How to treat low dimensional systems: Difference between revisions

From The Yambo Project
Jump to navigation Jump to search
(Created page with "In this tutorial you will learn (for a 2D material) how to: * generate a coulomb potential with a box-like cutoff * visualize this coulomb potential * use this cutoff in the...")
 
Line 13: Line 13:


== Generate the cutoff databse (yambo -r) ==
== Generate the cutoff databse (yambo -r) ==
To simulate a real isolated 2D-material a convergence with vacuum size is in principle required.
but the use of a truncated Coulomb potential allows to achieve faster convergence  eliminating the interaction between the repeated  images.
(see ref. Varsano)
For a 2D system a box-like cutoff in the direction perperdicular to the sheet (in this case z) is applied.
The used box size  L_z = a_z (cell size in bohr) - 1 bohr = 32 bohr
Create the input file:
$ yambo -F 01_cut2D.in  -r
Open the input file 01_cut2D.in
Change the variables inside as:
RandQpts= 1000000          # [RIM] Number of random q-points in the BZ
RandGvec= 100        RL    # [RIM] Coulomb interaction RS components
CUTGeo= "box z"            # [CUT] Coulomb Cutoff geometry: box/cylinder/sphere X/Y/Z/XY..
% CUTBox
  0.00    | 0.00    | 32.0    |        # [CUT] [au] Box sides
Close the input file and run yambo
$ yambo -F 01_cut2D.in  -J 2D

Revision as of 06:52, 26 March 2017

In this tutorial you will learn (for a 2D material) how to:

  • generate a coulomb potential with a box-like cutoff
  • visualize this coulomb potential
  • use this cutoff in the GW and BSE calculation
  • analyze the difference with similar calculations without cutoff

Prerequisites

Generate the cutoff databse (yambo -r)

To simulate a real isolated 2D-material a convergence with vacuum size is in principle required. but the use of a truncated Coulomb potential allows to achieve faster convergence eliminating the interaction between the repeated images. (see ref. Varsano)

For a 2D system a box-like cutoff in the direction perperdicular to the sheet (in this case z) is applied. The used box size L_z = a_z (cell size in bohr) - 1 bohr = 32 bohr

Create the input file:

$ yambo -F 01_cut2D.in  -r

Open the input file 01_cut2D.in

Change the variables inside as:

RandQpts= 1000000          # [RIM] Number of random q-points in the BZ
RandGvec= 100        RL    # [RIM] Coulomb interaction RS components
CUTGeo= "box z"            # [CUT] Coulomb Cutoff geometry: box/cylinder/sphere X/Y/Z/XY..
% CUTBox
 0.00     | 0.00     | 32.0    |        # [CUT] [au] Box sides


Close the input file and run yambo

$ yambo -F 01_cut2D.in  -J 2D