Electronic properties of 2D and 1D systems: Difference between revisions
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File:Graphen.jpg| Graphene sheet: Picture by AlexanderAlUS] | File:Graphen.jpg| Graphene sheet: Picture by AlexanderAlUS] | ||
File:cnt.png| Carbon | File:cnt.png| Rolling graphene sheets: Carbon Nanotubes | ||
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Revision as of 09:33, 1 April 2021
Prev:LabQSM#Module 3: Low dimensional structures (6h)
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![Graphene sheet: Picture by AlexanderAlUS]](/images/9/9e/Graphen.jpg)
Graphene sheet: Picture by AlexanderAlUS] -
Rolling graphene sheets: Carbon Nanotubes
![Graphene sheet: Picture by AlexanderAlUS]](/index.php?title=File:Graphen.jpg)
Input set-up for a low dimensional system:
Now we want to deal with systems of reduced dimensionality, e.g. periodic in one or two dimension but isolated in the other directions. This is accomplished by:
- Isolating the system in the non-periodic dimension as seen in Electronic properties of isolated molecules, so inserting an amount of vacuum in the supercell.
- Sampling the Brillouin zone that now has reduced dimension:
In Quantum ESPRESSO one needs to set the following:
K_POINTS automatic nk nk 1 0 0 0
this will generate a 2D sampling. In brief: you will need large supercells because of the present of vacuum which reflects in a large number of plane waves and a converged sampling of the BZ. The combination of this two issues makes the calculations of 2D system rather cumbersome.
Exercises:
Exercise 1:
- build a supercell for am ideal graphene structure
- relax the supercell
- calculate the graphene band structure
- calculate the density of states projected on π and σ states