I = PAT

I = PAT is the lettering of a formula put forward to describe the impact of human activity on the environment.

I = P × A × T

In words:

Human Impact on the environment equals the product of Population, Affluence, and Technology. This shows how the population, affluence and technology produce an impact

The equation was developed in the 1970s during the course of a debate between Barry Commoner, Paul R. Ehrlich and John Holdren. Commoner argued that environmental impacts in the United States were caused primarily by changes in its production technology following World War II, while Ehrlich and Holdren argued that all three factors were important and emphasized in particular the role of human population growth.^[1]^[2]^[3]

The equation can aid in understanding some of the factors affecting human impacts on the environment,^[4] but it has also been cited as one of the primary factors underlying many of the dire environmental predictions of the 1970s by Paul Ehrlich, George Wald, Denis Hayes, Lester Brown, René Dubos, and Sidney Ripley that did not come to pass.^[5] Neal Koblitz classified equations of this type as "mathematical propaganda" and criticized Ehrlich's use of them in the media (e.g. on The Tonight Show) to sway the general public.^[6]

The Kaya identity is closely related to the I = PAT equation. The I = PAT equation is more general, describing an abstract "impact". The Kaya identity describes more clearly the impact of human activity on CO₂ emissions.

Population

Population (est.) 10,000 BC – 2000 AD.

In the I=PAT equation, the variable P represents the population of an area, such as the world. Since the rise of industrial societies, human population has been increasing exponentially. This has caused Thomas Malthus and many others to postulate that this growth would continue until checked by widespread hunger and famine (see Malthusian growth model).

The United Nations and the US Census Bureau project that world population will increase from 7.4 billion today in 2016 (up from 7.0 billion forecast in 2005) to about 9.7 billion by 2050 (up from 9.2 billion).^[7]^[8] These projections take into consideration that population growth has slowed in recent years as women are having fewer children. This phenomenon is the result of demographic transition all over the world. The UN projects that human population might stabilize around 11.2 billion by 2100 (up from 9.2 billion).^[1] However, since the world population is set to keep rising for the next few decades, this factor of the I=PAT equation will likely keep increasing human impact on the environment for the near future.

Environmental Impacts

Increased population increases humans' environmental impact in many ways, which include but are not limited to:

Increased land use - Results in habitat loss for other species.
Increased resource use - Results in changes in land cover
Increased pollution - Can cause sickness and damages ecosystems.

Affluence

Main article: Consumption (economics)

World GDP per capita (in 1990 Geary-Khamis dollars)

The variable A, in the I=PAT equation stands for affluence. It represents the average consumption of each person in the population. As the consumption of each person increases, the total environmental impact increases as well. A common proxy for measuring consumption is through GDP per capita. While GDP per capita measures production, it is often assumed that consumption increases when production increases. GDP per capita has been rising steadily over the last few centuries and is driving up human impact in the I=PAT equation.

Environmental Impacts

Increased consumption significantly increases human environmental impact. This is because each product consumed has wide ranging effects on the environment. For example, if the construction of a car had the following environmental impacts among others:

605,664 gallons of water for parts and tires^[9]
682 lbs. of pollution at a mine for the lead battery.^[9]
2178 lbs. of discharge into water supply for the 22 lbs. of copper contained in the car.^[9]

then the more cars per capita, the greater the impact. Since the ecological impacts of each product are far reaching, increases in consumption quickly result in large impacts on the environment.

Technology

The T variable in the I=PAT equation represents how resource intensive the production of affluence is; how much environmental impact is involved in creating, transporting and disposing of the goods, services and amenities used. Improvements in efficiency can reduce resource intensiveness, reducing the T multiplier. Since technology can affect environmental impact in many different ways, the unit for T is often tailored for the situation I=PAT is being applied to. For example, for a situation where the human impact on climate change is being measured, an appropriate unit for T might be greenhouse gas emissions per unit of GDP.

Environmental Impacts

Increases in efficiency can reduce overall environmental impact. However, since P has increased exponentially, and A has also increased drastically, the overall environmental impact, I, has still increased.

Reception

The I=PAT equation has been criticized for being too simplistic by assuming that P, A, and T are independent of each other. In reality, at least 7 interdependencies between P, A, and T could exist, indicating that it is more correct to rewrite the equation as I = f(P,A,T).^[10] For example, a doubling of technological efficiency, or equivalently a reduction of the T-factor by 50%, does not necessarily reduce the environmental impact (I) by 50% if efficiency induced price reductions stimulate additional consumption of the resource that was supposed to be conserved, a phenomenon called the rebound effect (conservation) or Jevons Paradox. As was shown by Alcott,^[10]^{:Fig. 5} despite significant improvements in the carbon intensity of GDP (i.e., the efficiency in carbon use) since 1980, world fossil energy consumption has increased in line with economic and population growth. Similarly, an extensive historical analysis of technological efficiency improvements has conclusively shown that energy and materials use efficiency improvements were almost always outpaced by economic growth, resulting in a net increase in resource use and associated pollution.^[11]^[12]

As a result of the interdependencies between P, A, and T and potential rebound effects, policies aimed at decreasing environmental impacts through reductions in P, A, and T may not only be very difficult to implement (i.e., population control and material sufficiency and degrowth movements have been very controversial) but also are likely to be rather ineffective compared to rationing (i.e., quotas) or Pigouvian taxation of resource use or pollution.^[10]

References

1 2 O'Neill, B.C.; MacKellar, F.L.; Lutz, W. (2004). "Population, greenhouse gas emissions, and climate change". In Lutz, W.; Sanderson, W.C.; Scherbov, S. The End of World Population Growth in the 21st Century: New Challenges for Human Capital Formation & Sustainable Development. London: Earthscan Press. pp. 283–314.
↑ Ehrlich, Paul R.; Holdren, John P. (1971). "Impact of Population Growth". Science. American Association for the Advancement of Science. 171 (3977): 1212–1217. doi:10.1126/science.171.3977.1212. JSTOR 1731166.
↑ Barry Commoner (May 1972). "A Bulletin Dialogue: on "The Closing Circle" - Response". Bulletin of the Atomic Scientists: 17–56.
↑ Chertow, M. R. (2000). "The IPAT Equation and Its Variants". Journal of Industrial Ecology. 4 (4): 13–29. doi:10.1162/10881980052541927.
↑ R Bailey (2000) Earth day then and now, Reason 32(1), 18-28
↑ N Koblitz (1981) "Mathematics as Propaganda", in Mathematics Tomorrow, ed. Lynn Steen, pp 111-120.
↑ US Census Bureau international popopulation statistics and projections 1950 to 2050
↑ United Nations population projections
1 2 3 Andriantiatsaholiniaina, L. A.; Kouikoglou, V. S.; Phillis, Y. A. (2004). "Evaluating strategies for sustainable development: Fuzzy logic reasoning and sensitivity analysis". Ecological Economics. 48 (2): 149. doi:10.1016/j.ecolecon.2003.08.009.
1 2 3 Alcott, B. (2010). "Impact caps: Why population, affluence and technology strategies should be abandoned". Journal of Cleaner Production. 18 (6): 552–560. doi:10.1016/j.jclepro.2009.08.001.
↑ Huesemann, Michael H., and Joyce A. Huesemann (2011). Technofix: Why Technology Won’t Save Us or the Environment, Chapter 5, "In Search of Solutions II: Efficiency Improvements", New Society Publishers, Gabriola Island, British Columbia, Canada, ISBN 0865717044, 464 pp.
↑ Cleveland, C. J.; Ruth, M. (1998). "Indicators of Dematerialization and the Materials Intensity of Use". Journal of Industrial Ecology. 2 (3): 15. doi:10.1162/jiec.1998.2.3.15. ≥

Human/World population

Major topics	Biocapacity Optimum population Overpopulation Malthusian catastrophe Population Population ethics Population momentum Sustainable development Women's reproductive rights Zero population growth

Biological and related topics	Family planning Pledge two or fewer Human population control One-child policy Two-child policy Population biology Population decline Population density Physiological density Population dynamics Population growth Population model Population pyramid Projections of population growth

Human impact on the environment	Deforestation Desalination Desertification Environmental impact of agriculture of aviation of biodiesel of concrete of electricity generation of the energy industry of fishing of irrigation of mining of off-roading of oil shale industry of palm oil of paper of the petroleum industry of reservoirs of shipping of war Industrialisation Land degradation Land reclamation Overconsumption Pollution Quarrying Urbanization Loss of green belts Urban sprawl Waste Water scarcity Overdrafting

Population ecology	Carrying capacity Deep ecology Earth's energy budget Food security Habitat destruction I = P × A × T Malthusian growth model Overshoot (population) World energy consumption World energy resources World3 model

Literature	A Modest Proposal Observations Concerning the Increase of Mankind, Peopling of Countries, etc. An Essay on the Principle of Population "How Much Land Does a Man Need?" Operating Manual for Spaceship Earth Population Control: Real Costs, Illusory Benefits The Limits to Growth The Population Bomb The Skeptical Environmentalist The Ultimate Resource

Publications	Population and Environment Population and Development Review

Lists	Population and housing censuses by country Metropolitan areas by population Population milestone babies

Events and organizations	7 Billion Actions International Conference on Population and Development Population Action International Population Connection Population Matters Population Research Institute United Nations Population Fund Voluntary Human Extinction Movement World Population Day World Population Foundation

Related topics	Classic Maya collapse Fertility and intelligence Green Revolution Holocene extinction Migration

Commons Human overpopulation Environmental issues with population Human migration

Sustainability

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Consumption	Anthropization Anti-consumerism Ecological footprint Ethical Over-consumption Simple living Sustainability advertising Sustainability brand Sustainability marketing myopia Sustainable Systemic change resistance Tragedy of the commons

Population	Birth control Family planning Control Overpopulation Zero growth

Technology	Appropriate Environmental Sustainable

Biodiversity	Biosecurity Biosphere Conservation biology Deep ecology Endangered species Holocene extinction Invasive species

Energy	Carbon footprint Climate change mitigation Conservation Descent Efficiency Emissions trading Fossil-fuel phase-out Peak oil Renewable Energy poverty

Food	Forest gardening Local Permaculture Security Sustainable agriculture Sustainable fishery Urban horticulture

Water	Conservation Crisis Efficiency Footprint

Accountability	Sustainability accounting Sustainability measurement Sustainability metrics and indices Sustainability reporting Standards and certification Sustainable yield

Applications	Advertising Architecture Art Business City College programs Community Design Ecovillage Education for Sustainable Development Fashion Gardening Geopark Green marketing Industries Landscape architecture Living Low-impact development Sustainable market Organizations Packaging Practices Procurement Tourism Transport Urban drainage systems Urban infrastructure Urbanism

Management	Environmental Fisheries Forest Materials Natural resource Planetary Waste

Agreements	UN Conference on the Human Environment (Stockholm 1972) Brundtlandt Commission Report (1983) Our Common Future (1987) Earth Summit (1992) Rio Declaration on Environment and Development Agenda 21 (1992) Convention on Biological Diversity (1992) ICPD Programme of Action (1994) Earth Charter Lisbon Principles UN Millennium Declaration (2000) Earth Summit 2002 (Rio+10, Johannesburg) United Nations Conference on Sustainable Development (Rio+20, 2012) Sustainable Development Goals

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I = PAT

Population

Environmental Impacts

Affluence

Environmental Impacts

Technology

Environmental Impacts

Reception

See also

References