Energy conversion: Difference between revisions
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major improvements - differentiation in scale |
added energystorage and energydevaluation pro points |
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{{template:site specific definition}} | {{template:site specific definition}} | ||
Atomically precise technology for energy conversion can: | |||
* solve the enegry storage problem making renewable energy storable and fossile or nuclear fission baseload power plants unnecessary | |||
* circumvent burning processes that unnecessarily devaluates energy | |||
== Nanoscale: molecular power converters == | == Nanoscale: molecular power converters == | ||
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* [[chemomechanical converters]] | * [[chemomechanical converters]] | ||
* [[electromechanical converters]] | * [[electromechanical converters]] - the link for massive and efficient energy storage that is missing today | ||
* [[entropomechanical converters]] | * [[entropomechanical converters]] | ||
* [[Diamondoid solar cell|optoelectric / solarelectric]] | * [[Diamondoid solar cell|optoelectric / solarelectric]] | ||
Revision as of 09:21, 25 May 2015
Atomically precise technology for energy conversion can:
- solve the enegry storage problem making renewable energy storable and fossile or nuclear fission baseload power plants unnecessary
- circumvent burning processes that unnecessarily devaluates energy
Nanoscale: molecular power converters
AP technology provides several possibilities for energy conversion that work in a mill/zip/conveyor belt like style:
- chemomechanical converters
- electromechanical converters - the link for massive and efficient energy storage that is missing today
- entropomechanical converters
- optoelectric / solarelectric
Mesoscale
- thermomechanical: diamondoid heat pump system
Makroscale
- thermonuclear (indirectly)