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Revision as of 13:59, 24 October 2007 by 81.241.167.60 (talk) (→Non-zero-emission future technologies)(diff) ← Previous revision | Latest revision (diff) | Newer revision → (diff)Zero emission refers to an engine, motor, or other energy source, that emits no waste products that pollutes the environment or disrupts the climate.
Zero emission engines
Vehicles and other mobile machinery used for transport (over land, sea, air, rail) and for other uses (agricultural, mobile power generation, ...) contribute heavily to global warming/pollution, and thus zero emission engines are being actively researched. These technologies almost in all cases include an electric engine powered by an additional energy source compact enough to be installed in the vehicle. These energy sources vary from hydrogen fuel cells, batteries, Flywheel energy storage devices, ...
In some cases, (e.g. compressed air engines), the engine may also be mechanical. This mechanical engine is then powered by an additional, passive energy source as compressed air, or a combustible non-polluting gas (e.g. hydrogen).
As the above engines can be used in all vehicles, everything can altered; from cars to boats as well as propeller airplanes. For boats besides the above engines mentioned (and traditional means as sails & turbosails) , nuclear power plants and technology used commonly to power homes/industry can be used as well (e.g. PV solar panels).
Zero emission energy production
Current technology for power plants
Renewable energy sources, including solar power, wind power, tidal power and hydroelectric power. are often referred to as zero emission power, since their operation produce very few, or zero, emissions. On the other hand, the construction of such plants may involve emissions if the materials are created or assembled using equipment that produces emissions. For example, the production of high purity silicon for photovoltaic cells consumes large quantities of carbon, contributing to CO2 emissions, and this is also true for the production of steel and concrete for wind turbines and hydroelectric dams.
Similarly, Nuclear power plants do not emit significant amounts of pollutants during their operation, but the extraction of Uranium ore and construction of waste repositories usually involves machinery powered by gasoline. The construction of the plant itself also requires materials similar to those for renewable energy sources, tho because of nuclear powerplants large output per station, less so per amount of energy produced. All in all, emissions due to the operation, fuel production and waste management from nuclear powerplants are similar in magnitude to those of the renewables. However, though nuclear powerplants do not emit large amounts of pollution during normal operation, they do produce large quantities of radioactive waste, which has to be stored for several centuries before it's radioactivity has decreased to that of the uranium ore ( see Nuclear waste ). There is also concern that flawed designs or operation can lead to nuclear accidents, emitting radioactive pollutants, as happened during the Chernobyl disaster.
Potential future technologies
Many technological improvements have been suggested to reduce emissions from various energy sources. Carbon dioxide could be captured from fossil plants and stored underground rather than released into the atmosphere ( a technology known as carbon capture and storage ). Improved efficiency for solar cells, or cells made from novel materials, could offset the emissions associated with silicon production. New reactor technology could enable nuclear reactors to produce orders of magnitude more energy without increased emissions, and recycled or new materials could reduce the emissions associated with construction of windturbines and hydroelectric dams.
Besides commonly accepted future technologies as fast breeder reactors, less accepted technologies may in the future also be used for large scale energy production. These less accepted technologies inlclude cold fusion power plants, Randell Mills' hydrino power plants, Kenarev power plants, etc. A complete list of these potentially viable technologies can be found here
Non-zero-emission future technologies
To complement todays current zero-emission technology, many new energy sources with low emissions are being researched, including among others: Wave power, Nuclear fusion and Bio fuel. These non-zero-emission technologies, despite still emitting some degree of pollution are used to bridge the gap between the really polluting technology (coal, fossil oil, ...) and the zero-emission technology. The reason why these technologies are used is often because they are in some cases cheaper or because they can be integrated faster (less machinery to alter).
A concept like vegetable oil economy produces emissions; however, the only emissions are things that were first taken out of the atmosphere when the plants were growing. So there is no net emission.
See also
References
- Dixon, Lloyd (2002). Driving Emissions to Zero: Are the Benefits of California's Zero Emission Vehicle Program Worth the Costs?. RAND Corporation. ISBN 0-8330-3212-7.
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External Links
- A special issue of the Journal of Cleaner Production that focuses specifically on Zero Emissions
- Description of what 'zero emission' means