Thermodynamic limitations to nuclear energy deployment as a greenhouse gas mitigation technology

Joshua M. Pearce
International Journal of Nuclear Governance, Economy and Ecology 2008 - Vol. 2, No.1 pp. 113 - 130
Abstract:
To both replace fossil-fuel-energy use and meet the future energy demands, nuclear energy production would have to increase by 10.5% per year from 2010 to 2050. This large growth rate creates a cannibalistic effect, where nuclear energy must be used to supply the energy for future nuclear power plants. This study showed that the limit of ore grade to offset greenhouse gas emissions is significantly higher than the purely thermodynamic limit set by energy payback times found in the literature. In addition, any use of nuclear energy directly contributes heat to the Earth, which the Earth must radiate into space by raising its temperature to maintain thermodynamic equilibrium. This is a relatively small effect, but as energy consumption grows it must be considered for a world powered by nuclear energy. The results of this study demand modesty in claims of 'emission-free nuclear energy' as a panacea for global climate destabilisation.

http://www.inderscience.com/search/index.php?action=record&rec_id=17358

Nuclear energy production must increase by more than 10 percent each year from 2010 to 2050 to meet all future energy demands and replace fossil fuels, but this is an unsustainable prospect. According to a report published in Inderscience's International Journal of Nuclear Governance, Economy and Ecology such a large growth rate will require a major improvement in nuclear power efficiency otherwise each new power plant will simply cannibalize the energy produced by earlier nuclear power plants.

Physicist Joshua Pearce of Clarion University of Pennsylvania has attempted to balance the nuclear books and finds the bottom line simply does not add up. There are several problems that he says cannot be overcome if the nuclear power option is taken in preference to renewable energy sources.

For example, the energy input required from mining and processing uranium ore to its use in a power plant that costs huge amounts of energy to build and operate cannot be offset by power production in a high growth scenario. There are also growth limits set by the grade of uranium ore. "The limit of uranium ore grade to offset greenhouse gas emissions is significantly higher than the purely thermodynamic limit set by the energy payback time," he explains.

http://www.eurekalert.org/pub_releases/2008-03/ip-nc030408.php

It's been working really well for me.

If you're looking for something specific, it takes some imaginative boolean operators to narrow the results.

The supply of uranium in seawater is infinite!!11

A fifth-grade dropout told me so...

:rofl: