Optics at the independent particle level: Difference between revisions
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In this tutorial you will learn how to calculate optical spectra at the | In this tutorial you will learn how to calculate optical spectra at the independent particle level for bulk hBN. | ||
== Background == | |||
The long-wavelength dielectric function at the independent particle level (RPA without local fields) is essentially given by the following: | |||
[[File:CH1.png|x50px|Yambo tutorial image]] | [[File:CH1.png|x50px|Yambo tutorial image]] | ||
In practice, Yambo solves the Dyson equation for ''X'', which is described in the [[Local fields]] module. | |||
== Prerequisites == | == Prerequisites == | ||
Line 13: | Line 15: | ||
== Choosing input parameters == | == Choosing input parameters == | ||
Enter the folder for bulk hBN that contains the SAVE directory, and generate the input file. From <code>yambo -H</code> you should understand that the correct option is <code>yambo -o c</code>. Let's add some command line options: | Enter the folder for bulk hBN that contains the ''SAVE'' directory, and generate the input file. From <code>yambo -H</code> you should understand that the correct option is <code>yambo -o c</code>. Let's add some command line options: | ||
<!--If you have already worked in this folder, you might like to clean up any old files, and run the initialization again: | <!--If you have already worked in this folder, you might like to clean up any old files, and run the initialization again: | ||
cd YAMBO_TUTORIALS/hBN/YAMBO | cd YAMBO_TUTORIALS/hBN/YAMBO | ||
Line 20: | Line 22: | ||
Take care to '''not''' delete the <code>ns.*</code> files. --> | Take care to '''not''' delete the <code>ns.*</code> files. --> | ||
$ cd YAMBO_TUTORIALS/hBN/YAMBO | $ cd YAMBO_TUTORIALS/hBN/YAMBO | ||
$ yambo | $ yambo -F yambo.in_IP -J Full -o c | ||
This corresponds to optical properties in G-space at the independent particle level (<code>Chimod= "IP"</code>). | This corresponds to optical properties in G-space at the independent particle level: in the input file this is indicated by (<code>Chimod= "IP"</code>). | ||
====Optics runlevel==== | ====Optics runlevel==== | ||
Let's calculate just for the long-wavelength limit ''q = 0'' which is the valid case for optical spectra. This always corresponds to the ''first'' q-point. Change the following variables in the input file to: | Let's calculate just for the long-wavelength limit ''q = 0'' which is the valid case for optical spectra. This always corresponds to the ''first'' q-point. | ||
Change the following variables in the input file to: | |||
% [[Variables#QpntsRX|QpntsRXd]] | % [[Variables#QpntsRX|QpntsRXd]] | ||
1 | '''1''' | # [Xd] Transferred momenta | 1 | '''1''' | # [Xd] Transferred momenta | ||
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$ yambo -F yambo.in_IP -J Full | $ yambo -F yambo.in_IP -J Full | ||
... | ... | ||
<---> [05] Optics | |||
<---> [LA] SERIAL linear algebra | <---> [LA] SERIAL linear algebra | ||
<---> [DIP] Checking dipoles header | <---> [DIP] Checking dipoles header | ||
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Full SAVE yambo.in_IP r_setup | Full SAVE yambo.in_IP r_setup | ||
o-Full.eel_q1_ip o-Full.eps_q1_ip r-Full_optics_chi | o-Full.eel_q1_ip o-Full.eps_q1_ip r-Full_optics_chi | ||
Let's take a moment to understand what Yambo has done | Let's take a moment to understand what Yambo has done inside the Optics runlevel: | ||
# Compute the ''[x,Vnl]'' term | # Compute the ''[x,Vnl]'' term | ||
# Read the wavefunctions from disc [WF] | # Read the wavefunctions from disc [WF] | ||
Line 62: | Line 65: | ||
[r,Vnl] included :yes | [r,Vnl] included :yes | ||
... | ... | ||
<ol start=" | <ol start="5"> | ||
<li>Finally, Yambo computes ''X<sub>0</sub>'' for this ''q'', and writes the dielectric function inside the <code>o-Full.eps_q1_ip</code> file for plotting</li> | <li>Finally, Yambo computes ''X<sub>0</sub>'' for this ''q'', and writes the dielectric function inside the <code>o-Full.eps_q1_ip</code> file for plotting</li> | ||
</ol> | </ol> |
Revision as of 17:12, 29 March 2017
In this tutorial you will learn how to calculate optical spectra at the independent particle level for bulk hBN.
Background
The long-wavelength dielectric function at the independent particle level (RPA without local fields) is essentially given by the following: In practice, Yambo solves the Dyson equation for X, which is described in the Local fields module.
Prerequisites
- You must first complete the "How to use Yambo" tutorial
You will need:
- The
SAVE
databases for bulk hBN - The
yambo
executable gnuplot
, for plotting spectra
Choosing input parameters
Enter the folder for bulk hBN that contains the SAVE directory, and generate the input file. From yambo -H
you should understand that the correct option is yambo -o c
. Let's add some command line options:
$ cd YAMBO_TUTORIALS/hBN/YAMBO $ yambo -F yambo.in_IP -J Full -o c
This corresponds to optical properties in G-space at the independent particle level: in the input file this is indicated by (Chimod= "IP"
).
Optics runlevel
Let's calculate just for the long-wavelength limit q = 0 which is the valid case for optical spectra. This always corresponds to the first q-point. Change the following variables in the input file to:
% QpntsRXd 1 | 1 | # [Xd] Transferred momenta % ETStpsXd= 1001 # [Xd] Total Energy steps
in order to select just the first q. The last variable ensures we generate a smooth spectrum. Save the input file and launch the code, keeping the command line options as before (i.e., just remove the lower case options):
$ yambo -F yambo.in_IP -J Full ... <---> [05] Optics <---> [LA] SERIAL linear algebra <---> [DIP] Checking dipoles header <---> [x,Vnl] computed using 4 projectors <---> [M 0.017 Gb] Alloc WF ( 0.016) <---> [WF] Performing Wave-Functions I/O from ./SAVE <01s> Dipoles: P and iR (T): |########################################| [100%] 01s(E) 01s(X) <01s> [M 0.001 Gb] Free WF ( 0.016) <01s> [DIP] Writing dipoles header <01s> [X-CG] R(p) Tot o/o(of R) : 5501 52992 100 <01s> Xo@q[1] |########################################| [100%] --(E) --(X) <01s> [06] Game Over & Game summary $ ls Full SAVE yambo.in_IP r_setup o-Full.eel_q1_ip o-Full.eps_q1_ip r-Full_optics_chi
Let's take a moment to understand what Yambo has done inside the Optics runlevel:
- Compute the [x,Vnl] term
- Read the wavefunctions from disc [WF]
- Compute the dipoles, i.e. matrix elements of p
- Write the dipoles to disk as
SAVE/ndb.dip*
databases. This you can see in the report file:
$ grep -A20 "WR" r-Full_optics_chi [WR./Full//ndb.dip_iR_and_P] Brillouin Zone Q/K grids (IBZ/BZ): 14 72 14 72 RL vectors (WF): 1491 Electronic Temperature [K]: 0.0000000 Bosonic Temperature [K]: 0.0000000 X band range : 1 100 RL vectors in the sum : 1491 [r,Vnl] included :yes ...
- Finally, Yambo computes X0 for this q, and writes the dielectric function inside the
o-Full.eps_q1_ip
file for plotting
Cut off
Before plotting the output, let's change a few more variables. The previous calculation used all the G-vectors in expanding the wavefunctions, 1491. This corresponds roughly to the cut off energy of 40Ry we used in the DFT calculation. Generally, however, we can use a smaller value. We use the verbosity to switch on this variable, and a new -J flag to avoid reading the previous database:
$ yambo -F yambo.in_IP -J 6Ry -V RL -o c
Change the value of FFTGvecs
and also its unit:
FFTGvecs= 6 Ry # [FFT] Plane-waves
Save the input file and launch the code again:
$ yambo -F yambo.in_IP -J 6Ry -V RL
and then plot the o-Full.eps_q1_ip and o-6Ry.eps_q1_ip files:
$ gnuplot gnuplot> plot "o-Full.eps_q1_ip" w l,"o-6Ry.eps_q1_ip" w p
Clearly there is very little difference between the two spectra.
q-direction
Now let's select a different component of the dielectric tensor:
$ yambo -o c -F yambo.in_IP -J 6Ry -V RL ... % LongDrXd 0.000000 | 0.000000 | 1.000000 | # [Xd] [cc] Electric Field % ... $ yambo -F yambo.in_IP -J 6Ry -V RL
This time yambo reads from the 6Ry folder, so it does not need to compute the dipoles again, and the calculation is fast. Plotting gives:
$ gnuplot gnuplot> plot "o-6Ry.eps_q1_ip" t "q || x-axis" w l,"o-6Ry.eps_q1_ip_01" t "q || c-axis" w l
Non-local commutator
Last, we show the effect of switching off the non-local commutator term (see the expression at the top) due to the pseudopotential. As there is no option to do this inside yambo, you need to rename the database file. Change back to the q || (1 0 0) direction, and launch yambo with a different -J
option:
$ mv SAVE/ns.kb_pp_pwscf SAVE/ns.kb_pp_pwscf_OFF $ yambo -o c -F yambo.in_IP -J 6Ry_NoVnl $ yambo -F yambo.in_IP -J 6Ry_NoVnl
Note the warning in the output:
<---> [WARNING] Missing non-local pseudopotential contribution
which also appears in the report file, and noted in the database as [r,Vnl] included :no
. The difference is tiny:
However, when your system is larger, with more projectors in the pseudopotential or more k-points (see the BSE tutorial), the inclusion of Vnl can make a huge difference in the computational load, so it's always worth checking to see if the terms are important in your system.
Summary
From this tutorial you've learned:
- How to compute a simple optical spectrum
- How to reduce the computational load through reducing the G-vector/energy cut off and removing the Vnl term
- How to plot different components of the dielectric tensor
- How to use the
-J
option to neatly label and organise files and databases
Links
- Next module: Local fields
- Back to tutorials menu