Difference between revisions of "Diamondoid solar cell"
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== Related == | == Related == | ||
| + | * '''[[Ligand field theory]]''' | ||
* '''[[Mechanooptical conversion]]''' | * '''[[Mechanooptical conversion]]''' | ||
* rectenna [https://de.wikipedia.org/wiki/Rectenna (leave to wikipedia)] for optical wavelengths with nanotube diodes that are able to switch fast enough [[non mechanical technology path]] | * rectenna [https://de.wikipedia.org/wiki/Rectenna (leave to wikipedia)] for optical wavelengths with nanotube diodes that are able to switch fast enough [[non mechanical technology path]] | ||
* radiation protection | * radiation protection | ||
* photonic crystals | * photonic crystals | ||
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Revision as of 11:58, 22 September 2022
How does one construct a solar cell material with just carbon or some abundant elements (N,O,P,S,(Fe??),..) too?
Bent graphene can be a tunable semiconductor as was found with nanotubes.
A direct conversion into mechanical energy might be to consider.
[Todo: how much research exists - what is missing?]
Diamond seems to be an excellent material for solar cells.
Article: Turning diamond film into solar cells
[Todo: better references needed]
Related
- Ligand field theory
- Mechanooptical conversion
- rectenna (leave to wikipedia) for optical wavelengths with nanotube diodes that are able to switch fast enough non mechanical technology path
- radiation protection
- photonic crystals
