Hubbert curve
The Hubbert curve is an approximation of the production rate of a resource over time. It is a symmetric
Shape
The prototypical Hubbert curve is a probability density function of a logistic distribution curve. It is not a gaussian function (which is used to plot normal distributions), but the two have a similar appearance. The density of a Hubbert curve approaches zero more slowly than a gaussian function:
The graph of a Hubbert curve consists of three key elements:
- a gradual rise from zero resource production that then increases quickly
- a "Hubbert peak", representing the maximum production level
- a drop from the peak that then follows a steep production decline.
The actual shape of a graph of real world production trends is determined by various factors, such as development of enhanced production techniques, availability of competing resources, and government regulations on production or consumption. Because of such factors, real world Hubbert curves are often not symmetrical.
Application
Peak oil
Using the curve, Hubbert modeled the rate of petroleum production for several regions, determined by the rate of new oil well discovery, and extrapolated a world production curve.[1] The relative steepness of decline in this projection is the main concern in peak oil discussions. This is because a steep drop in the production implies that global oil production will decline so rapidly that the world will not have enough time to develop sources of energy to replace the energy now used from oil, possibly leading to drastic social and economic impacts.
Other resources
Hubbert models have been used to predict the production trends of various resources, such as
Critique
After the predicted early-1970s peak of oil production in the U.S., production declined over the following 35 years in a pattern closely matching the Hubbert curve. However, new extraction methods began reversing this trend beginning in the mid-2000s decade, with production reaching 10.07 million b/d in November 2017 – the highest monthly level of crude oil production in U.S. history. As such, the Hubbert curve has to be calculated separately for different oil provinces, whose exploration has started at a different time, and oil extracted by new techniques, sometimes called
See also
- Bioeconomics (biophysical)
- Energy accounting
- Gaussian function, a "bell curve" shape
- Thermoeconomics
References
- ^ a b c d M. King Hubbert. "Nuclear Energy and the Fossil Fuels" (PDF). Drilling and Production Practice (1956) American Petroleum Institute & Shell Development Co. Publication No. 95, See Pp 9-11, 21-22. Archived from the original (PDF) on 2008-05-27.
- ^ Ugo Bardi and Leigh Yaxley. [1] Proceedings of the 4th ASPO Workshop, Lisbon 2005
- ^ Jean Laherrere. Multi-Hubbert Modeling. July, 1997.
- ^ Patzek, Tad (2008-05-17). "Exponential growth, energetic Hubbert cycles, and the advancement of technology". Archives of Mining Sciences. 53 (2): 131–159. Retrieved 2018-11-17.
External links
- The Hubbert Curve: Its Strengths And Weaknesses article by Jean Laherrère.
- Hubbert Math further mathematical manipulations by a Stanford professor
- M. King Hubbert Bibliography