Peak Oil Production

The Peak of World Oil Production and the Road to the Olduvai Gorge

Richard C. Duncan, Ph.D.

Pardee Keynote Symposia
Geological Society of America
Summit 2000
Reno, Nevada
November 13, 2000

The theory is a proposed way of measuring industrial civilisation by a single ratio - world annual energy use to population. The important idea is that, unlike previous civilisations which have risen and fallen to be replaced by others, industrial civilisation would be the last because we would have used up all the easily obtainable resources (oil, coal, minerals) which are necessary for a civilisation to form.

The theory is defined by the ratio of world energy production (use) and world population. The details are worked out. The theory is easy. It states that the life expectancy of Industrial Civilisation is less than or equal to 100 years: 1930–2030.

World energy production per capita from 1945 to 1973 grew at a breakneck speed of 3.45%/year. Next from 1973 to the all-time peak in 1979, it slowed to a sluggish 0.64%/year. Then suddenly – and for the first time in history - energy production per capita took a long-term decline of 0.33%/year from 1979 to 1999. The Olduvai theory explains the 1979 peak and the subsequent decline. More to the point, it says that energy production per capita will fall to its 1930 value by 2030, thus giving Industrial Civilisation a lifetime of less than or equal to 100 years.

Abstract

The Olduvai theory has been called unthinkable, preposterous, absurd, dangerous, self-fulfilling, and self-defeating. I offer it, however, as an inductive theory based on world energy and population data and on what I’ve seen during the past 30 years in some 50 nations on all continents except Antarctica. It is also based on my experience in electrical engineering and energy management systems, my hobbies of anthropology and archaeology, and a lifetime of reading in various fields.

The theory is defined by the ratio of world energy production (use) and world population. The details are worked out. The theory is easy. It states that the life expectancy of Industrial Civilization is less than or equal to 100 years: 1930-2030.

World energy production per capita from 1945 to 1973 grew at a breakneck speed of 3.45%/year. Next from 1973 to the all-time peak in 1979, it slowed to a sluggish 0.64%/year. Then suddenly —and for the first time in history — energy production per capita took a long-term decline of 0.33%/year from 1979 to 1999. The Olduvai theory explains the 1979 peak and the subsequent decline. More to the point, it says that energy production per capita will fall to its 1930 value by 2030, thus giving Industrial Civilization a lifetime of less than or equal to 100 years.

Should this occur, any number of factors could be cited as the 'causes' of collapse. I believe, however, that the collapse will be strongly correlated with an 'epidemic' of permanent blackouts of high-voltage electric power networks — worldwide. Briefly explained: "When the electricity goes out, you are back in the Dark Age. And the Stone Age is just around the corner."

The Olduvai theory, of course, may be proved wrong. But, as of now, it cannot be rejected by the historic world energy production and population data.

Institute on Energy and Man
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The Peak of World Oil Production and the Road to the Olduvai Gorge

Richard C. Duncan, Ph.D.

Pardee Keynote Symposia
Geological Society of America
Summit 2000
Reno, Nevada
November 13, 2000

Collapse, if and when it comes again, will this time be global. No longer can any individual nation collapse. World civilization will disintegrate as a whole. Competitors who evolve as peers collapse in like manner. Joseph A. Tainter, 1988

1. Introduction

The Olduvai theory is a data-based schema that states that the life expectancy of Industrial Civilization is less than or equal 100 years. We shall develop the theory from its early roots in Greek philosophy down to respected scientists in the 20th century. This approach is useful because, although the theory is easy to understand, it is difficult (i.e. distressing) for most people to accept - just as it was for me.

The Olduvai theory deals neither with the geology or the paleontology of the Olduvai Gorge. Nor is it prescriptive. Rather, the theory simply attempts to explain the historic world energy production (and use) and population data in terms of overshoot and collapse. I chose the name "Olduvai" because (1) it is justly famous, (2) I've been there, (3) its long hollow sound is eerie and ominous, and (4) it is a good metaphor for the 'Stone Age way of life'. In fact, the Olduvai way of life was (and still is) a sustainable way of life - local, tribal, and solar - and, for better or worse, our ancestors practiced it for millions of years.

No doubt that the peak and decline of Industrial Civilization, should it occur, will be due to a complex matrix of causes, such as overpopulation, the depletion of nonrenewable resources, environmental damage, pollution, soil erosion, global warming, newly emerging viruses, and resource wars. That said, the Olduvai theory uses a single metric only, as defined by "White's Law." But now it comes with a new twist - (((a will-o'-the-wisp))) - electricity.

Most of my industrial experience is in electric power networks and the energy management systems (EMS) that control them. Electricity is not a primary energy source, but rather an "energy carrier": zero mass, travels near the speed of light, and, for all practical purposes, it can't be stored. Moreover, electric power systems are costly, complex, voracious of fuel, polluting, and require 24h-7d-52w maintenance and operations. Another problem is that electricity is taken for granted. Just flip the switch and things happen. In short: Electricity is the quintessence of the 'modern way of life', but the electric power systems themselves are demanding, dangerous, and delicate. All this suggests that permanent blackouts will be strongly correlated with the collapse of Industrial Civilization - the so-named "Olduvai cliff," discussed later.

This paper is the backup for the accompanying slide show titled "The Olduvai Theory: An Illustrated Guide" (see Duncan, 2000c).

Definitions: "Oil" (O) means crude oil and natural gas liquids. 'Energy' (E) means the primary sources of energy - specifically oil, gas, coal, and nuclear & hydropower. 'Pop' means world population. 'ô' means oil production per capita. 'ê' means energy production per capita. "G" means billion (10^9). "b" means barrels of oil. 'boe' means barrels of oil equivalent (energy content, not quality). 'J' means joule. 'Industrial Civilization' and 'Electrical Civilization', as we shall see, mean the same thing.

Industrial Civilization is shown as a pulse-shaped curve of world average energy-use per capita (ê). The 'life expectancy' (i.e. 'duration') of Industrial Civilization is defined as the time (in years) between the upside point when ê reaches 30% of its peak value and the corresponding downside point when ê falls to the same value (Figure 4). The new twist is that the Olduvai theory now focuses on the mounting problems with the high-voltage electric power networks - worldwide.

Civilization and Ready Kilowatt: Although the fossil fuels are still very important, electricity is the indispensable end-use energy for Industrial Civilization. To determine its importance, it is essential to distinguish between the primary energy consumed to generate electricity versus the primary energy consumed for all other (i.e. non-electric) end-uses, such as work and heat. Consider the following. We estimate that 42% of the world's primary energy in 1999 was consumed to generate electricity. This compares to oil's contribution to all non-electric end-uses of 39%; gas' contribution of 18%; and coal's contribution of a mere 1%. Moreover: When energy quality is accounted for, then the importance of electricity becomes very, VERY clear. For example, if you want to heat your room, then 1 joule (J) of coal is 'equal' to 1 J of electricity. However, if you want to power up your TV, then 1 J of electricity is 'equal' to 3 J of coal! So if you're going to worry about energy, then don't loose sleep over oil, gas, and coal. Worry about the electric switch on the wall!

2. Energy And Civilization

Other factors remaining constant, culture evolves as the amount of energy harnessed per capita per year is increased, or as the efficiency of the instrumental means of putting the energy to work is increased. We may now sketch the history of cultural development from this standpoint. Leslie White, 1949 "White's Law"

Oil is liquid, power packed, and portable. It is the major primary source of energy for Industrial Civilization. (But not the major end-use source!) We have developed a new method of modeling and simulation and then used it to make a series of five forecasts of world oil production - one new forecast every year. Figure 1 shows the main results of our most recent forecast, i.e. Forecast #5. (Duncan, 2000b)

Figure 1. World, OPEC, and Non-OPEC Oil Production

Notes: (1) World oil production is forecast to peak in 2006. (2) The OPEC/non-OPEC crossover event occurs in 2008. (3) The OPEC nations' rate of oil production from 1985 to 1999 increased by 9.33 times that of the non-OPEC nations.

Figure 1 shows the historic world oil production data from 1960 to 1999 and our forecasts from 2000 to 2040. Note that the overall growth rate of oil production slowed from 1960 to 1999 (curve 1). In detail: The average rate of growth from 1960 to 1973 was a whopping 6.65%/year. Next, from 1973 to 1979 growth slowed to 1.49%/year. Then, from 1979 to 1999, it slowed yet further to a glacial 0.75%/year. Moving beyond the historic period, Forecast #5 predicts that world oil production will reach its all-time peak in 2006. Then from its peak in 2006 to year 2040 world oil production will fall by 58.8 % - an average decline of 2.45%/year during these 34 years.

The OPEC/non-OPEC crossover event is predicted to occur in 2008 (Figure 1, curves 2 &3). This event will divide the world into two camps: one with surplus oil, the other with none. Forecast #5 presents the following scenario. (1) Beginning in 2008 the 11 OPEC nations will produce more than 50% of the world's oil. (2) Thereafter OPEC will control nearly 100% of the world"s oil exports. (3) BP Amoco (2000) puts OPEC's "proved reserves" at 77.6% of the world total. (4) OPEC production from 1985 to 1999 grew at a strong average rate of 3.46%/year. In contrast, non-OPEC production grew at sluggish 0.37%/year during this same 14-year period.

The oil forecasting models, the application program to run them, and a User's Guide are all available free at www.halcyon.com/duncanrc/. (Duncan, 2000a)

The peak of world oil production (2006) and the OPEC/non-OPEC crossover event (2008) are important to the 'Olduvai schema', discussed later. But first let's have a look at the ratio of world oil production and world population. Figure 2 shows the historic data.

Figure 2. World Average Oil Production per Capita: 1920-1999

Notes: (1) World average oil production per capita (ô) grew exponentially from 1920 to 1973. (2) Next, the average growth rate was near zero from 1973 to the all-time peak in 1979. (3) Then from its peak in 1979 to 1999, ô decreased strongly by an average of 1.20%/year. (4) Typical response: "I didn't know that!" (5) The little cartoons emphasize that oil is by far the major primary source of energy for transportation (i.e. about 95% of the oil produced in 1999 was used for transportation).

Figure 2 shows the world average oil production per capita from 1920 to 1999. The curve represents the ratio of world oil production (O) and world population (Pop): i.e. ô = O/(Pop) in barrels per capita per year (i.e. b/c/year). Note well that ô grew exponentially from 1920 to 1973. Next, growth was negligible from 1973 to the all-time peak in 1979. Finally, from its peak in 1979 to 1999, ô decreased at an average rate of 1.20%/year (i.e. from 5.50 b/c in 1979 to 4.32 b/c in 1999). "You've gotta be kidding!"

The 1979 peak and decline of world oil production per capita are shown on page 11 of BP Amoco (2000), www.bpamoco.com/worldenergy/. Not to be missed.

Bottom Line: Although world oil production (O) from 1979 to 1999 increased at an average rate of 0.75%/year (Figure 1), world population (Pop) grew even faster. Thus world oil production per capita (ô) declined at an average rate of 1.20%/year during the 20 years from 1979 to 1999 (Figure 2).

The main goals in this study, as was mentioned, are to describe, discuss, and test the Olduvai theory of Industrial Civilization against historic data. Applying White's Law, our metric (i.e. indicator) is the ratio of world total energy production (E) and world population (Pop): i.e. ê = E/(Pop). Figure 3 shows ê during the historic period.

Figure 3. World Energy Production per Capita: 1920-1999

Notes: (1) World average energy production per capita (ê) grew significantly from 1920 to its all-time peak in 1979. (2) Then from its peak in 1979 to 1999, ê declined at an average rate of 0.33%/year. This downward trend is the "Olduvai slope", discussed later. (3) The tiny cartoons emphasize that the delivery of electricity to end-users is the sin quo non of the 'modern way of life'. Not hydrocarbons.

Observe the variability of ê in Figure 3. In detail: From 1920 to 1945 ê grew moderately at an average of 0.69%/year. Then from 1945 to 1973 it grew at the torrid pace of 3.45%/year. Next, from 1973 to the all-time peak in 1979, growth slowed to 0.64%/year. But then suddenly - and for the first time in history - ê began a long-term decline extending from 1979 to 1999. This 20-year period is named the "Olduvai slope," the first of the three downside intervals in the "Olduvai schema."

Bottom Line: Although world energy production (E) from 1979 to 1999 increased at an average rate of 1.34%/year, world population (Pop) grew even faster. Thus world energy production per capita (ê) declined at an average rate of 0.33%/year during these same 20 years (Figure 3). See White's Law, top of this section.

Acknowledgments: As far as I know, credit goes to Robert Romer (1985) for being first to publish the peak-period data for world energy production per capita (ê) from 1900 to 1983. He put the peak (correctly!) in 1979, followed by a sharp decline through 1983, the last year of his data. Credit is also due to John Gibbons, et al. (1989) for publishing a graph of ê from 1950 to 1985. Gibbons, et al. put the peak in 1973. But curiously, neither of the above studies made any mention whatever about the importance of the peak and decline of world energy production per capita.

The 1979 peak and decline of world energy production per capita (ê) is shown on page 40 of BP Amoco (2000), www.bpamoco.com/worldenergy/. Have a look.

3. Evolution of an Idea

And what a glorious society we would have if men and women would regulate their affairs, as do the millions of cells in the developing embryo. Hans Spemann, 1938

The seeds of the Olduvai Theory were planted long ago. For example, the Greek lyric poet Pindar (c. 522-438 BCE) wrote, "What course after nightfall? Has destiny written that we must run to the end?" (Eiseley, 1970)

Arabic scholar Ibn Khaldun (1332-1406) regarded "group solidarity" as the primary requisite for civilization. "Civilization needs the tribal values to survive, but these very same values are destroyed by civilization. Specifically, urban civilization destroys tribal values with the luxuries that weaken kinship and community ties and with the artificial wants for new types of cuisine, new fashions in clothing, larger homes, and other novelties of urban life." (Weatherford, 1994)

Joseph Granvill in 1665 observed that, although energy-using machines made life easier, they also made it more dependent. "For example, if artificial demands are stimulated, than resources must be consumed at an ever-increasing pace." (Eiseley, 1970)

But, as far as I know, it was the American adventurer and writer Washington Irving (1783-1859) who was first to realize that civilization could quickly collapse.

Nations are fast losing their nationality. The great and increasing intercourse, the exchange of fashions and uniformity of opinions by the diffusion of literature are fast destroying those peculiarities that formerly prevailed. We shall in time grow to be very much one people, unless a return to barbarism throws us again into chaos. (Irving, 1822)

The first statement that I've found that Industrial Civilization is likely to collapse into a primitive mode came from the mathematical biologist Alfred Lotka.

The human species, considered in broad perspective, as a unit including its economic and industrial accessories, has swiftly and radically changed its character during the epoch in which our life has been laid. In this sense we are far removed from equilibrium - a fact that is of the highest practical significance, since it implies that a period of adjustment to equilibrium conditions lies before us, and he would be an extreme optimist who should expect that such adjustment can be reached without labor and travail. While such sudden decline might, from a detached standpoint, appear as in accord with the eternal equities, since previous gains would in cold terms balance the losses, yet it would be felt as a superlative catastrophe. Our descendants, if such as this should be their fate, will see poor compensation for their ills and in fact that we did live in abundance and luxury. (Lotka, 1925)

Polymath Norbert Wiener (1894-1964) wrote in 1950 that the best we can hope for the role of progress is that "our attempts to progress in the face of overwhelming necessity may have the purging terror of Greek tragedy."

[America's] resources seemed inexhaustible [in 1500] However, the existence of the new lands encouraged an attitude not unlike that of Alice's Mad Tea party. When the tea and cakes were exhausted at one seat, the natural thing was to move on and occupy the next seat. As time passed, the tea table of the Americas had proved not to be inexhaustible What many of us fail to realize is that the last four hundred years are a highly special period in the history of the world. This is partly the result of increased communication, but also of an increased mastery of nature which, on a limited planet like the earth, may prove in the long run to be an increased slavery to nature. (Wiener, 1950)

Sir Charles Galton Darwin wrote in 1953:

The fifth revolution will come when we have spent the stores of coal and oil that have been accumulating in the earth during hundreds of millions of years. It is to be hoped that before then other sources of energy will have been developed, but without considering the detail [here] it is obvious that there will be a very great difference in ways of life. Whether a convenient substitute for the present fuels is found or not, there can be no doubt that there will have to be a great change in ways of life. This change may justly be called a revolution, but it differs from all the preceding ones in that there is no likelihood of its leading to increases of population, but even perhaps to the reverse. (Darwin, 1953)

Sir Fred Hoyle in 1964 put it bluntly.

It has often been said that, if the human species fails to make a go of it here on the Earth, some other species will take over the running. In the sense of developing intelligence this is not correct. We have or soon will have, exhausted the necessary physical prerequisites so far as this planet is concerned. With coal gone, oil gone, high-grade metallic ores gone, no species however competent can make the long climb from primitive conditions to high-level technology. This is a one-shot affair. If we fail, this planetary system fails so far as intelligence is concerned. The same will be true of other planetary systems. On each of them there will be one chance, and one chance only. (Hoyle, 1964)

4. World Models, etc.

Perhaps the most widespread evil is the Western view of man and nature. Among us, it is widely believed that man is apart from nature, superior to it; indeed, evolution is a process to create man and seat him on the apex of the cosmic pinnacle. He views the earth as a treasury that he can plunder at will. And, indeed, the behavior of Western people, notably since the advent of the Industrial Revolution, gives incontrovertible evidence to support this assertion.

Ian McHarg, 1971

Jay Forrester of MIT in 1970 built a world model "to understand the options available to mankind as societies enter the transition from growth to equilibrium."

What happens when growth approaches fixed limits and is forced to give way to some form of equilibrium? Are there choices before us that lead to alternative world futures? Exponential growth does not continue forever. Growth of population and industrialization will stop. If man does not take conscious action to limit population and capital investment, the forces inherent in the natural and social system will rise high enough to limit growth. The question is only a matter of when and how growth will cease, not whether it will cease. (Forrester, 1971)

The basic behavior of Forrester's world model was overshoot and collapse. It projected that the material standard of living (MSL) would peak in 1990 and then decline through the year 2100. Moreover, measured by the MSL (i.e. the leading and lagging 30% points), the life expectancy of Industrial Civilization was about 210 years. (Forrester, 1971, Figure 4-2). He used the world model to search for social (i.e. cultural, "conscious action") policies for making the transition to sustainability.

In our social systems, there are no utopias. No sustainable modes of behavior are free of pressures and stresses. But to develop the more promising modes will require restraint and dedication to a long-range future that man may not be capable of sustaining. Our greatest challenge now is how to handle the transition from growth into equilibrium. The industrial societies have behind them long traditions that have encouraged and rewarded growth. The folklore and the success stories praise growth and expansion. But that is not the path of the future. (ibid., 1971)

He found that sustainability could be achieved in the modeled world system when the following five social policies were applied together in 1970:

Natural-resource-usage-rate reduced 75%

Pollution generation reduced 50%

Capital-investment generation reduced 40%

Food production reduced 20%

Birth rate reduced 30% (ibid., 1971)

Critics (mostly economists) argued that such policies were e.g. "blue sky" and "unrealistic". Fortunately, the project team was just then completing a two-year study using the more comprehensive 'World3' model. They too searched for social policies that might achieve sustainability in the world system. However, the World3 'reference run' (like Forrester's in 1971) also projected overshoot and collapse of the world system.

This is the World3 reference run, . Both population POP and industrial output per capita IOPC grow beyond sustainable levels and subsequently decline. The cause of their decline is traceable to the depletion of nonrenewable resources. (Meadows, et al, 1972, Figure 35)

The World3 'reference run' (1972, above) projected that the industrial output per capita (IOPC) would reach its all-time peak in 2013 and then would steeply decline through 2100. Moreover, the duration of Industrial Civilization (as measured by the leading and lagging IOPC 30% points) came out to be about 105 years.

I first presented the Olduvai theory to the public in 1989.

The broad sweep of human history can be divided into three phases.

The first, or pre-industrial phase was a very long period of equilibrium when simple tools and weak machines limited economic growth.

The second, or industrial phase was a very short period of non-equilibrium that ignited with explosive force when powerful new machines temporarily lifted all limits to growth.

The third, or de-industrial phase lies immediately ahead during which time the industrial economies will decline toward a new period of equilibrium, limited by the exhaustion of nonrenewable resources and continuing deterioration of the natural environment. (Duncan, 1989)

In 1992, twenty years after the first World3 study, the team members re-calibrated the model with the latest data and used it to help "envision a sustainable future." But -

All that World3 has told us so far is that the model system, and by implication the "real world" system, has a strong tendency to overshoot and collapse. In fact, in the thousands of model runs we have tried over the years, overshoot and collapse has been by far the most frequent outcome. (Meadows, et al., 1992)

The updated World3 'reference run', in fact, gave almost exactly the same results as it did in the first study in 1972! For example: Industrial output per capita (IOPC) reached its all-time peak in 2014 (v. 2013 previously) and the duration of Industrial Civilization came out to be 102 years (v. 104 years previously).

Australian writer Reg Morrison likewise foresees that overshoot and collapse is where humanity is headed. In his scenario (i.e. no formal model), the world population rises to about 7.0 billion in the 2036. Thence it plunges to 3.2 billion in 2090 - an average loss of 71.4 million people per year (i.e. deaths minus births) during 54 years.

Given the current shape of the human population graph, those indicators also spell out a much larger and, from our point of view, more ominous message: the human plague cycle is right on track for a demographically normal climax and collapse. Not only have our genes managed to conceal from us that we are entirely typical mammals and therefore vulnerable to all of evolution's customary checks and balances, but also they have contrived to lock us so securely into the plague cycle that they seem almost to have been crafted for that purpose. Gaia is running like a Swiss watch. (Morrison, 1999)

The foregoing discussions show that many respected professionals have reached conclusions that are consistent with the Olduvai theory, to which we now turn.

5. The Olduvai Theory: 1930-2030

The earth's immune system, so to speak, has recognized the presence of the human species and is starting to kick in. The earth is attempting to rid itself of an infection by the human parasite.

Richard Preston, 1994

The Olduvai theory, to review, states that the life expectancy of Industrial Civilization is less than or equal to one hundred years, as measured by the world average energy production person per year: ê = E/(Pop). Industrial Civilization, defined herein, began in 1930 and is predicted to end on or before the year 2030. Our main goals for this section are threefold: (1) to discuss the Olduvai theory from 1930 to 2030, (2) to identify the important energy events during this time, and (3) to stress that Industrial Civilization = Electrical Civilization = the 'modern way of life.' Figure 4 depicts the Olduvai theory.

Figure 4. The Olduvai Theory: 1930-2030

Notes: (1) 1930 => Industrial Civilization began when (ê) reached 30% of its peak value. (2) 1979 => ê reached its peak value of 11.15 boe/c. (3) 1999 => The end of cheap oil. (4) 2000 => Start of the "Jerusalem Jihad". (5) 2006 => Predicted peak of world oil production (Figure 1, this paper). (6) 2008 => The OPEC crossover event (Figure 1). (7) 2012 => Permanent blackouts occur worldwide. (8) 2030 => Industrial Civilization ends when ê falls to its 1930 value. (9) Observe that there are three intervals of decline in the Olduvai schema: slope, slide and cliff - each steeper than the previous. (10) The small cartoons stress that electricity is the essential end-use energy for Industrial Civilization.

Figure 4 shows the complete Olduvai curve from 1930 to 2030. Historic data appears from 1930 to 1999 and hypothetical values from 2000 to 2030. These 100 years are labeled "Industrial Civilization." The curve and the events together constitute the "Olduvai schema." Observe that the overall curve has a pulse-like waveform - namely overshoot and collapse. Eight key energy events define the Olduvai schema.

Eight Events: The 1st event in 1930 (see Note 1, Figure 4) marks the beginning of Industrial Civilization when ê reached 3.32 boe/c. This is the "leading 30% point", a standard way to define the duration of a pulse. The 2nd event in 1979 (Note 2) marks the all-time peak of world energy production per capita when ê reached 11.15 boe/c. The 3rd event in 1999 (Note 3) marks the end of cheap oil. The 4th event on September 28, 2000 (Note 4) marks the eruption of violence in the Middle East - i.e. the "Jerusalem Jihad". Moreover, the "JJ" marks the end of the Olduvai "slope" wherein ê declined at 0.33%/year from 1979 to 1999.

Next in Figure 4 we come the future intervals in the Olduvai schema. The Olduvai "slide", the first of the future intervals, begins in 2000 with the escalating warfare in the Middle East. The 5th event in 2006 (Note 5) marks the all-time peak of world oil production (Figure 1, this paper). The 6th event in 2008 (Note 6) marks the OPEC crossover event when the 11 OPEC nations produce 51% of the world's oil and control nearly 100% of the world's oil exports. The year 2011 marks the end of the Olduvai slide, wherein ê declines at 0.67%/year from 2000 to 2011.

The "cliff" is the final interval in the Olduvai schema. It begins with the 7th event in 2012 (Note 7) when an epidemic of permanent blackouts spreads worldwide, i.e. first there are waves of brownouts and temporary blackouts, then finally the electric power networks themselves expire. The 8th event in 2030 (Note 8) marks the fall of world energy production (use) per capita to the 1930 level (Figure 4). This is the lagging 30% point when Industrial Civilization has become history. The average rate of decline of ê is 5.44%/year from 2012 to 2030.

"The hand writes, then moves on." Decreasing electric reliability is now.

The power shortages in California and elsewhere are the product of the nation's long economic boom, the increasing use of energy-guzzling computer devices, population growth and a slowdown in new power-plant construction amid the deregulation of the utility market. As the shortages threaten to spread eastward over the next few years, more Americans may face a tradeoff they would rather not make in the long-running conflict between energy and the environment: whether to build more power plants or to contend with the economic headaches and inconveniences of inadequate power supplies. (Carlton, 2000)

The electricity business has also run out of almost all-existing generating capacity, whether this capacity is a coal-fired plant, a nuclear plant or a dam. The electricity business has already responded to this shortage. Orders for a massive number of natural gas-fired plants have already been placed. But these new gas plants require an unbelievable amount of natural gas. This immediate need for so much incremental supply is simply not there. (Simmons, 2000)

As we have emphasized, Industrial Civilization is beholden to electricity. Namely: In 1999, electricity supplied 42% (and counting) of the world's end-use energy versus 39% for oil (the leading fossil fuel). Yet the small difference of 3% obscures the real magnitude of the problem because it omits the quality of the different forms of end-use energy. With apologies to George Orwell and the 2nd Law of Thermodynamics - "All joules (J) of energy are equal. But some joules are more equal than others." Thus, if you just want to heat your coffee, then 1 J of oil energy works just as well as 1 J of electrical energy. However, if you want to power up your computer, then 1 J of electricity is worth 3 J of oil. Therefore, the ratio of the importance of electricity versus oil to Industrial Civilization is not 42:39, but more like 99:1. Similar ratios apply to electricity versus gas and electricity versus coal.

Au Courant King Kilowatt!

Question: Where will the Olduvai die-off occur? Response: Everywhere. But large cities, of course, will be the most dangerous places to reside when the electric grids die. There you have millions of people densely packed in high-rise buildings, surrounded by acres-and-acres of blacktop and concrete: no electricity, no work, and no food. Thus the urban areas will rapidly depopulate when the electric grids die. In fact we have already mapped out the danger zones. (e.g. See Living Earth, 1996.) Specifically: The big cities stand out brightly as yellow-orange dots on NASA's satellite mosaics (i.e. pictures) of the earth at night. These planetary lights blare out "Beware", "Warning", and "Danger". The likes of Los Angeles and New York, London and Paris, Bombay and Hong Kong are all unsustainable hot spots.

6. Summary and Conclusions

The theory of civilization is traced from Greek philosophy in about 500 BCE to a host of respected scientists in the 20th century. For example: The 'reference runs' of two world simulation models in the 1970s put the life expectancy of civilization between about 100 and 200 years. The Olduvai theory is specifically defined as the ratio of world energy production and world population. It states that the life expectancy of Industrial Civilization is less than or equal to 100 years: from 1930 to 2030. The theory is tested against historic data from 1920 to 1999.

Although all primary sources of energy are important, the Olduvai theory postulates that electricity is the quintessence of Industrial Civilization. World energy production per capita increased strongly from 1945 to its all-time peak in 1979. Then from 1979 to 1999 - for the first time in history - it decreased from 1979 to 1999 at a rate of 0.33%/year (the Olduvai 'slope', Figure 4). Next from 2000 to 2011, according to the Olduvai schema, world energy production per capita will decrease by about 0.70%/year (the 'slide'). Then around year 2012 there will be a rash of permanent electrical blackouts - worldwide. These blackouts, along with other factors, will cause energy production per capita by 2030 to fall to 3.32 b/year, the same value it had in 1930. The rate of decline from 2012 to 2030 is 5.44%/year (the Olduvai 'cliff'). Thus, by definition, the duration of Industrial Civilization is less than or equal to 100 years.

The Olduvai 'slide' from 2001 to 2011 (Figure 4) may resemble the "Great Depression" of 1929 to 1939: unemployment, breadlines, and homelessness. As for the Olduvai 'cliff' from 2012 to 2030 - I know of no precedent in human history.

Governments have lost respect. World organizations are ineffective. Neo-tribalism is rampant. The population is over six billion and counting. Global warming and emerging viruses are headlines. The reliability of electric power networks is falling. And the instant the power goes out, you are back in the Dark Age.

In 1979 I concluded, "If God made the earth for human habitation, then He made it for the Stone Age mode of habitation." The Olduvai theory is thinkable.

References

BPAmoco (2000). BP Amoco Statistical Review of World Energy (1968-2000). BP Amoco, London. www.bpamoco.com/worldenergy/.
Carlton, J (2000). An Electricity Crunch May Force the Nation into Tough Tradeoffs. Wall Street Journal (October 10). p. A1.
Darwin, CG (1953). The Next Million Years. Doubleday, Garden City, NY. 210 p.
Duncan, RC (1989). Evolution, Technology, and the Natural Environment: A Unified Theory of Human History. Proceedings of the St. Lawrence Section ASEE Annual Meeting, Binghamton, NY. 14B1-11 to 14B1-20.
Duncan, RC (2000a). The Heuristic Oil Forecasting Method: User's Guide & Forecast #4. www.halcyon.com/duncanrc/ (Forecast #4). 30 p.
Duncan, RC (2000b). Crude Oil Production and Prices: A Look Ahead at OPEC Decision-Making Process. PTTC Workshop, Bakersfield, CA. (Forecast #5, September 22). 15 p.
Duncan, RC (2000c). The Olduvai Theory: An Illustrated Guide. Pardee Keynote Symposia, Geological Society of America, Summit 2000, Reno, NV. 6 p.
Eiseley, L (1970). The Invisible Pyramid. University of Nebraska Press, Lincoln. 173 p.
Forrester, J (1971, 1973). World Dynamics. Wright-Allen Press, Cambridge, MA. 144 p.
Gibbons, JH, Blair, PD and Gwin, HL (1989). Strategies for Energy Use. Scientific American, 261 (3), September, p. 86-93.
Hoyle, F (1964). Of Men and Galaxies. University of Washington Press, Seattle. 73 p.
Irving, W (1970). Journals and Notebooks, Vol. III, 1819-1827. University of Wisconsin Press, Madison, WI. 791 p.
Living Earth (1996). The Brilliant Earth: A Nocturnal Satellite Map. The Living Earth, Inc., Santa Monica, CA. Poster.
Lotka, AJ (1925). Elements of Physical Biology. Williams & Wilkins, Baltimore. 460 p.
McHarg, I (1971). Man, Planetary Disease. Vital Speeches of the Day (October). p. 634-640.
Meadows, DH, Meadows, DL, Randers, J and Behrens III, WW (1972, 1974). The Limits to Growth. New American Library, New York. 207 p.
Meadows, DH, Meadows, DL, Randers, J (1992). Beyond the Limits: Confronting Global Collapse, Envisioning a Sustainable Future. Chelsea Green, Post Mills, VT. 300 p.
Morrison, R (1999). The Spirit in the Gene: Humanity's Proud Illusion and the Laws of Nature. Cornell University Press, Ithaca, NY. 286 p.
Preston, R (1994). The Hot Zone. Doubleday, New York. 323 p.
Romer, RH (1985). Energy: Facts and Figures. Spring Street Press, Amherst, MA. 68 p.
Spemann, H (1938). Embryonic Development and Induction. Yale Univ. Pr., Newhaven, CN. 401 p.
Simmons, MR (2000). Energy in the New Economy: The Limits to Growth. Energy Institute of the Americas, Oklahoma City (October 2). 1 p.
Tainter, JA (1988). The Collapse of Complex Societies. Cambridge University Press, UK. 250p.
Weatherford, JM (1994). Savages and Civilization: Who Will Survive? Crown, New York. 310 p.
White, L (1949). The Science of Culture: A Study of Man and Civilization. Farrar, Straus & Co. New York. 444 p.
Wiener, N (1950, 1954). The Human Use of Human Beings: Cybernetics and Society. Doubleday, New York, 199 p.

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Institute on Energy and Man
5307 Ravenna Place NE, #1
Seattle, WA 98105
duncanrc@halcyon.com

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An in-depth analysis has been published in The Social Contract, Winter 2005-2006: The Olduvai Theory. Energy, Population, and Industrial Civilization.

"The Olduvai Theory states that the life expectancy of industrial civilization is approximately 100 years: circa 1930-2030. Energy production per capita (e) defines it. The exponential growth of world energy production ended in 1970... Average e will show no growth from 1979 through circa 2008 ... The rate of change of e will go steeply negative circa 2008 ... World population will decline to about two billion circa 2050 ... A growing number of independent studies concur...."

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The Olduvai Theory

The Olduvai Theory:
Sliding Towards a Post-Industrial Stone Age
Richard C. Duncan, Ph.D.
Institute on Energy and Man,
June 27, 1996

Indeed, the ability to control energy, whether it be making wood fires or building power plants, is a prerequisite for civilization.
-- Isaac Asimov, 1991

1. INTRODUCTION

In 1989, I concluded that the life-expectancy of Industrial Civilization is horridly short. This hypothesis was defined in terms of a measurable index, world energy-use per person, and named the "transient-pulse theory of Industrial Civilization." I sketched its maximum point at 1990, followed by a persistent decline (see Note 1). Back then, however, I had no data to support this claim.

The ratio of world annual energy-use to world population gives a robust, testable profile of Industrial Civilization. Over the past six years, I devised a quantitative basis for the theory and gathered several sets of world energy and population data to test it (Note 2). In these pages, the name "Olduvai theory" means the same as "transient-pulse theory," used in previous papers (Note 3).

[ Note 1: 'Industrial Civilization' includes all capital investments and international trade agreements such as GATT, EU, and NAFTA. 'GATT' means General Agreement on Tariffs and Trade; etc.
Note 2: 'World energy' includes oil, natural gas, coal, nuclear- and hydroelectricity. Energy and population data are available from several sources, e.g., United Nations publications.
Note 3: Since the 1950s, the Olduvai Gorge in Tanzania has been strongly associated with human origins and the Stone Age way-of-life. In this discussion, 'Olduvai theory' is a metaphor. It suggests our impending return to a Stone Age way-of-life.]

Please have a quick look at Figures 1 and 2. But before getting into the details, in the next section I'd like tell a detective story.

2. ODYSSEY: MY QUEST FOR THE OLDUVAI SIGNATURE

I would rather discover a single fact, even a small one, than debate the great issues at length without discovering anything at all.
-- Galileo Galilei, c. 1640

My Odyssey with the Olduvai theory began thirty-two years ago during a lecture series titled, Of Men and Galaxies, given at the University of Washington by cosmologist Sir Fred Hoyle.

It has often been said that, if the human species fails to make a go of it here on Earth, some other species will take over the running. In the sense of developing high intelligence this is not correct. We have, or soon will have, exhausted the necessary physical prerequisites so far as this planet is concerned. With coal gone, oil gone, high-grade metallic ores gone, no species however competent can make the long climb from primitive conditions to high-level technology. This is a one-shot affair. If we fail, this planetary system fails so far as intelligence is concerned. The same will be true of other planetary systems. On each of them there will be one chance, and one chance only. (Hoyle, 1964; emphasis added)

I was fascinated—and stunned. His soft-spoken proposal seemed incredulous, bizarre, preposterous—and possibly inevitable. A return to the Stone Age? Deep cultural and material impoverishment? However nobody else in the audience seemed the least concerned. Perhaps Hoyle was just giving a lead-in to his next science fiction thriller. So for the next decade I went about my way: raising kids, building airplanes and teaching engineers. Haunted by Hoyle's hypothesis.

Then in 1975 and 1976, conferences took me to Colorado and, by-the-by, to Mesa Verde National Park where the magnificent, long-deserted cliff dwellings of the Anasazi made it clear that all civilizations are ephemeral. But Fred Hoyle wasn't reiterating the tired old-saw of historian-philosophers such as Spencer, Spengler, Sorokin and Toynbee: i.e., the endless rise-and-fall cycles of civilizations. He was talking about something quite different, more profound, more pervasive. Global Industrial Civilization has no cycles at all. It's "a one-shot affair." Exponential growth, exponential decline. That's it.

Time passed, and the years from 1985 to 1992 found me working for power company in Saudi Arabia. While there, I traveled widely, including visits to Ethiopia, China, India, the (then) USSR, etc. Mainly I traveled to answer the question, "Is Fred Hoyle right?" The question, of course, was not about the durability of any one of these nations (most looked fragile, some non-existent), but about the life-expectancy of Global Industrial Civilization itself.

Based on what I'd seen around the world, industrialization isn't evolving toward sustainability. Just the opposite. Hoyle was right. "This is a one shot affair.... there will be one chance, and one chance only." So the real question was, "How long will it last?" A thousand years? A million years? Or what? So in 1989, just before leaving on a trip to East Africa (and incidentally, the Olduvai Gorge), I dug through some books. There was no lack of speculation. Estimates differed wildly; a summary appears in Table 1. [ For completeness, my 1991(a) estimate is included. ]

Table 1. Estimates of the Life-Expectancy of Industrial Civilization
Haldane	1927	"39 million years"
Russell	1949	"it cannot long continue"
Drake	1961	one million years
Watson	1969	potentially "millions of years"
Arrester	1971	natural response, about 200 years
Meadows, et al.	1972	natural response, 100-200 years
O'Neill	1976	"even our success becomes failure"
Leakey	1977	about 100 years
Harris	1977	"a bubble-like nature"
Crick	1981	short to 10,000 years or more
Laszlo	1987	"extremely short" to very long

Back in Saudi Arabia, I began a paper for presentation at the American Society of Engineering Educators Conference in New York, October, 1989. The title was, "Evolution, Technology, and the Natural Environment: A Unified Theory of Human History." So to say, the "coming-out" of the Olduvai theory. I concluded,

The broad sweep of human history can be divided into three phases:

• The first, or pre-industrial phase was a very long period of equilibrium when economic growth was limited by simple tools and weak machines.
• The second, or industrial phase was very short period of non-equilibrium that ignited with explosive force when powerful new machines temporarily lifted all limits to growth.
• The third, or de-industrial phase lies immediately ahead during which time industrial economies will decline toward a new period of equilibrium, limited by the exhaustion of non-renewable resources and continuing deterioration of the natural environment. (Duncan, 1989)

In that paper I used "world average energy-use per person" as a measurable indicator of Industrial Civilization. I sketched the peak at 1990. Only one problem— I had no hard data to test the theory. But I did have Hoyle's hypothesis and my own round-the-world observations of global conditions and trends.

Then, in the nick-of-time, an article appeared in the September issue of Scientific American showing that world average energy-use per person had peaked in about 1973, and had since gone into steep decline (Gibbons, et al., 1989; their curve is included in Figure 2). At the end of my presentation, a handful of engineers from the audience gathered around and we discussed my theory and its consequences. Most agreed. However I needed more data.

Again I returned to Saudi Arabia. But there, with meager access to data, I struggled with several more papers (e.g., Duncan, 1990; 1991a; 1991b). Then somehow the editor of a small journal got wind of what I was doing and invited me to submit an article. It was published as, "The Life-Expectancy of Industrial Civilization: The Decline to Global Equilibrium" (Duncan, 1993c). In the main it concluded,

• Industrial Civilization can be described by a single pulse waveform of duration X, as measured by average energy-use per person per year.
• The life-expectancy of Industrial Civilization is less than one-hundred (100) years: i.e., X <>

But data was still lacking.

I moved back to the USA, and by early-1993 had tested the Olduvai theory against two new sets of data. The energy data was from the energy industry itself, and the population data was from the United Nations [i.e., BP (1992) and UN (1992)].

Eureka! The Olduvai signature appeared at last. The British Petroleum and United Nations data confirmed that world per capita energy-use had peaked in about 1978 and subsequently had declined (Duncan, 1993b). Only the Olduvai theory could explain the peak and decline. In contrast, both the "exponential growth theory" (of "mainstream" economics) and "steady-state" theory (of "utopian" economics) failed.

By late-1993, I had further tested the Olduvai theory against several more sets of data, e.g., Davis (1990) and the UN (1993). In both cases, the historic peak occurred in about 1978. Again, the Olduvai theory prevailed (Note 4). I reported these results in a paper, "Sustainability—Is There a Middle Road?: The Transient-Pulse Theory of Industrial Civilization" (Duncan, 1993a).

[ Note 4: In the foregoing tests, I purposely avoided any dull mathematics. Only "long-division" was used: i.e., the ratio of world energy-use to population. Any 6th grader could do it. That's important. ]

While new energy and population data was coming in, I spent the next two and a half years developing a better method for predicting the energy production life-cycle (see Duncan, 1996). Although theoretically important, that work isn't relevant here because the Olduvai theory is arbitrated by historic data only.

Next, we'll take a closer look at the theory.

3. FROM THE CAVES, TO THE MOON, TO THE CAVES

The moon landing may be our Great Pyramid, an accomplishment never to be equaled.
-- Alan Cromer, 1993

Figure 1 is qualitative. Descriptive only. A visual aide. Right-brain stuff. It's a sketch of the Olduvai theory. The "Olduvai signature," I call it. So please don't try to scale out the horizontal or vertical axes. (We'll do that later.)

Figure 1. The Olduvai Theory of Industrial Civilization

1. Pre Industrial Phase [c. 3 000 000 BC to 1765]

• A - Tool making (c. 3 000 000 BC)
• B - Fire used (c. 1 000 000 BC)
• C - Noelithic agricultural revolution (c. 8 000 BC)
• D - Watts steam engine of 1765 Industrial Phase (1930-2025)

2. Industrial Phase [1930 to 2025, estimated ]

• E - Per capita energy-use 37% of peak value
• F - Peak energy-use
• G - Present energy-use
• H - Per capita energy-use 37% of peak value

3. Post Industrial Phase [c. 2100 and beyond ]

• J, K, and L = Recurring future attempts at industrialization fail.
  Other scenarios are possible.

[Note 5: In Figure 1, it may be helpful to think of the curve as income per person per year in dollars. Or perhaps as material standard of living. Better yet, just remember the little cartoon folks.]

Figure 1 divides the very long span of human history into three phases: (1) PreIndustrial, (2) Industrial, and (3) Post-Industrial. Seven events are marked on the left part of the curve (i.e., points A through G). Likewise, five hypothetical events are marked on the future part of the curve (i.e., H through L).

Phase 1, the Pre-Industrial Phase, spans thousands of millennia of sustainable conditions when society was powered exclusively by (renewable) solar energy. It began some three million years ago when our hominid ancestors started making simple tools (point A, Figure 1). The tools, in turn, made possible greater energy-use in such forms as food, fiber and shelter. Epic milestones leisurely passed, including the use of fire at about one million BCE and the Neolithic Agricultural Revolution at about 8,000 BCE. The end of the Pre-Industrial Phase is marked at 1765, the year James Watt invented the condensing steam engine (point D, Figure 1).

Phase 1 was followed by a transition period—i.e., The Industrial Revolution— delimited by the years 1765 and 1930 (points D and E, Figure 1).

Phase 2, the Industrial Phase, comprises the shaded portion of Figure 1. The life expectancy of Industrial Civilization is defined as the duration in years (x) between the leading and lagging "37% points" (i.e., points E and H). It is a short, extravagant period when transportation, commerce and industry were powered predominantly by (nonrenewable) fossil-fuels. Historic data (presented later) quantifies the peak period of the curve: i.e., the years between points E and G. Using that data, I mark the beginning of the Industrial Phase at 1930 (point E), the year average energy-use per person reached 37% of its peak value.

Note that the peak of Industrial Civilization was reached in about 1977 (point F), less than fifty years after it began. More significant, Figure 1 identifies the global energy "watershed". For the first time in the gaping millennia of human existence, average per capita energy-use peaked and began to decline!

As I read it, the descent into the Olduvai valley will be steep and swift. A scenario of Phase 3, the Post-Industrial Phase, is sketched in Figure 1 (i.e., from point I onward) wherein Industrial Civilization has disintegrated into farming villages, kinship tribes and rogue bands. The surviving population will have "achieved" permanent sustainability—at the subsistence level.

Of course, other scenarios are possible. For example, "The human species may follow the road to extinction rather than revert to the berry-picking stage" (Georgescu-Roegen, 1971). Or more recently, "The danger of extinction is real ... It is time to face the facts" (Leslie, 1996). However, because the circumstances of human society beyond the end of the second phase (i.e., point H. Figure 1) don't effect my thesis, the third phase is de-emphasized in the remainder of this discussion.

Hard to believe? Yes indeed. So let's do the numbers.

4. THE ENERGY WATERSHED _/\_ UP-SLOPE, PEAK, DOWN-SLOPE

Physicists learned to realize that whether they like a theory or they don't like a theory is not the essential question. Rather, it's whether or not the theory gives predictions that agree with experiment.
-- Richard Feynman, 1985

Figure 2 is quantitative. Numeric. Left-brain stuff. It's an accurately scaled graph showing the peak period of Industrial Civilization between 1950 and 1995. So please do scale out the horizontal and vertical axes. And if you'd like to go back to 3,000,000 BCE, Isaac Asimov (1991) gives all the numbers.

Figure 2. World Average Energy-Use Per Person
Comparison of Four Sets of Historic Data

"BOE" means Barrels of Oil Equivalent

As far as I know, credit goes to Robert H. Romer (1985) for first publishing the peak-period data for world per capita energy-use. He gives the peak at 1979, followed by a sharp decline through 1983, the last year of his data. However, this information was published as a relatively opaque worksheet. And curiously, no mention was made about the energy watershed. His data are graphed in Figure 2.

Credit likewise goes to Gibbons, et al. (1989; see Note 6) for an early publication of the peak-period of world per capita energy-use. The authors displayed the data as a viewer-friendly graph that peaked in 1973, followed by a steep downward slope through 1985. Here again, no mention was made about the significance of the peak or decline. Their curve is included in Figure 2.

[Note 6: Dr. Gibbons is Science Advisor to President Clinton.]

As previously mentioned, in 1993 I published two papers containing extensive world per capita energy-use data and presented that data as both worksheet values and plotted graphs. Moreover, I emphasized the importance of the peak and the implications of long-term decline. My first paper (1993b) shows the peak at 1978 and decline through 1991. My second paper (1993a) shows the peak at 1980 and decline through 1992. The two-year difference is due to the use of independent sets of data. In June 1996, I updated my tests of the Olduvai theory. This latest test shows the peak at 1978 followed by decline through 1995. The data are graphed in Figure 2.

A separate data test of the theory was made by F. M. Wright in June 1996. He showed the per capita energy-use peak at 1978 and overall decline continuing through 1994, as graphed in Figure 2. The slight difference between our curves results from the fact that Wright used US Census Bureau data for world population, while I used UN data. Note however that our curves are virtually superimposed.

Table 2 (below) summarizes the data tests. These tests show that, (1) on the average, world per capita energy-use peaked in 1977, and (2) the subsequent rate of decline has been about 0.90% per year. The Olduvai theory explains this data. In contrast, however, the exponential-growth theory and the steady-state theory both fail. While Table 2 isn't (yet) the Rosetta Stone of Industrial Civilization, each new set of data takes it one year closer.

Table 2. Data Tests of the Oduvai Theory

Author	Pub Dates	Data Period	Peak Year	Peak Value [BOE]*	Last Value [BOE]*	Years of Decline [#]	Rate of Decline [%/year]
Romer	1985	1900- 1983	1979	11.35	10.62	4	1.29
Gibbons, et al.	1989	1950- 1985	1973	11.54	9.19	12	1.57
Duncan	1989- 1996	1900- 1995	1978	11.47	10.24	17	0.63
Wright	1996	1965- 1994	1978	11.43	10.34	16	0.60
Average			1977	11.45			0.90

* "BOE" means Barrels of Oil Equivalent

Now let's stand back and look at the big picture.

5. DENYING THE UNDENIABLE

On the whole, however, it is only out of pride or gross ignorance, or cowardice, that we refuse to see in the present the lineaments of times to come.
-- Marguerite Yourcenar, 1951

Mental blockbusters have exploded throughout the history of human inquiry. "Revolutions" they're called. But typically they only pricked human egos, and ruffled vested interests and tired-old dogmas. Thus, the past discoveries (such as the solar-centric theory) were benign because such psycho-threats could simply be flouted or ignored. But the Olduvai theory is different because, willy-nilly, it will adversely impact the lives of almost everybody.

Back in 1989 I became deeply depressed when I concluded that our greatest scientific achievements will soon be forgotten and our most cherished monuments will crumble to dust. But more so, I knew that my children would feel the pressure, and will likely suffer. That really hurt.

In time however, my perspective changed. Now I just treat the Olduvai theory like any other scientific theory. Nothing personal. Each year, I gather the data. Update Figure 2. And watch the theory unfold. Let the chips fall. What else?

Still, the impending Post-Industrial Stone Age is a tragedy because it really isn't inevitable. There's no absolute reason why we couldn't live in material sufficiency on this planet for millions of years. But prudence isn't our forte. "Even our success becomes failure." And, in a way, it's not our fault. Long ago Natural Selection dealt us a bad hand—we're sexually prolific, tribal, short-term and self-centered. And after thousands of years of trying, Culture hasn't changed that. And there is no sign that She will.

Backward to the future. Forward to the past. Almost perfect symmetry.

6. SUMMARY AND CONCLUSIONS

Industrial Civilization doesn't evolve. Rather, it rapidly consumes "the necessary physical prerequisites" for its own existence. It's short-term, unsustainable. "This is a one shot affair.... there will be one chance, and one chance only."

Energy-use per person is used as a measurable index of industrialization. In 1989, I proposed the Olduvai theory of Industrial Civilization, as illustrated in Figure 1.

• Industrial Civilization can be described by a single pulse waveform of duration X, as measured by average energy-use per person per year.
• The life-expectancy of Industrial Civilization is less than one-hundred (100) years: i.e., X <>

In 1989 I postulated that per capita energy-use had peaked and was already on the decline. But back then I lacked sufficient data to test the theory.

By 1996, however, I had successfully tested the Olduvai theory against numerous sets of data. Four of these tests are graphed in Figure 2. The following facts emerge.

1. On the average, world per capita energy-use reached a maximum value (i.e., a peak) in 1977.
2. The 1977-1995 rate of decline has averaged 0.90% per year.
3. Per capita energy-use will continue to decline as long as the world population growth rate exceeds the energy growth rate.
4. If the decline continues (and extinction is avoided), human societies will bottom out at the subsistence level of energy-use.

The Olduvai theory explains the Figure 2 data, but the exponential-growth theory (of mainstream economics) and the steady-state theory both fail.

The Olduvai theory cannot be overthrown (i.e., scientifically rejected) by outrage or indignation. However, it can be overthrown by either, (1) demonstrating that the four sets of data in Figure 2 are in error, or (2) by gathering additional data over the next few decades and demonstrating that the Olduvai theory cannot explain that data. In any case, the data will be the final arbiter.

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Suggestion: If you're a 'lady or man from Missouri' or a 'doubting Teresa or Thomas' (and you should be), then go to your library, get the data, and test the Olduvai theory yourself. I'll gladly include your findings in the next update of Figure 2.

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References:

Asimov, I. & White, I. (1991) The March of The Millennia: A Key Look at History. New York: Walker.
BP (1996 & previous ed.). BP Statistical Review of World Energy. British Petroleum Company, London.
Cromer, A. (1993). How high, high-tech? Northeastern University Magazine, May. Boston.
Davis, G. R. (1990). Energy for planet earth. Scientific American 263, 21-27.
Duncan, R. C. (1996). The Mexican petroleum 'play' in two 'acts': Taking hold of oil production data. System Dynamics Conference Proceedings. System Dynamics Society, Cambridge, MA.
Duncan, R. C. (1993a). Sustainability—Is there a middle road? Moses Greeley Parker Lecture Series. Lowell, MA.
Duncan, R. C. (1993b). The realities of world energy production: A prediction based on historic data. Humanist Association of Massachusetts, Cambridge, MA.
Duncan, R. C. (1993c). The life-expectancy of Industrial Civilization: The decline to global equilibrium. Population and Environment 14, 325-357.
Duncan, R. C. (1991a). The life-expectancy of Industrial Civilization. System Dynamics Conference Proceedings (Bangkok). Systems Dynamics Society, Cambridge, MA.
Duncan, R. C. (199lb). The evolution of social control: Is a world society governable? Proceedings of the Preparing for a Sustainable Society Conference, Ryerson Polytechnical Institute, Toronto.
Duncan, R. C. (1990). A unified theory of human history: Summary presentation. AESR Newsletter, April, v. III, n. 1.
Duncan, R. C. (1989). Evolution, technology and the natural environment. Proceedings of the ASEE Conference, Binghamton, New York.
Feynman, R. P. QED, Princeton University Press, Princeton, NJ.
Georgescu-Roegen, N. (1971). The Entropy Law and The Economic Problem. The University of Alabama Distinguished Lecture Series #1.
Gibbons, J. H., Blair, P. D., & Gwin, H. L. (1989). Strategies for energy use. Scientific American, 3, 86-93.
Hoyle, F. (1964). Of Men and Galaxies. University of Washington Press, Seattle.
Leslie, J. (1996). The End of the World: The Science and Ethics of Human Extinction. Routledge, London.
Romer, R. H. (1985). Energy Facts and Figures. Spring Street Press, Amherst, MA.
UN (1996 & previous ed.). Statistical Yearbook. United Nations Organization, New York.
Wright, F. M. (1996). Personal communication. Seattle, WA.
Yourcenar, M. (1951). Memoirs of Hadrian. (1968 ea.) Penguin, Middlesex, UK.

Download Duncan & Youngquist's new world oil production model at http://www.halcyon.com/duncanrc/ .
To run this model one must download the free Stella Run-Time at http://www.hps-inc.com/products/STELLA/runtime.html .

For more from Duncan, see:
THE WORLD PETROLEUM LIFE-CYCLE: ENCIRCLING THE PRODUCTION PEAK
http://hubbertpeak.com/duncan/clinton.htm
http://hubbertpeak.com/duncan/index.html