Mark Z. Jacobson

Mark Z. Jacobson

Mark Z. Jacobson is professor of civil and environmental engineering at Stanford University and director of the Atmosphere and Energy Program there.[1] Jacobson develops computer models about the effects of different energy technologies and their emissions on air pollution and climate.[2]

Jacobson says that wind, water and solar power can be scaled up in cost-effective ways to meet our energy demands, freeing us from dependence on both fossil fuels and nuclear power. In 2009 Jacobson and Mark A. Delucchi published “A Plan to Power 100 Percent of the Planet With Renewables” in Scientific American. The article addressed a number of issues, such as the worldwide spatial footprint of wind turbines, the availability of scarce materials needed for manufacture of new systems, the ability to produce reliable energy on demand and the average cost per kilowatt hour. A more detailed and updated technical analysis has been published as a two-part article in the journal Energy Policy.[3]

Contents

Research

Using computer modeling he developed over 20 years, Jacobson has found that soot emissions (which lead to respiratory illness, heart disease and asthma) have resulted in 1.5 million premature deaths each year, mostly in the developing world where wood and animal dung are used for cooking. Jacobson has also said that soot from diesel engines, coal-fired power plants and burning wood is a "bigger cause of global warming than previously thought, and is the major cause of the rapid melting of the Arctic's sea ice".[1]

Jacobson states that if the United States wants to reduce global warming, air pollution and energy instability, it should invest only in the best energy options, and that nuclear power is not one of them.[4] Jacobson's analyses show that "nuclear power results in up to 25 times more carbon emissions than wind energy, when reactor construction, uranium refining and transport are considered".[2]

His work also shows that "carbon capture and sequestration technology can reduce carbon dioxide emissions from coal-fired power plants but will increase air pollutants and will extend all the other deleterious effects of coal mining, transport and processing, because more coal must be burned to power the capture and storage steps".[2]

Jacobson has studied how wind, water and solar technologies can provide 100 per cent of the world's energy, eliminating all fossil fuels.[5] He advocates a "smart mix" of renewable energy sources to reliably meet electricity demand:

Because the wind blows during stormy conditions when the sun does not shine and the sun often shines on calm days with little wind, combining wind and solar can go a long way toward meeting demand, especially when geothermal provides a steady base and hydroelectric can be called on to fill in the gaps.[2]

In 2010, the journal Energy Policy published two papers by Jacobson and Mark A. Delucchi about "Providing all global energy with wind, water, and solar power". The articles analyze the feasibility of providing worldwide energy for all purposes (electric power, transportation, heating/cooling, etc.) from wind, water, and sunlight (WWS). In Part I, Jacobson and Delucchi discuss WWS energy system characteristics, current and future energy demand, availability of WWS resources, numbers of WWS devices, and area and material requirements.[6] They estimate that 3,800,000 5 MW wind turbines, 49,000 300 MW concentrated solar plants, 40,000 300 MW solar PV power plants, 1.7 billion 3 kW rooftop PV systems, 5350 100 MW geothermal power plants, and 270 new 1300 MW hydroelectric power plants will be needed. Such a WWS infrastructure reduces world power demand by 30% and requires only 0.41% and 0.59% more of the world's land for footprint and spacing, respectively.[6]

In Part II, Jacobson and Delucchi address variability, economics, and policy of WWS energy Jacobson and Delucchi suggest producing all new energy with WWS by 2030 and replacing the pre-existing energy by 2050. Barriers to the plan are primarily social and political, not technological or economic. The energy cost in a WWS world should be similar to today's costs.[6]

Education

  • M.S. (1991) and Ph.D. (1994) Atmospheric Science, University of California at Los Angeles.[7]

See also

References

External links


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