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Calculation of intersubband plasmons in doped carbon nanotubes.

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.gitignore
 
 
Makefile
Makefile
 
 
README.md
README.md
 
 
cntabsorpt.f90
cntabsorpt.f90
 
 
code_snippets.txt
code_snippets.txt
 
 
fitting_e_d.png
fitting_e_d.png
 
 
globvar.f90
globvar.f90
 
 
libDrudeOpt.f90
libDrudeOpt.f90
 
 
libMath.f90
libMath.f90
 
 
libswntElec.f90
libswntElec.f90
 
 
libswntOpt.f90
libswntOpt.f90
 
 
libswntSTB.f90
libswntSTB.f90
 
 
swnt.param.current
swnt.param.current
 
 
swntpar.f90
swntpar.f90
 
 
swntstruct.f90
swntstruct.f90
 
 
tube.param.105
tube.param.105
 
 

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cntabsorpt

Calculation of intersubband plasmons in doped carbon nanotubes.

We theoretically investigate intersubband plasmon excitations in doped single wall carbon nanotubes (SWNTs) by examining the dependence of plasmon frequency on the nanotube diameter, chirality, and Fermi energy. The intersubband plasmons can be excited by light with polarization perpendicular to the nanotube axis and thus the plasmon excitations corresponds to optical transitions between the two different subbands, which are sensitive to the Fermi energy. In every SWNT, this mechanism leads to the emergence of the optical absorption peak at the plasmon frequency for a given Fermi energy, E_F. The plasmon frequencies calculated for many SWNTs with diameter d < 2 nm exhibit a dependence on (1/d)^(-0.7) and the frequencies are further affected by Fermi energy as E_F^0.25. With this knowledge, it is possible to develop a map of intersubband plasmon excitations in doped SWNTs that could be useful to quickly estimate the doping level and also be an alternative way to characterize nanotube chirality.

If you use this code for your research, please, cite this: https://arxiv.org/abs/1811.11451

In this code you can calculate:

  1. Energy bands for any chirality (n,m) if tube diameter is smaller than 2 nm.
  2. Complex dielectric permittivity function.
  3. Optical absorption (interband and intraband).
  4. DOS and joint DOS

The main input of the program is tube.param.** file, where ** stands for n amd m numbers.
The structure of the input file is the following:

300.0-----------------------Temperature
10 5------------------------n m
100-------------------------number of k points
0.0-------------------------doping (n-p) per length (1/A)
0.0-------------------------Fermi level (eV)
1.3-------------------------refractive index
1.0-------------------------background dielectric permittivity
501-------------------------number of laser photon energies
0.0 4.0---------------------Laser photon energy range (eV)
0.05------------------------Laser linewidth (eV)
501 -0.7 0.7----------------number of electron DOS energies, electron DOS energy range (eV)
0.0-------------------------polarization angle

For any further questions do not hesitate to contact me: dasha.shatco@gmail.com

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Calculation of intersubband plasmons in doped carbon nanotubes.

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tight-binding spectroscopy carbon-nanotubes absorption plasmon

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