary value, the RMSD rises only slowly.

If a production maximum has not been passed, this analysis tends strongly to reject assumed values of the EUR that are less than the primary value, but the analysis does not discriminate strongly among values of the EUR that are larger than the primary value.

                If one traces out the date tM of the peak of the secondary Gaussians corresponding to a series of increasing values assumed for the EUR , one gets the curve shown in  Figure 7.   Reading from Figure 7,  it can be seen that for values of the EUR of 2.0 x 1012 bbl , 3.0 x 1012 bbl , and 4.0 x 1012 bbl , peak production is indicated for the years  2004, 2019, and 2030 respectively.

                The average slope of the curve of Figure 7 shows that for every new billion barrels of oil added to the estimate of the world”s EUR ,  the date of the world peak production is delayed approximately  5.5  days !  Doubling the world EUR moves the date of the maximum back by about 26 years!

                Figure 8 shows the data and the best-fit secondary Gaussians for these three assumed values of the EUR .  Three different values of the  EUR are listed in the upper left and the years of the corresponding peak production are given.  It should be noted that the highest curve in Figure 8 assumes not only that the  EUR  is  4.0 x 1012  bbl, but it implies that the world production capability and world demand can rise to 39 x 109  bbl / yr  by the peak year 2030.


                In Figure 9 one sees two curves of world daily per capita production of oil which are normalized to have the same value in the year 1920.  The upper curve assumes that the world population has not changed since 1920, while the lower curve takes account of the growth of world population since 1920, and so it shows the actual per capita oil production.  At the end of 1995, world per capita oil production was less than 2 L per person per day!  The world population is increasing ( 1996 ) by about  1.5 % per year  ( ~90  million per year ), so world oil production will have to climb by  1.5 %  per year just in order to keep the per capita world oil production constant with no further decline.

                For the U.S., the maximum per capita oil production was approximately 7 L per day in  1970  which has declined to approximately 4 liters per day in  1995.


                The ratio of current reserves  ( bbl )  to current annual production  ( bbl / y )  is the number of years the current reserves would last if the current annual production continued unchanged.  This number is widely quoted as an approximate indication of the future of oil production.  If the ratio has the value of  40  years, it means that the reserves would last  40  years  “at the present rate of production.”  ( Bartlett, 1978 )

This suggests to some that the world production might remain constant for 40 years and then abruptly drop to zero.  Rates of production are not constant over long periods, so this widely quoted ratio is a meaningless indicator of the future course of oil production.

                Theoretical curves that suggest the future path of the reserves-to-production ratio can be calculated for each of the best-fit Gaussians.  Figure 10 shows the predicted reserves-to-production ratio as a function of time for the primary Gaussian of Figure 1 for U.S. oil production.  Figure 11 shows three curves of the predicted reserves-to-production ratios for world oil production that correspond to the three Gaussians of Figure 8.

                One notes that for a fixed value of the EUR, the reserves-to-production ratio decreases monotonically but at a rate that is less rapid than one year each year.  New enlarged estimates of the value of the EUR could slow or temporarily reverse the decline in the actual ratio.

                In Figure 11 one can see that for EUR  =  2.0 x 1012 bbl ,  the world reserves-to- production ratio in the year 2000 can be estimated to be approximately  42  years.


                The term “sustainability” is frequently invoked to describe the conditions which will allow a society to continue many generations into the future. (Bartlett, 1997-98)   Figures 1 and 8 suggest that current rates of consumption of oil cannot continue for many generations in the future, so that present U.S. and world rates of consumption of oil are not sustainable.  In general, a society cannot be sustainable as long as it remains vitally dependent on oil.


                Because of the critical importance of oil to modern society, many studies have yielded estimates of the size of the remaining oil resources, and of the probable future paths of U.S. and world oil production.  Only a few are cited here.

                Campbell & Laherrere  ( 1998 )  report that “Global production of conventional oil will begin to decline sooner than most people think, probably within 10 years.”( p.78 )  “Using several different techniques to estimate the current reserves of conventional oil and the amount still left to be discovered, we conclude that the [ peak will be reached and the ] decline will begin before 2010.” ( p.79 )   From Figure 7 one sees that if the world EUR is  2.4 x 1012  bbl,  the year of the maximum of the Hubbert Gaussian is indicated to be in 2010.

                Edwards  ( 1997 )  has given an extensive summary of the works of others and has added his own detailed analysis of the long-term situations in the U.S. and the world in regard to all fossil fuels.  For U.S. oil, he cites ( his Table 4 )  three estimates of the EUR whose average is  277  x 109 bbl.  This is considerably higher than the 222.2 x 109 bbl that is yielded by this analysis.  The secondary curve for  277 x 109 bbl  would be some distance to the right of the secondary curve shown in Fig. 3.

                Edwards’  Table 1  lists  14  estimates of the EUR for world oil ranging from a low of 1.65 x 1012 bbl  to a high of   3.2 x 1012  bbl ,  along with  11  predictions of the date of the peak of world oil production.  The mean values of the EUR and their corresponding peak dates, along with the RMSD of the EUR and the peak dates, derived from the spread of the tabulated values, are: EUR =  ( 2.4  +/-  0.4 ) x 1012 bbl,   and Peak Date =  ( 2010  +/-  11 yrs ) .  Perhaps it is only fortuitous, but these two numbers are the coordinates of a point on the line of  Figure 7, and hence they are in agreement with the analysis given here.

                Ivanhoe  ( 1995 )  shows Hubbert curves for discoveries and production for both the U.S. and the world, and then shows graphically the probable production scenarios for the future.  In his Figure 3 he shows curves from Hubbert which he has reworked for world oil production based on  EURs  of 1.5 x 1012  and  2.0 x 1012  bbl.  The two peaks are shown in 1988 and 1996 respectively.  Ivanhoe’s peaks thus show that the delay in the date of the peak is approximately 5.8 days per billion barrels of oil added to the world EUR.

                Ivanhoe has written ( 1997 ) that the critical date when global oil demand will exceed world production will fall sometime between 2000 and 2010.

                MacKenzie  ( 1996 )  has done a computer analysis of world oil which he has combined with a review of published estimates of oil reserves.  He concludes that:  

At the low end, for EUR oil equal to 1.8 x 1012 bbl, peaking could occur as early as 2007; at the high end ( 2.3 x1012  bbl ), peaking could occur around 2014.  ( An implausibly high 2.6 x 1012 bbl for EUR would postpone peaking only another five years - -  to 2019 ).

MacKenzie’s computer-generated estimates can be compared with the estimates read from Figure 7 where, for EURs of 1.8 x 1012 , 2.3 x 1012 , and 2.6 x 1012  bbl , the predicted peak dates are in the years 2000, 2009, and 2013.

                From his analysis, MacKenzie has produced his estimate of the date of peak world production  vs  EUR  which is given in his Figure 13.  His predicted peak dates are 6 to 8 years later than those given here in Figure 7, but his curve has the same slope as Figure 7, namely 5.5 days delay per billion barrels added to the estimate of the EUR.

                Masters, Attanasi & Root ( 1994 ) have estimated the world  EUR of petroleum to be 2.3 x 1012  bbl.  They note that this value:

. . . is limited by our concepts of world petroleum geology and our understanding of specific basins; nonetheless, continued expansion of exploration activity, around the world, has resulted in only minimal adjustments to our quantitative understanding of ultimate resources. . .

They also indicate that:

Unconventional resources are present in large quantities, in particular in the Western Hemisphere, and are of a dimension to substantially contribute to world reserves should economic conditions permit.

                Adelman & Lynch   ( 1997 )  point out that even as oil is produced and used, estimates of reserves of oil generally to rise with time so that a “fixed view of resource limits creates undue pessimism.”  Their optimism is based on the past history of increases in the value of the world  EUR.

Because of the increases in reserves that they see, they indicate their belief that it is misleading to think of the EUR as a fixed quantity, so that analyses such as the one presented here are seriously misleading.

                We can note that according to Figure 7, an increase in the world EUR of approximately 66 billion bbl is necessary to delay the date of the maximum of the Gaussian by one year.


                The work reported here is an analytical study of the data on U.S. and world production of oil.  The study has no geological content beyond that of the values of the EUR.  The results are internally precise and self-consistent, and hence are reproducible, and they are consistent with the results of a number of other studies.  Studies based on assumed fixed values of the EURs are often criticized by noting that values of the EURs tend to increase with time.  Increasing estimates of the EUR of the U.S. can be accommodated in this analysis by referring to Figures 3 and 4.  The consequences of increasing estimates of the world EUR can be evaluated by examination of Figures 7 and 8.

                Prices, politics, and the consequences of the law of supply and demand will be significant short-term determinants of the course of oil production in the future.  The effects of these economic factors are not modeled in this analysis.

                Only time will tell the degree to which the results of this analysis may or may not be reasonable. 


                This work originated from discussions with Professors John D. Edwards ( Geology ) and Robert A. Ristinen ( Physics ).  I thank them for their insight and help.  Richard C. Duncan has very kindly shared with me the results of a number of his works.  In addition, I wish to express my great appreciation to Steve Anderson, L.F. ( Buzz ) Ivanhoe, James J. MacKenzie, Charles D. Masters, David Root, and Walter Youngquist for their many valuable suggestions.


Adelman, M. A. and Lynch, M. C., 1997, Fixed view of resource limit creates undue pessimism: Oil & Gas Journal, v. 95, no. 14,  p. 56-60

Bartlett, A. A., 1978, Forgotten fundamentals of the energy crisis: Am. Jour. of Phys., v. 46, p. 876-888

Bartlett, A. A., 1997-98, Reflections on sustainability, population growth, and the environment - revisited: Renewable Resources Jour., v. 15, no. 4, Winter 1997-1998, p. 6-23

Campbell, C. J. and Laherrere, J. H., 1998, The end of cheap oil:

Scientific American, v. 278, no.3, p. 78-83

Edwards, J. D., 1997, Crude oil and alternate energy production forecasts for the twenty-first century; the end of the hydrocarbon era: Am. Assoc. Petroleum Geologists, Bull., v. 81, no. 8, p. 1292-1305 . Much of this work was available earlier in a report from the Energy and Minerals Applied Research Center,  ( EMARC ) ( 1996 ), Department of Geological Sciences, University of Colorado at Boulder, 80309-0250

Hubbert, M. K., 1974, U.S. energy resources, a review as of 1972;  A background paper prepared at the request of Henry M. Jackson, Chairman, Committee on Interior and Insular Affairs, United States Senate, Pursuant to Senate Resolution 45, A National Fuels and Energy Policy Study: Serial No. 93 - 40 ( 92 - 75 ), Part 1.  U.S. Government Printing Office, Washington, 1974,  p. 186

Hubbert, M. K., 1982,  Oil and gas supply modeling: NBS special publication 631, U.S. Department of Commerce / National Bureau of Standards ( now the National Institute of Standards and Technology, NIST ) May 1982. p. 90

Ivanhoe, L.F., 1995, Future world oil supplies: there is a finite limit, World Oil, v. 216, no. 10, p. 77-88.

Ivanhoe, L.F., 1997, King Hubbert - updated; Hubbert Center Newsletter, No. 97 / 1, Colorado School of Mines, Golden, CO

MacKenzie, J.J., 1996, Oil as a finite resource: When is global production likely to peak? World Resources Institute, 1709 New York Ave. NW, Washington, D.C., 20006

Masters, C. D., Root, D. H., Attanasi, E. D., 1994, World petroleum assessment and analysis: Proceedings of the 14th World Petroleum Congress, John Wiley &  Sons, New York City, p. 529-541

(USEIA, 1995) U.S. Energy Information Administration, Annual Energy Review, 1995:  DOE / EIA ( 95 ) The U.S. production data are from the column “Crude Oil” of Table 5.1, p. 141. The world production data are from the column “World” of Table 11.5, p. 297


Analytically determined primary values of the three parameters that describe the Gaussian that is the best fit to the data on the production of oil in the U.S.

Ultimate Resource, Q , bbl                                                                          222.2 x 109                          

Year ( date ) of maximum,  tM                                                          1975.6                                    

S ( width parameter ) , years                                                                      27.56                                      

Quantities that characterize the primary Gaussian:

RMSD between the data and the primary curve: bbl / y           0.10293 x 109                          

Production through 1995: bbl                                                                 0.171 x 1012                        

Percent of  EUR produced by the end of 1995                            76.8 %                                   

Full-width at half-maximum of primary Gaussian: y                              64.9                                        

Gaussian maximum ( peak ) production, bbl / y                              3.217 x 109          

RMSD / maximum production                                                            3.20 %                                   


Figure 1.  The data for the production of oil in the U.S. are shown, along with the primary Gaussian.  This is the Gaussian that has the smallest RMSD and hence is the best fit to the data.   Each major square has the units of  1 x 109  bbl / y  multiplied by  20 y, equals  20 x 109  barrels of oil.

The values of the three parameters that characterize this Gaussian are given in Table 1.

Figure 2.  For U.S. oil, the upper curve shows the values of the  RMSD when   S   and   tM   have their primary values of   27.555   years and 1975.6   respectively,  and the assumed value of the EUR  ( Q )  of the U.S. is changed systematically about its primary value of   0.2222 x 1012 bbl. ( 0.22 trillion bbl )  The lower curve shows the values of the  RMSD when, for each non-primary value of the EUR , one systematically varies   S   and   tM   until one locates a secondary minimum value of the  RMSD.  The quantities   S   and   tM   have the same value ( their primary values ) for all points on the upper curve;  on the lower curve their values change from point to point.  The two curves share the same minimum at the primary value of  ( EUR  =  0.2222  x 1012 bbl ).

Figure 3.  The data for U.S. oil production and two Gaussians are shown: the left one is the primary Gaussian in which all three parameters are adjusted to give the minimum  RMSD  between the data and the curve.  The value of the EUR for this best-fit is   0.2222 x 1012 bbl.   The right curve is a secondary Gaussian for the case where the EUR is arbitrarily given the non-primary value of  0.250 x 1012 bbl, and then the two parameters   S  and  tM  were adjusted to find the values that gave the secondary minimum  RMSD.  The right curve represents a value of the EUR that is  12.5 %  higher than the primary value of  the EUR .   For the right curve, the  RMSD  of the fit of the Gaussian to the data is approximately  15 %  higher than it is for the fit of the primary Gaussian on the left.

Figure 4.   As one increases the assumed EUR  for the U.S., the date of the peak of the secondary Gaussians moves to later times; the delay is approximately 39 days for each billion barrels of oil that are added to the estimate of the EUR of the U.S.

Figure 5.  The data for world oil production are compared with the best-fit primary Gaussian.  Because the world data do not yet show a prolonged downturn, this analysis is very insensitive to the size of the parameter Q , ( the EUR ) which, from this fit, is lower than many geological estimates.  Curves for more widely accepted geological estimates of the EUR are shown in Figure 8.  The large fluctuations in the recent data are due to political and economic factors.

Figure 6.  The  RMSDs  of the secondary Gaussians for world oil are shown as a function of the assumed values of the world EUR.  The primary Gaussian that is shown in  Figure 5  is characterized by values of the EUR and the RMSD  at the minimum of this curve.  For assumed values of the EUR that are less than the minimum, the  RMSD  deteriorates ( rises ) rapidly, while for values larger than the minimum, the  RMSD  is seen to rise more slowly.  The reason for this asymmetry is the fact that the world oil production data have not yet shown any prolonged downturn.  This should be compared with the lower curve of Figure 2 which is the same plot for U.S. oil where there has been a long downturn in production and where the RMSD rise around the minimum is more symmetrical.

Figure 7. As one follows the secondary Gaussians for world oil for increasing assumed values of the EUR , the location of the peaks of the best-fit secondary Gaussians move to later times at a rate of approximately  5.5  days for each billion barrels of oil added to the EUR.  For assumed values of the EUR of  2.0 x 1012 bbl ,  3.0 x 1012 bbl, and 4.0 x 1012 bbl, this analysis suggests that the peaks would occur respectively in the years 2004, 2019, and 2030 and the respective peak productions would be  26.5 x 109 , 33 x 109 , and 39.5 x 109 bbl per year.

Figure 8.  The world oil production data are shown, along with three best-fit secondary Gaussians corresponding to values of the EUR of   2.0 x 1012 bbl ,  3.0 x 1012 bbl , and  4.0 x l012  bbl, with respective dates of peak production of  2004, 2019, and 2030.  The number of days required to produce one billion barrels of oil at each of the three peaks are, respectively, 13.8, 11.0, and 9.2.

Figure 9.  The lower curve shows the recent history of the per capita world production of oil which had its largest value of approximately  2.2  liters per ( person-day )  in the 1970s and which has fallen to approximately  1.7  liters per ( person-day )  by 1995.  The upper curve shows what the recent history would have been if the world population had not changed since 1920.

In the period from 1920  to 1995 the world population has had an average growth rate of  approximately 1.5 %  per year which has resulted in the population tripling in these 75 years.

Figure 10   This curve shows the reserves-to-production ratio for U.S. oil, and it is derived from the primary Gaussian for U.S. oil.  A point on the curve shows, for that date, how many years U.S. oil would last if production were held constant at the value it had on that date. For example, in the year 1980, the remaining reserves of U.S. oil would last approximately  30 years if production remained unchanged from its  1980 value: production would then drop abruptly to zero.

Figure 11   These curves show how the reserves-to-production ratios vary with time for each of the three Gaussians of Figure 8 which correspond to world EURs of  2.0,  3.0,  and 4.0 x 1012  bbl.  For example, if the world EUR is  3000  billion barrels, the reserves-to-production ratio in the year 2000 would be expected to be approximately  74  years.

Albert A. Bartlett; Professor Emeritus of Physics
University of Colorado, Boulder, 80309-0390; (303) 492 7016
Department Office: (303) 492 6952: FAX (303) 492 3352
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E-Mail: Albert.Bartlett@Colorado.EDU