Archive:000/Conventional nuclear power: Difference between revisions
No edit summary |
m (Elie moved page Conventional nuclear power to Archive:000/Conventional nuclear power without leaving a redirect: Huge_refactor) |
||
| (4 intermediate revisions by the same user not shown) | |||
| Line 3: | Line 3: | ||
[[Category:Energy sources]] | [[Category:Energy sources]] | ||
Currently, all of the world's nuclear power plants{{x|any exceptions are ''experimental'' and not | Currently, all of the world's nuclear power plants{{x|any exceptions are ''experimental'' and not scalable yet (as of 2024)}} run on '''conventional nuclear power''': [[nuclear fission]] that depends heavily on uranium-235. | ||
{{considerations}} __NOTOC__ | {{considerations}} __NOTOC__ | ||
==Scarcity of uranium-235== | ==Scarcity of uranium-235== | ||
{{basically|Major | {{basically|Major limitation|bad}} | ||
[[File:Shinarump Mine Waste Rock.jpg|thumb|Uranium occurs naturally as a mix of two isotopes: uranium-235 (0.7%) and uranium-238 (99.3%).]] | [[File:Shinarump Mine Waste Rock.jpg|thumb|Uranium occurs naturally as a mix of two isotopes: uranium-235 '''(0.7%)''' and uranium-238 '''(99.3%)'''.]] | ||
{{dp | {{dp | ||
| Line 42: | Line 42: | ||
}} | }} | ||
This is the main reason why nuclear power only provides a '''small fraction''' of the world's [[energy]].<!-- TODO: add pie chart --> Uranium-235 is a scarce mineral - far more scarce than [[fossil fuels]]. | '''This''' is the main reason why nuclear power only provides a '''small fraction''' of the world's [[energy]].<!-- TODO: add pie chart --> Uranium-235 is a scarce mineral - far more scarce than [[fossil fuels]]. | ||
If all the world's energy were to come from nuclear, we'd '''run out''' of uranium-235 in about '''4 years.''' | If all the world's energy were to come from nuclear, we'd '''run out''' of uranium-235 in about '''4 years.''' | ||
{{p2|(see maths)|{{calc|uranium.reserves * nuclear_power_plant.efficiency|years energy.tfc|||}} }} | {{p2|(see maths)|{{calc|uranium.reserves * nuclear_power_plant.efficiency|years energy.tfc|||}} }} | ||
{{p2|(more)|~ We'd run out even faster [[energy demand scenarios|if all nations were developed]].<br /><br />~ In either case, conventional nuclear power can't really meet global energy demands. Best case, it might be sufficient for [[baseload]] electricity only (which is a smaller part of total [[energy demand]]).}} | {{p2|(more)|~ We'd run out even faster [[energy demand scenarios|if all nations were developed]].<br /><br />~ In either case, conventional nuclear power can't really meet global energy demands. Best case, it might be sufficient for [[baseload]] electricity only (which is a smaller part of total [[energy demand]]).}} | ||
<!-- TALK: There's another way this can be calculated: comparing 'uranium primary energy' vs 'fossil fuel primary energy'. Both calculations produce about the same result. It might be worth refactoring this page to include both, if it can be done in a way that doesn't make things seem more complicated for the reader. --> | |||
'''Possible solutions:''' | '''Possible solutions:''' | ||
* [[Breeder reactors]], to make use of uranium-238, which is over 100 times more abundant. | * [[Breeder reactors]], to make use of uranium-238, which is over 100 times more abundant. | ||
'''FAQ:''' <small> | |||
* "What about obtaining uranium from seawater? I heard that's more abundant?" | |||
** The amount of energy required to extract [[uranium from seawater]] is high. The only way to [[EROI|get back more energy than we put in]] is if we use the uranium-238 part of it. Conventional nuclear power does not. | |||
</small> | |||
==Nuclear waste== | ==Nuclear waste== | ||
| Line 68: | Line 73: | ||
==Risk of meltdowns== | ==Risk of meltdowns== | ||
{{basically|Generally manageable}} | {{basically|Generally manageable}} | ||
{{ | Meltdowns have happened twice in history: [[Chernobyl]] and [[Fukushima]]. Nuclear plants have since been designed to not repeat the mistakes of the past. {{en}} Then again, some people say there are still unknown risks. <sup>[discussion needed]</sup> | ||
<!-- TODO: {{qn}}: put in perspective the number of lives lost and the amount of land lost, relative to the amount of energy generated (throughout all of history). Compare to fossil fuels etc. --> | |||
==Weapons proliferation== | ==Weapons proliferation== | ||
{{basically|Under control}} | {{basically|Under control}} | ||
Reactors are well designed to prevent people from stealing uranium to make thermonuclear bombs. Governments of course still have nuclear warheads, which is still a [[nuclear war|major issue in itself]]. | |||
Latest revision as of 16:29, 26 October 2024
Currently, all of the world's nuclear power plants
Scarcity of uranium-235
Major limitation
uranium.reserves
8.070 million tonnes uranium_natural
Global uranium mineral reserves, measured in energy units
The calculator understands "tonnes uranium_natural" as an energy unit. It's based on the fact that natural uranium is just 0.7% uranium-235 (the isotope we extract energy from). The rest is uranium-238, which isn't useful for energy unless we use breeder reactors.
Citation:
Uranium 2020: Resources, Production and Demand ('Red Book')
"The total recoverable identified resources to $260/kg U is 8.070 million tonnes U."
Citation:
Uranium 2020: Resources, Production and Demand ('Red Book')
"The total recoverable identified resources to $260/kg U is 8.070 million tonnes U."
nuclear_power_plant.efficiency
33%
Electrical output divided by the heat energy of the nuclear reactor
Nuclear power plants convert heat (from uranium-235, currently) into electricity. The process is approximately 33% efficient.
Citation: Key World Energy Statistics 2020 (IEA report) - Page 73 - Glossary - Nuclear
Citation: Key World Energy Statistics 2020 (IEA report) - Page 73 - Glossary - Nuclear
energy.tfc
9937.70 Mtoe/year
Global energy usage - total final consumption (TFC)
Includes: fuel (80.7%) + electricity (19.3%) AFTER it is generated.
Does not include the fuel used in generating electricity. See [energy.tes] for that.
Citation: "Key World Energy Statistics 2020" IEA
- Page 47 - Simplified energy balance table - World energy balance, 2018
Does not include the fuel used in generating electricity. See [energy.tes] for that.
Citation: "Key World Energy Statistics 2020" IEA
- Page 47 - Simplified energy balance table - World energy balance, 2018
This is the main reason why nuclear power only provides a small fraction of the world's energy. Uranium-235 is a scarce mineral - far more scarce than fossil fuels.
If all the world's energy were to come from nuclear, we'd run out of uranium-235 in about 4 years.
(see maths)
(calculation loading)
(more)~ We'd run out even faster if all nations were developed.
~ In either case, conventional nuclear power can't really meet global energy demands. Best case, it might be sufficient for baseload electricity only (which is a smaller part of total energy demand).
Possible solutions:
- Breeder reactors, to make use of uranium-238, which is over 100 times more abundant.
FAQ:
- "What about obtaining uranium from seawater? I heard that's more abundant?"
- The amount of energy required to extract uranium from seawater is high. The only way to get back more energy than we put in is if we use the uranium-238 part of it. Conventional nuclear power does not.
Nuclear waste
Long-term problem
Since the reactors only make use of the uranium-235 component, the remaining matter becomes "spent fuel" and must be disposed of. This nuclear waste is still radioactive enough to cause harm to anyone exposed to it without protective equipment. It remains this way for millions of years.
Possible solutions:
- Breeder reactors, which could keep obtaining energy from the spent fuel (mostly uranium-238) until there's barely any radioactive waste left at all.
Risk of meltdowns
Generally manageable
Meltdowns have happened twice in history: Chernobyl and Fukushima. Nuclear plants have since been designed to not repeat the mistakes of the past. [ELABORATION needed] Then again, some people say there are still unknown risks. [discussion needed]
Weapons proliferation
Under control
Reactors are well designed to prevent people from stealing uranium to make thermonuclear bombs. Governments of course still have nuclear warheads, which is still a major issue in itself.