Difference between revisions of "Quasiparticle"
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Due to [[gem-gum technology]] allowing for precise and repeatable structuring of matter at the atomic scale <br> | Due to [[gem-gum technology]] allowing for precise and repeatable structuring of matter at the atomic scale <br> | ||
designing structures specifically for exploring the properties and possible application areas of quasi-particles <br> | designing structures specifically for exploring the properties and possible application areas of quasi-particles <br> | ||
Revision as of 16:21, 13 August 2023
(wiki-TODO: duplicate page - fuse with zoo of quasiparticles)
Due to gem-gum technology allowing for precise and repeatable structuring of matter at the atomic scale
designing structures specifically for exploring the properties and possible application areas of quasi-particles
becomes experimentally very accessible.
Quasi particles seem to be a largely untapped treasure trove of possible applications.
Many quasi-particles may only be able to support low power densities and thus
be "only" suitable for sensing and computing applications (quasiparticles involving nuclear spins come to mind),
while others (including phonons) will also be usable in high power applications.
Especially interesting ones:
Some less known ones:
- Polaron
- Spinon
- Magnon
Related
- Quantum mechanics
- Non mechanical technology path
- Slightly off-topic: Electrons as anions in a crystal
- Optical particle accelerators
External links
Wikipedia
- Quasipartilce
- List of quasiparticles
- Fracton – fractal analog to a phonon ???
- (Roton – elementary excitation in superfluid helium-4)
- Cooper pair
Whole classes of quasi-particles:
- Anyon
- Majorana fermion
- Fracton (subdimensional particle) ?
- Soliton waves – example: Nematicon
