CZ:Featured article/Current: Difference between revisions

Latest revision as of 10:19, 11 September 2020

After decades of failure to slow the rising global consumption of coal, oil and gas,^[1] many countries have proceeded as of 2024 to reconsider nuclear power in order to lower the demand for fossil fuels.^[2] Wind and solar power alone, without large-scale storage for these intermittent sources, are unlikely to meet the world's needs for reliable energy.^[3]^[4]^[5] See Figures 1 and 2 on the magnitude of the world energy challenge.

Nuclear power plants that use nuclear reactors to create electricity could provide the abundant, zero-carbon, dispatchable^[6] energy needed for a low-carbon future, but not by simply building more of what we already have. New innovative designs for nuclear reactors are needed to avoid the problems of the past.

(CC) Image: Geoff Russell
Fig.1 Electricity consumption may soon double, mostly from coal-fired power plants in the developing world.^[7]

Issues Confronting the Nuclear Industry

New reactor designers have sought to address issues that have prevented the acceptance of nuclear power, including safety, waste management, weapons proliferation, and cost. This article will summarize the questions that have been raised and the criteria that have been established for evaluating these designs. Answers to these questions will be provided by the designers of these reactors in the articles on their designs. Further debate will be provided in the Discussion and the Debate Guide pages of those articles.

Footnotes

↑ Global Energy Growth by Our World In Data
↑ Public figures who have reconsidered their stance on nuclear power are listed on the External Links tab of this article.
↑ Pumped storage is currently the most economical way to store electricity, but it requires a large reservoir on a nearby hill or in an abandoned mine. Li-ion battery systems at $500 per KWh are not practical for utility-scale storage. See Energy Storage for a summary of other alternatives.
↑ Utilities that include wind and solar power in their grid must have non-intermittent generating capacity (typically fossil fuels) to handle maximum demand for several days. They can save on fuel, but the cost of the plant is the same with or without intermittent sources.
↑ Mark Jacobson believes that long-distance transmission lines can provide an alternative to costly storage. See the bibliography for more on this proposal and the critique by Christopher Clack.
↑ "Load following" is the term used by utilities, and is important when there is a lot of wind and solar on the grid. Some reactors are not able to do this.
↑ Fig.1.3 in Devanney "Why Nuclear Power has been a Flop"

[GlobalEnergyGrowth-1] Global Energy Growth by Our World In Data

[PublicFigures-2] Public figures who have reconsidered their stance on nuclear power are listed on the External Links tab of this article.

[StoringPower1-3] Pumped storage is currently the most economical way to store electricity, but it requires a large reservoir on a nearby hill or in an abandoned mine. Li-ion battery systems at $500 per KWh are not practical for utility-scale storage. See Energy Storage for a summary of other alternatives.

[StoringPower2-4] Utilities that include wind and solar power in their grid must have non-intermittent generating capacity (typically fossil fuels) to handle maximum demand for several days. They can save on fuel, but the cost of the plant is the same with or without intermittent sources.

[StoringPower3-5] Mark Jacobson believes that long-distance transmission lines can provide an alternative to costly storage. See the bibliography for more on this proposal and the critique by Christopher Clack.

[LoadFollowing-6] "Load following" is the term used by utilities, and is important when there is a lot of wind and solar on the grid. Some reactors are not able to do this.

[GordianKnotFig1.3-7] Fig.1.3 in Devanney "Why Nuclear Power has been a Flop"

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-== '''[[Accidental release source terms]]''' ==
+{{:{{FeaturedArticleTitle}}}}
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+<small>
-'''Accidental release source terms''' are the mathematical equations that quantify the flow rate at which accidental releases of air  [[pollutant]]s into the ambient [[Natural environment|environment]] can occur at industrial facilities such as [[Petroleum refining processes|petroleum refineries]], [[petrochemical]] plants, [[natural gas processing]] plants, oil and [[gas]] transportation [[Pipeline transport|pipelines]], [[chemical plant]]s, and many other industrial activities. Governmental regulations in a good many countries require that the probability of such accidental releases be analyzed and their quantitative impact upon the environment and human health be determined so that mitigating steps can be planned and implemented.
+==Footnotes==
-There are a number of mathematical calculation methods for determining the flow rate at which gaseous and liquid pollutants might be released from various types of accidents. Such calculational methods are referred to as ''source terms'', and this article on accidental release source terms explains some of the calculation methods used for determining the mass flow rate at which gaseous pollutants may be accidentally released. Given those mass flow rates, [[atmospheric dispersion modeling]] studies can then be performed.
-''[[Accidental release source terms|.... (read more)]]''
-{| class="wikitable collapsible collapsed" style="width: 90%; float: center; margin: 0.5em 1em 0.8em 0px;"
-|-
-! style="text-align: center;" | &nbsp;[[Accidental release source terms#References|notes]]
-|-
-|
 {{reflist|2}}
-|}
+</small>

CZ:Featured article/Current: Difference between revisions

Latest revision as of 10:19, 11 September 2020

Issues Confronting the Nuclear Industry

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