Difference between revisions of "Tutorial-v.1.0.0"
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− | == | + | == Getting started == |
− | Welcome! | + | Welcome to SALMON Tutorial! |
− | In this tutorial, we explain the use of SALMON from the very beginning, taking a few | + | |
+ | In this tutorial, we explain the use of SALMON from the very beginning, taking a few samples that cover applications of SALMON in several directions. | ||
We assume that you are in the computational environment of UNIX/Linux OS. | We assume that you are in the computational environment of UNIX/Linux OS. | ||
− | First you need to download | + | First you need to download and install SALMON in your computational environment. |
− | and install SALMON in your computational environment. | + | If you have not yet done it, do it following the instruction, [[download-v.1.0.0]] and [[Install and Run-v.1.0.0]]. |
− | You may | + | |
+ | As described in [[Install and Run-v.1.0.0]], you are required to prepare at least an input file and pseudopotential files to run SALMON. | ||
+ | In the following, we present input files for several sample calculations and provide a brief explanation of the namelist variables that appear in the input files. | ||
+ | You may modify the input files to execute for your own calculations. | ||
+ | Pseudopotential files of elements that appear in the samples are also attached. | ||
+ | We also present explanations of main output files. | ||
+ | |||
+ | We present 6 tutorials. | ||
+ | |||
+ | First 3 tutorials (Tutorial-1 ~ 3) are for an isolated molecule, acetylene C2H2. | ||
+ | If you are interested in learning electron dynamics calculations in isolated systems, please look into these tutorials. | ||
+ | In SALMON, we usually calculate the ground state solution first. | ||
+ | This is illustrated in [[#Tutorial-1: Ground state of C2H2 molecule|Tutorial-1]]. | ||
+ | After finishing the ground state calculation, two tutorials of electron dynamics calculations are prepared. | ||
+ | [[#Tutorial-2: Polarizability and photoabsorption of C2H2 molecule|Tutorial-2]] | ||
+ | illustrates the calculation of linear optical responses in real time, obtaining polarizability and photoabsorption of the molecule. | ||
+ | [[#Tutorial-3: Electron dynamics in C2H2 molecule under a pulsed electric field|Tutorial-3]] | ||
+ | illustrates the calculation of electron dynamics in the molecule under a pulsed electric field. | ||
+ | |||
+ | Next 2 tutorials (Tutorial-4 ~ 5) are for a crystalline solid, silicon. | ||
+ | If you are interested in learning electron dynamics calculations in extended periodic systems, please look into these tutorials. | ||
+ | Since ground state calculations of small unit-cell systems are not computationally expensive | ||
+ | and a time evolution calculation is usually much more time-consuming than the ground state calculation, | ||
+ | we recommend to run the ground and the time evolution calculations as a single job. | ||
+ | The following two tutorials are organized in that way. | ||
+ | [[#Tutorial-4: Dielectric function of crystalline silicon|Tutorial-4]] | ||
+ | illustrates the calculation of linear response properties of crystalline silicon to obtain the dielectric function. | ||
+ | [[#Tutorial-5: Electron dynamics in crystalline silicon under a pulsed electric field|Tutorial-5]] | ||
+ | illustrates the calculation of electron dynamics in the crystalline silicon induced by a pulsed electric field. | ||
+ | |||
+ | The final tutorial (Tutorial-6) is for an irradiation and a propagation of a pulsed light in a bulk silicon, | ||
+ | coupling Maxwell equations for the electromagnetic fields of the pulsed light and the electron dynamics in the unit cells. | ||
+ | This calculation is quite time-consuming and is recommended to execute using massively parallel supercomputers. | ||
+ | [[#Tutorial-6: Pulsed-light propagation through a silicon thin film|Tutorial-6]] | ||
+ | illustrates the calculation of a pulsed, linearly polarized light irradiating normally on a surface of a bulk silicon. | ||
+ | |||
+ | == C2H2 (isolated molecules) == | ||
+ | |||
+ | === Tutorial-1: Ground state of C2H2 molecule === | ||
+ | In this tutorial, we learn the calculation of the ground state solution of acetylene (C2H2) molecule, solving the static Kohn-Sham equation. | ||
+ | This tutorial will be useful to learn how to set up calculations in SALMON for any isolated systems such as molecules and nanoparticles. | ||
+ | It should be noted that at present it is not possible to carry out the geometry optimization in SALMON. | ||
+ | Therefore, atomic positions of the molecule are specified in the input file and are fixed during the calculations. | ||
+ | |||
+ | ==== Input files ==== | ||
+ | : To run the code, following files are used: | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''C2H2_gs.inp'' || input file that contains namelist variables and their values | ||
+ | |- | ||
+ | | ''C_rps.dat'' || pseodupotential file for carbon atom | ||
+ | |- | ||
+ | | ''H_rps.dat'' || pseudopotential file for hydrogen atom | ||
+ | |} | ||
+ | |||
+ | * You may download the above 3 files (zipped file) from: | ||
+ | |||
+ | [[media:C2H2_gs_input.zip| Download zipped input and pseudopotential files]] | ||
+ | |||
+ | * In the input file ''C2H2_gs.inp'', namelists variables are specified. Most of them are mandatory to execute the ground state calculation. We present their explanations below: | ||
+ | |||
+ | [[Explanations of input files (ground state of C2H2 molecule)-v.1.0.0]] | ||
+ | |||
+ | : This will help you to prepare an input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file ''SALMON/manual/input_variables.md''. | ||
+ | |||
+ | ==== Output files ==== | ||
+ | : After the calculation, following output files are created in the directory that you run the code, | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''C2H2_info.data'' || information on ground state solution | ||
+ | |- | ||
+ | | ''dns.cube'' || a cube file for electron density | ||
+ | |- | ||
+ | | ''elf.cube'' || electron localization function (ELF) | ||
+ | |- | ||
+ | | ''psi1.cube'', ''psi2.cube'', ... || electron orbitals | ||
+ | |- | ||
+ | | ''dos.data'' || density of states | ||
+ | |- | ||
+ | | ''pdos1.data'', ''pdos2.data'', ... || projected density of states | ||
+ | |- | ||
+ | | ''C2H2_gs.bin'' || binary output file to be used in the real-time calculation | ||
+ | |} | ||
+ | |||
+ | * You may download the above files (zipped file, except for the binary file ''C2H2_gs.bin'') from: | ||
+ | |||
+ | [[media:C2H2_gs_output.zip|Download zipped output files]] | ||
+ | |||
+ | * Main results of the calculation such as orbital energies are included in ''C2H2_info.data''. Explanations of the ''C2H2_info.data'' and other output files are described in: | ||
+ | |||
+ | [[Explanations of output files (ground state of C2H2 molecule)-v.1.0.0]] | ||
+ | |||
+ | ==== Images ==== | ||
+ | : We show several image that are created from the output files. | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | image || files used to create the image | ||
+ | |- | ||
+ | | [[:File:HOMO.png#file|highest occupied molecular orbital (HOMO)]] || ''psi1.cube'', ''psi2.cube'', ... | ||
+ | |- | ||
+ | | [[:File:Dns.png#file|electron density]] || ''dns.cube'' | ||
+ | |- | ||
+ | | [[:File:Elf.png#file|electron localization function]] || ''elf.cube'' | ||
+ | |} | ||
+ | |||
+ | === Tutorial-2: Polarizability and photoabsorption of C2H2 molecule === | ||
+ | In this tutorial, we learn the linear response calculation in the acetylene (C2H2) molecule, solving the time-dependent Kohn-Sham equation. | ||
+ | The linear response calculation provides the polarizability and the oscillator strength distribution of the molecule. | ||
+ | This tutorial should be carried out after finishing the ground state calculation that was explained in [[#Tutorial-1: Ground state of C2H2 molecule|Tutorial-1]]. | ||
+ | In the calculation, an impulsive perturbation is applied to all electrons in the C2H2 molecule along the molecular axis which we take ''z'' axis. | ||
+ | Then a time evolution calculation is carried out without any external fields. | ||
+ | During the calculation, the electric dipole moment is monitored. | ||
+ | After the time evolution calculation, a time-frequency Fourier transformation is carried out for the electric dipole moment to obtain the frequency-dependent polarizability. | ||
+ | The imaginary part of the frequency-dependent polarizability is proportional to the oscillator strength distribution and the photoabsorption cross section. | ||
+ | |||
+ | ==== Input files ==== | ||
+ | : To run the code, the input file ''C2H2_rt_response.inp'' that contains namelist variables and their values for the linear response calculation is required. The binary file ''C2H2_gs.bin'' that is created in the ground state calculation and pseudopotential files are also required. The pseudopotential files should be the same as those used in the ground state calculation. | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''C2H2_rt_response.inp'' || input file that contains namelist variables and their values | ||
+ | |- | ||
+ | | ''C_rps.dat'' || pseodupotential file for carbon | ||
+ | |- | ||
+ | | ''H_rps.dat'' || pseudopotential file for hydrogen | ||
+ | |- | ||
+ | | ''C2H2_gs.bin'' || binary file created in the ground state calculation | ||
+ | |} | ||
+ | |||
+ | * You may download the ''C2H2_rt_response.inp'' file (zipped file) from: | ||
+ | |||
+ | [[media:C2H2_rt_response_input.zip| Download zipped input file]] | ||
+ | |||
+ | * In the input file ''C2H2_rt_response.inp'', namelists variables are specified. Most of them are mandatory to execute the linear response calculation. We present their explanations below: | ||
+ | |||
+ | [[Explanations of input files (polarizability and photoabsorption of C2H2 molecule)-v.1.0.0]] | ||
+ | |||
+ | : This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file ''SALMON/manual/input_variables.md''. | ||
+ | |||
+ | ==== Output files ==== | ||
+ | : After the calculation, following output files are created in the directory that you run the code, | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''C2H2_lr.data'' || polarizability and oscillator strength distribution as functions of energy | ||
+ | |- | ||
+ | | ''C2H2_p.data'' || components of dipole moment as functions of time | ||
+ | |} | ||
+ | |||
+ | * You may download the above files (zipped file) from: | ||
+ | |||
+ | [[media:C2H2_rt_response_output.zip|Download zipped output files]] | ||
+ | |||
+ | *Explanations of the output files are given in: | ||
+ | |||
+ | [[Explanations of output files (polarizability and photoabsorption of C2H2 molecule)-v.1.0.0]] | ||
+ | |||
+ | === Tutorial-3: Electron dynamics in C2H2 molecule under a pulsed electric field === | ||
+ | In this tutorial, we learn the calculation of the electron dynamics in the acetylene (C2H2) molecule under a pulsed electric field, solving the time-dependent Kohn-Sham equation. | ||
+ | As outputs of the calculation, such quantities as the total energy and the electric dipole moment of the system as functions of time are calculated. | ||
+ | This tutorial should be carried out after finishing the ground state calculation that was explained in [[#Tutorial-1: Ground state of C2H2 molecule|Tutorial-1]]. | ||
+ | In the calculation, a pulsed electric field that has cos^2 envelope shape is applied. The parameters that characterize the pulsed field such as magnitude, frequency, polarization direction, and carrier envelope phase are specified in the input file. | ||
+ | |||
+ | ==== Input files ==== | ||
+ | : To run the code, following files are used. The ''C2H2.data'' file is created in the ground state calculation. Pseudopotential files are already used in the ground state calculation. Therefore, ''C2H2_rt_pulse.inp'' that specifies namelist variables and their values for the pulsed electric field calculation is the only file that the users need to prepare. | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''C2H2_rt_pulse.inp'' || input file that contain namelist variables and their values. | ||
+ | |- | ||
+ | | ''C_rps.dat'' || pseodupotential file for Carbon | ||
+ | |- | ||
+ | | ''H_rps.dat'' || pseudopotential file for Hydrogen | ||
+ | |- | ||
+ | | ''C2H2.data'' || binary file created in the ground state calculation | ||
+ | |} | ||
+ | |||
+ | * You may download the ''C2H2_rt_pulse.inp'' file (zipped file) from: | ||
+ | |||
+ | [[media:C2H2_rt_pulse_input.zip| Download zipped input file]] | ||
+ | |||
+ | * In the input file ''C2H2_rt_pulse.inp'', namelists variables are specified. Most of them are mandatory to execute the calculation of electron dynamics induced by a pulsed electric field. We present explanations of the namelist variables that appear in the input file in: | ||
+ | |||
+ | [[Explanations of input files (C2H2 molecule under a pulsed electric field)-v.1.0.0]] | ||
+ | |||
+ | : This will help you to prepare the input file for other systems and other pulsed electric fields that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file ''SALMON/manual/input_variables.md''. | ||
+ | |||
+ | ==== Output files ==== | ||
+ | : After the calculation, following output files are created in the directory that you run the code, | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''C2H2_p.data'' || components of the electric dipole moment as functions of time | ||
+ | |- | ||
+ | | ''C2H2_ps.data'' || power spectrum that is obtained by a time-frequency Fourier transformation of the electric dipole moment | ||
+ | |} | ||
+ | |||
+ | * You may download the above files (zipped file) from: | ||
+ | |||
+ | [[media:C2H2_rt_pulse_output.zip|Download zipped output files]] | ||
+ | |||
+ | *Explanations of the files are described in: | ||
+ | |||
+ | [[Explanations of output files (C2H2 molecule under a pulsed electric field)-v.1.0.0]] | ||
+ | |||
+ | == Crystalline silicon (periodic solids) == | ||
+ | |||
+ | === Tutorial-4: Dielectric function of crystalline silicon=== | ||
+ | In this tutorial, we learn the linear response calculation of the crystalline silicon of a diamond structure. | ||
+ | Calculation is done in a cubic unit cell that contains eight silicon atoms. | ||
+ | Since the ground state calculation costs much less computational time than the time evolution calculation, | ||
+ | both calculations are successively executed. | ||
+ | After finishing the ground state calculation, an impulsive perturbation is applied to all electrons in the unit cell | ||
+ | along ''z'' direction. | ||
+ | Since the dielectric function is isotropic in the diamond structure, calculated dielectric function should not depend | ||
+ | on the direction of the perturbation. | ||
+ | During the time evolution, electric current averaged over the unit cell volume is calculated. | ||
+ | A time-frequency Fourier transformation of the electric current gives us a frequency-dependent conductivity. | ||
+ | The dielectric function may be obtained from the conductivity using a standard relation. | ||
+ | |||
+ | ==== Input files ==== | ||
+ | : To run the code, following files are used: | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''Si_gs_rt_response.inp'' || input file that contain namelist variables and their values. | ||
+ | |- | ||
+ | | ''Si_rps.dat'' || pseodupotential file of silicon | ||
+ | |} | ||
+ | |||
+ | * You may download the above 2 files (zipped file) from: | ||
+ | |||
+ | [[media: Si_gs_rt_response_input.zip| Download zipped input and pseudopotential files]] | ||
+ | |||
+ | * In the input file ''Si_gs_rt_response.inp'', namelists variables are specified. Most of them are mandatory to execute the calculation. We present explanations of the namelist variables that appear in the input file in: | ||
+ | |||
+ | [[Explanations of input files (dielectric function of crystalline silicon)-v.1.0.0]] | ||
+ | |||
+ | |||
+ | : This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file ''SALMON/manual/input_variables.md''. | ||
+ | |||
+ | ==== Output files ==== | ||
+ | : After the calculation, following output files are created in the directory that you run the code, | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''Si_gs_info.data'' || information of ground state calculation | ||
+ | |- | ||
+ | | ''Si_eigen.data'' || energy eigenvalues of orbitals | ||
+ | |- | ||
+ | | ''Si_k.data'' || information on k-points | ||
+ | |- | ||
+ | | ''Si_rt.data'' || electric field, vector potential, and current as functions of time | ||
+ | |- | ||
+ | | ''Si_force.data'' || force acting on atoms | ||
+ | |- | ||
+ | | ''Si_lr.data'' || Fourier spectra of the dielectric functions | ||
+ | |- | ||
+ | | ''Si_gs_rt_response.out'' || standard output file | ||
+ | |} | ||
+ | |||
+ | * You may download the above files (zipped file) from: | ||
+ | |||
+ | [[media:Si_gs_rt_response_output.zip|Download zipped output files]] | ||
+ | |||
+ | * Explanations of the output files are described in: | ||
+ | |||
+ | [[Explanation of output fiels (dielectric function of crystalline silicon)-v.1.0.0]] | ||
+ | |||
+ | === Tutorial-5: Electron dynamics in crystalline silicon under a pulsed electric field === | ||
+ | In this tutorial, we learn the calculation of electron dynamics in a unit cell of crystalline silicon of a diamond structure. | ||
+ | Calculation is done in a cubic unit cell that contains eight silicon atoms. | ||
+ | Since the ground state calculation costs much less computational time than the time evolution calculation, | ||
+ | both calculations are successively executed. | ||
+ | After finishing the ground state calculation, a pulsed electric field that has cos^2 envelope shape is applied. | ||
+ | The parameters that characterize the pulsed field such as magnitude, frequency, polarization, and carrier envelope phase | ||
+ | are specified in the input file. | ||
+ | |||
+ | ==== Input files ==== | ||
+ | : To run the code, following files are used: | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''Si_gs_rt_pulse.inp'' || input file that contain namelist variables and their values. | ||
+ | |- | ||
+ | | ''Si_rps.dat'' || pseodupotential file for Carbon | ||
+ | |} | ||
+ | |||
+ | * You may download the above 2 files (zipped file) from: | ||
+ | |||
+ | [[media:Si_gs_rt_pulse_input.zip| Download zipped input and pseudopotential files]] | ||
+ | |||
+ | * In the input file ''Si_gs_rt_pulse.inp'', namelists variables are specified. Most of them are mandatory to execute the calculation. We present explanations of the namelist variables that appear in the input file in: | ||
+ | |||
+ | [[Explanation of input files (crystalline silicon under a pulsed electric field)-v.1.0.0]] | ||
+ | |||
+ | |||
+ | : This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file ''SALMON/manual/input_variables.md''. | ||
+ | |||
+ | ==== Output files ==== | ||
+ | : After the calculation, following output files are created in the directory that you run the code, | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''Si_gs_info.data'' || information of ground state calculation | ||
+ | |- | ||
+ | | ''Si_eigen.data'' || energy eigenvalues of orbitals | ||
+ | |- | ||
+ | | ''Si_k.data'' || information on k-points | ||
+ | |- | ||
+ | | ''Si_rt.data'' || electric field, vector potential, and current as functions of time | ||
+ | |- | ||
+ | | ''Si_force.data'' || force acting on atoms | ||
+ | |- | ||
+ | | ''Si_lr.data'' || Fourier transformations of various quantities | ||
+ | |- | ||
+ | | ''Si_gs_rt_pulse.out'' || standard output file | ||
+ | |} | ||
+ | |||
+ | * You may download the above files (zipped file) from: | ||
+ | |||
+ | [[media:Si_gs_rt_pulse_output.zip|Download zipped output files]] | ||
+ | |||
+ | * Explanations of the output files are described in: | ||
+ | |||
+ | [[Explanation of output files (crystalline silicon under a pulsed electric field)-v.1.0.0]] | ||
+ | |||
+ | == Maxwell + TDDFT multiscale simulation == | ||
+ | |||
+ | === Tutorial-6: Pulsed-light propagation through a silicon thin film === | ||
+ | In this tutorial, we learn the calculation of the propagation of a pulsed light through a thin film of crystalline silicon. | ||
+ | We consider a silicon thin film of ?? nm thickness, and an irradiation of a few-cycle, linearly polarized pulsed light normally on the thin film. | ||
+ | First, to set up initial orbitals, the ground state calculation is carried out. | ||
+ | The pulsed light locates in the vacuum region in front of the thin film. | ||
+ | The parameters that characterize the pulsed light such as magnitude and frequency are specified in the input file. | ||
+ | The calculation ends when the reflected and transmitted pulses reach the vacuum region. | ||
+ | |||
+ | ==== Input files ==== | ||
+ | : To run the code, following files are used: | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''Si_gs_rt_multiscale.inp'' || input file that contain namelist variables and their values. | ||
+ | |- | ||
+ | | ''Si_rps.dat'' || pseodupotential file for silicon | ||
+ | |} | ||
+ | |||
+ | * You may download the above two files (zipped file) from: | ||
+ | |||
+ | [[media: Si_gs_rt_multiscale_input.zip| Download zipped input and pseudopotential files]] | ||
+ | |||
+ | |||
+ | * In the input file ''Si_gs_rt_multiscale.inp'', namelists variables are specified. Most of them are mandatory to execute the calculation. We present explanations of the namelist variables that appear in the input file in: | ||
+ | |||
+ | [[Explanation of input files (pulsed-light propagation through a silicon thin film)-v.1.0.0]] | ||
+ | |||
+ | |||
+ | : This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file ''SALMON/manual/input_variables.md''. | ||
+ | |||
+ | ==== Output files ==== | ||
+ | : After the calculation, following output files are created in the directory that you run the code, | ||
+ | |||
+ | {| class="wikitable" | ||
+ | | file name || description | ||
+ | |- | ||
+ | | ''Si_gs_info.data'' || results of the ground state as well as input parameters | ||
+ | |- | ||
+ | | ''Si_eigen.data'' || orbital energies in the ground state calculation | ||
+ | |- | ||
+ | | ''Si_k.data'' || information on k-points | ||
+ | |- | ||
+ | | ''Si_Ac_xxxxxx.data'' || various quantities at a time as functions of macroscopic position | ||
+ | |- | ||
+ | | ''Si_Ac_M_xxxxxx.data'' || various quantities at a macroscopic point as functions of time | ||
+ | |- | ||
+ | | ''Si_Ac_vac.data'' || vector potential at vacuum position adjacent to the medium | ||
+ | |- | ||
+ | | ''Si_gs_rt_multiscale.out'' || standard output file | ||
+ | |} | ||
+ | |||
+ | * You may download the above files (zipped file) from: | ||
+ | |||
+ | [[media:Si_gs_rt_multiscale_output.zip|Download zipped output files]] | ||
+ | |||
+ | * Explanations of the output files are described in: | ||
+ | |||
+ | [[Explanation of output files (pulsed-light propagation through a silicon thin film)-v.1.0.0]] | ||
+ | |||
+ | == Namelists and their values == | ||
+ | |||
+ | We here summarize namelists that appear in this Tutorial. | ||
+ | A thorough list of the namelist variables may be found in the downloaded file in | ||
+ | 'SALMON/manual/input_variables.md'. | ||
+ | |||
+ | === &units === | ||
+ | |||
+ | Mandatory: none | ||
+ | |||
+ | &units | ||
+ | unit_system='A_eV_fs' | ||
+ | / | ||
+ | |||
+ | This namelist specifies the unit system to be used in the input file. | ||
+ | Options are 'A_eV_fs' for Angstrom, eV, and fs, and 'a.u.' or 'au' for atomic units. | ||
+ | If you do not specify it, atomic unit will be used as default. | ||
+ | |||
+ | For isolated systems (specified by <code>iperiodic = 0</code> in <code>&system</code>), the unit of 1/eV is used for the output files of DOS and PDOS if <code>unit_system = 'A_eV_fs'</code> is specified, while atomic unit is used if not. For other output files, the Angstrom/eV/fs units are used irrespective of the namelist value. | ||
+ | |||
+ | For periodic systems (specified by <code>iperiodic =3</code> in <code>&system</code>), the unit system specified by this namelist variable is used for most output files. See the first few lines of output files to confirm the unit system adopted in the file. | ||
+ | |||
+ | === &calculation === | ||
+ | |||
+ | Mandatory: calc_mode | ||
+ | |||
+ | &calculation | ||
+ | calc_mode = 'GS' | ||
+ | / | ||
+ | |||
+ | The value of the <code>calc_mode</code> should be one of <code>'GS'</code>, <code>'RT'</code>, and <code>'GS-RT'</code>. | ||
+ | For isolated systems (specified by <code>iperiodic = 3</code> in <code>&system</code>), the ground state (<code>'GS'</code>) and the real time (<code>'RT'</code>) calculations should be done separately and sequentially. | ||
+ | For periodic systems (specified by <code>iperiodic = 3</code> in <code>&system</code>), both ground state and real time calculations should be carried out as a single task (<code>calc_mode = 'GS_RT'</code>). | ||
+ | |||
+ | For Maxwell + TDDFT multi-scale calculation, add the following namelist. | ||
+ | |||
+ | use_ms_maxwell = 'y' | ||
+ | |||
+ | === &control === | ||
+ | |||
+ | Mandatory: none | ||
+ | |||
+ | &control | ||
+ | sysname = 'C2H2' | ||
+ | / | ||
+ | |||
+ | 'C2H2' defined by <code>sysname = 'C2H2'</code> will be used in the filenames of output files. | ||
+ | If you do not specify it, the file name will start with 'default'. | ||
+ | |||
+ | === &functional === | ||
+ | |||
+ | &functional | ||
+ | xc ='PZ' | ||
+ | / | ||
+ | |||
+ | <code>xc ='PZ'</code> indicates that (adiabatic) local density approximation is adopted (Perdew-Zunger: Phys. Rev. B23, 5048 (1981)). | ||
+ | This is the default choice. | ||
+ | |||
+ | For isolated systems (specified by <code>iperiodic = 0</code> in <code>&system</code>), only the default choice of 'PZ' is available at present. | ||
+ | |||
+ | For periodic systems (specified by <code>iperiodic = 3</code> in <code>&system</code>), the following functionals may be available in addition to 'PZ': | ||
+ | |||
+ | xc = 'PZM' | ||
+ | |||
+ | Perdew-Zunger LDA with modification to improve sooth connection between high density form and low density one. :J. P. Perdew and Alex Zunger, Phys. Rev. B 23, 5048 (1981). | ||
+ | |||
+ | xc = 'TBmBJ' | ||
+ | cval = 1.0 | ||
+ | |||
+ | Tran-Blaha meta-GGA exchange with Perdew-Wang correlation. :Fabien Tran and Peter Blaha, Phys. Rev. Lett. 102, 226401 (2009). John P. Perdew and Yue Wang, Phys. Rev. B 45, 13244 (1992). This potential is known to provide a reasonable description for the bandage of various insulators. For this choice, the additional mixing parameter 'cval' may be specified. If cval is set to a minus value, the mixing-parameter will be computed following the formula in the original paper [Phys. Rev. Lett. 102, 226401 (2009)]. The default value for this parameter is 1.0. | ||
+ | |||
+ | === &system === | ||
+ | |||
+ | Mandatory: iperiodic, al, nstate, nelem, natom | ||
+ | |||
+ | '''For an isolated molecule (Tutorial-1, 2, 3)''': | ||
+ | |||
+ | &system | ||
+ | iperiodic = 0 | ||
+ | al = 16d0, 16d0, 16d0 | ||
+ | nstate = 5 | ||
+ | nelem = 2 | ||
+ | natom = 4 | ||
+ | nelec = 10 | ||
+ | / | ||
+ | |||
+ | <code>iperiodic = 0</code> indicates that the isolated boundary condition will be used in the calculation. | ||
+ | <code>al = 16d0, 16d0, 16d0</code> specifies the lengths of three sides of the rectangular parallelepiped where the grid points are prepared. | ||
+ | <code>nstate = 8</code> indicates the number of Kohn-Sham orbitals to be solved. | ||
+ | <code>nelec = 10</code> indicate the number of valence electrons in the system. Since the present code assumes that the system is spin saturated, <code>nstate</code> should be equal to or larger than <code>nelec/2</code>. | ||
+ | <code>nelem = 2</code> and <code>natom = 4</code> indicate the number of elements and the number of atoms in the system, respectively. | ||
+ | |||
+ | '''For a periodic system (Tutorial-4, 5)''': | ||
+ | |||
+ | &system | ||
+ | iperiodic = 3 | ||
+ | al = 10.26d0,10.26d0,10.26d0 | ||
+ | nstate = 32 | ||
+ | nelec = 32 | ||
+ | nelem = 1 | ||
+ | natom = 8 | ||
+ | / | ||
+ | |||
+ | <code>iperiodic = 3</code> indicates that three dimensional periodic boundary condition (bulk crystal) is assumed. | ||
+ | <code>al = 10.26d0, 10.26d0, 10.26d0</code> specifies the lattice constans of the unit cell. | ||
+ | <code>nstate = 32</code> indicates the number of Kohn-Sham orbitals to be solved. | ||
+ | <code>nelec = 32</code> indicate the number of valence electrons in the system. | ||
+ | <code>nelem = 1</code> and <code>natom = 8</code> indicate the number of elements and the number of atoms in the system, respectively. | ||
+ | |||
+ | '''For Maxwell - TDDFT multi scale calculation (Tutorial-6)''': | ||
+ | |||
+ | &system | ||
+ | iperiodic = 3 | ||
+ | al = 10.26d0,10.26d0,10.26d0 | ||
+ | isym = 8 | ||
+ | crystal_structure = 'diamond' | ||
+ | nstate = 32 | ||
+ | nelec = 32 | ||
+ | nelem = 1 | ||
+ | natom = 8 | ||
+ | / | ||
+ | |||
+ | The difference from the above case is the variables, <code>isym = 8</code> and <code>crystal_structure = 'diamond'</code>, | ||
+ | which indicates that the spatial symmetry of the unit cell is used in the calculation. | ||
+ | Although the use of the symmetry substantially reduces the computational cost, it should be used very carefully. | ||
+ | At present, the spatial symmetry has been implemented only for the case of the diamond structure. | ||
+ | |||
+ | === &pseudo === | ||
+ | |||
+ | Mandatory: pseudo_file, izatom | ||
+ | |||
+ | '''For C2H2 molecule''': | ||
+ | |||
+ | &pseudo | ||
+ | izatom(1)=6 | ||
+ | izatom(2)=1 | ||
+ | pseudo_file(1)='C_rps.dat' | ||
+ | pseudo_file(2)='H_rps.dat' | ||
+ | lmax_ps(1)=1 | ||
+ | lmax_ps(2)=0 | ||
+ | lloc_ps(1)=1 | ||
+ | lloc_ps(2)=0 | ||
+ | / | ||
+ | |||
+ | Parameters related to atomic species and pseudopotentials. | ||
+ | <code>izatom(1) = 6</code> specifies the atomic number of the element #1. | ||
+ | <code>pseudo_file(1) = 'C_rps.dat'</code> indicates the filename of the pseudopotential of element #1. | ||
+ | <code>lmax_ps(1) = 1</code> and <code>lloc_ps(1) = 1</code> specify the maximum angular momentum of the pseudopotential projector and the angular momentum of the pseudopotential that will be treated as local, respectively. | ||
+ | |||
+ | '''For crystalline Si''': | ||
+ | |||
+ | &pseudo | ||
+ | izatom(1)=14 | ||
+ | pseudo_file(1) = './Si_rps.dat' | ||
+ | lloc_ps(1)=2 | ||
+ | / | ||
+ | |||
+ | <code>izatom(1) = 14</code> indicates the atomic number of the element #1. | ||
+ | <code>pseudo_file(1) = 'Si_rps.dat'</code> indicates the pseudopotential filename of element #1. | ||
+ | <code>lloc_ps(1) = 2</code> indicate the angular momentum of the pseudopotential that will be treated as local. | ||
+ | |||
+ | === &atomic_coor === | ||
+ | |||
+ | Mandatory: atomic_coor or atomic_red_coor (they may be provided as a separate file) | ||
+ | |||
+ | '''For C2H2 molecule''': | ||
+ | |||
+ | &atomic_coor | ||
+ | 'C' 0.000000 0.000000 0.599672 1 | ||
+ | 'H' 0.000000 0.000000 1.662257 2 | ||
+ | 'C' 0.000000 0.000000 -0.599672 1 | ||
+ | 'H' 0.000000 0.000000 -1.662257 2 | ||
+ | / | ||
+ | |||
+ | Cartesian coordinates of atoms. The first column indicates the element. Next three columns specify Cartesian coordinates of the atoms. The number in the last column labels the element. | ||
+ | |||
+ | === &atomic_red_coor === | ||
+ | |||
+ | Mandatory: atomic_coor or atomic_red_coor (they may be provided as a separate file) | ||
+ | |||
+ | '''For a crystalline silicon''': | ||
+ | |||
+ | &atomic_red_coor | ||
+ | 'Si' .0 .0 .0 1 | ||
+ | 'Si' .25 .25 .25 1 | ||
+ | 'Si' .5 .0 .5 1 | ||
+ | 'Si' .0 .5 .5 1 | ||
+ | 'Si' .5 .5 .0 1 | ||
+ | 'Si' .75 .25 .75 1 | ||
+ | 'Si' .25 .75 .75 1 | ||
+ | 'Si' .75 .75 .25 1 | ||
+ | / | ||
+ | |||
+ | Cartesian coordinates of atoms are specified in a reduced coordinate system. First column indicates the element, next three columns specify reduced Cartesian coordinates of the atoms, and the last column labels the element. | ||
+ | |||
+ | === &rgrid === | ||
+ | |||
+ | Mandatory: dl or num_rgrid | ||
+ | |||
+ | This namelist provides grid spacing of Cartesian coordinate system. | ||
+ | <code>dl(3)</code> specify the grid spacing in three Cartesian coordinates. | ||
+ | This is adopted for C2H2 calculation (Tutorial-1). | ||
+ | |||
+ | &rgrid | ||
+ | dl = 0.25d0, 0.25d0, 0.25d0 | ||
+ | / | ||
+ | |||
+ | <code>num_rgrid(3)</code> specify the number of grid points in each Cartesian direction. | ||
+ | This is adopted for crystalline Is calculation (Tutorial-4, 5, 6). | ||
+ | |||
+ | &rgrid | ||
+ | num_rgrid = 12,12,12 | ||
+ | / | ||
+ | |||
+ | === &kgrid === | ||
+ | |||
+ | Mandatory: none | ||
+ | |||
+ | This namelist provides grid spacing of k-space for periodic systems. | ||
+ | |||
+ | &kgrid | ||
+ | num_kgrid = 4,4,4 | ||
+ | / | ||
+ | |||
+ | === &scf === | ||
+ | |||
+ | Mandatory: nscf | ||
+ | |||
+ | This namelists specify parameters related to the self-consistent field calculation. | ||
+ | |||
+ | &scf | ||
+ | ncg = 4 | ||
+ | nscf = 1000 | ||
+ | convergence = 'norm_rho_dng' | ||
+ | threshold_norm_rho = 1.d-15 | ||
+ | / | ||
+ | |||
+ | <code>ncg = 4</code> is the number of conjugate-gradient iterations in solving the Kohn-Sham equation. Usually this value should be 4 or 5. <code>nscf = 1000</code> is the number of scf iterations. For isolated systems specified by <code>&system/iperiodic = 0</code>, the scf loop in the ground state calculation ends before the number of the scf iterations reaches <code>nscf</code>, if a convergence criterion is satisfied. There are several options to examine the convergence. If the value of <code>norm_rho_dng</code> is specified, the convergence is examined by the squared difference of the electron density, | ||
+ | |||
+ | === &hartree === | ||
+ | |||
+ | Mandatory: none | ||
+ | |||
+ | &hartree | ||
+ | meo = 3 | ||
+ | num_pole_xyz = 2,2,2 | ||
+ | / | ||
+ | |||
+ | <code>meo</code> specifies the order of multipole expansion of electron density that is used to prepare boundary condition for the Hartree potential. | ||
+ | * <code>meo=1</code>: Monopole expansion (spherical boundary condition). | ||
+ | * <code>meo=2</code>: Multipole expansions around each atom. | ||
+ | * <code>meo=3</code>: Multipole expansion around the center of mass of electrons in cubits that are defined by <code>num_pole_xyz</code>. | ||
+ | <code>num_pole_xyz(3)</code> defines the division of space when <code>meo = 3</code> is specified. | ||
+ | |||
+ | A default for <code>meo</code> is <code>3</code>, and defaults for <code>num_pole_xyz</code> are <code>(0,0,0)</code>. | ||
+ | When default is set for <code>num_pole_xyz</code>, the division of space is carried out using a prescribed method. | ||
+ | |||
+ | === &tgrid === | ||
+ | |||
+ | Mandatory: dt, Nt | ||
+ | |||
+ | &tgrid | ||
+ | dt=1.25d-3 | ||
+ | nt=5000 | ||
+ | / | ||
+ | |||
+ | <code>dt=1.25d-3</code> specifies the time step of the time evolution calculation. | ||
+ | <code>nt=5000</code> specifies the number of time steps in the calculation. | ||
+ | |||
+ | === &propagation === | ||
+ | |||
+ | This namelist specifies the numerical method for time evolution calculations of electron orbitals. | ||
+ | |||
+ | &propagation | ||
+ | propagator='etrs' | ||
+ | / | ||
+ | |||
+ | <code>propagator = 'etrs'</code> indicates the use of enforced time-reversal symmetry propagator. [https://doi.org/10.1016/S0010-4655(02)00686-0 M.A.L. Marques, A. Castro, G.F. Bertsch, and A. Rubio, Comput. Phys. Commun., 151 60 (2003)]. | ||
+ | |||
+ | &propagation | ||
+ | propagator='middlepoint' | ||
+ | / | ||
+ | |||
+ | <code>propagation='middlepoint'</code> indicates that Hamiltonian at midpoint of two-times is used. | ||
+ | |||
+ | The default is ''middlepoint''. | ||
+ | |||
+ | === &emfield === | ||
+ | |||
+ | This namelist specifies the pulse shape of an electric filed applied to the system in time evolution calculations. | ||
+ | We explain below separating two cases, [[#Linear response calculations]] and [[#Pulsed electric field calculations]]. | ||
+ | |||
+ | ==== Linear response calculations ==== | ||
+ | |||
+ | A weak impulsive field is applied at ''t=0''. | ||
+ | For this case, <code>ae_shape1 = 'impulse'</code> should be described. | ||
+ | |||
+ | Mandatory: ae_shape1 | ||
+ | |||
+ | &emfield | ||
+ | ae_shape1 = 'impulse' | ||
+ | epdir_re1 = 0.d0,0.d0,1.d0 | ||
+ | / | ||
+ | |||
+ | <code>epdir_rel(3)</code> specify a unit vector that indicates the direction of the impulse. | ||
+ | |||
+ | For a periodic system specified by <code>iperiodic = 3</code>, one may add <code>trans_longi</code>. | ||
+ | It has the value, <code>'tr'</code>(transverse) or <code>'lo'</code>(longitudinal), that specifies the treatment of the | ||
+ | polarization in the time evolution calculation. The default is <code>'tr'</code>. | ||
+ | |||
+ | &emfield | ||
+ | trans_longi = 'tr' | ||
+ | ae_shape1 = 'impulse' | ||
+ | epdir_re1 = 0.,0.,1. | ||
+ | / | ||
+ | |||
+ | The magnitude of the impulse of the pulse may be explicitly specified by, for example, <code>e_impulse = 1d-2</code>. The default is '1d-2' in atomic unit. | ||
+ | |||
+ | ==== Pulsed electric field calculations ==== | ||
+ | |||
+ | A Pulsed electric field of finite time duration is applied. | ||
+ | For this case, <code>as_shape1</code> should be specified. | ||
+ | It indicates the shape of the envelope of the pulse. | ||
+ | The options include 'Acos2' and 'Ecos2' (See below for other options). | ||
+ | |||
+ | Mandatory: ae_shape1, epdir_re1, {rlaser_int1 or amplitude1}, omega1, pulse_tw1, phi_cep1 | ||
+ | |||
+ | &emfield | ||
+ | ae_shape1 = 'Ecos2' | ||
+ | epdir_re1 = 0.d0,0.d0,1.d0 | ||
+ | rlaser_int_wcm2_1 = 1.d8 | ||
+ | omega1=9.28d0 | ||
+ | pulse_tw1=6.d0 | ||
+ | phi_cep1=0.75d0 | ||
+ | / | ||
+ | |||
+ | <code>ae_shape1 = 'Ecos2'</code> specifies the envelope of the pulsed electric field, | ||
+ | 'Ecos2' for the cos^2 envelope for the electric field. | ||
+ | If 'Acos2' is specified, this gives cos^2 envelope for the vector potential. | ||
+ | Note that 'phi_cep1' must be 0.75 (or 0.25) if one employs 'Ecos2' pulse shape, since otherwise the time integral of the electric field does not vanish. | ||
+ | There is no such restriction for the 'Acos2' pulse shape. | ||
+ | |||
+ | <code>epdir_re1 = 0.d0,0.d0,1.d0</code> specifies the real part of the unit polarization vector of the pulsed electric field. | ||
+ | If only the real part is specified, it describes a linearly polarized pulse. | ||
+ | Using both real ('epdir_re1') and imaginary ('epdir_im1') parts of the polarization vector, circularly (and general ellipsoidary) polarized pulses may be described. | ||
+ | |||
+ | <code>laser_int_wcm2_1 = 1.d8</code> specifies the maximum intensity of the applied electric field in unit of W/cm^2. | ||
+ | It is also possible to specify the maximum intensity of the pulse by <code>amplitude1</code>. | ||
+ | |||
+ | <code>omega1=9.26d0</code> specifies the average photon energy (frequency multiplied with hbar). | ||
+ | |||
+ | <code>pulse_tw1=6.d0</code> specifies the pulse duration. | ||
+ | Note that it is not the FWHM but a full duration of the cos^2 envelope. | ||
+ | |||
+ | <code>phi_cep1=0.75d0</code> specifies the carrier envelope phase of the pulse. | ||
+ | As noted above, 'phi_cep1' must be 0.75 (or 0.25) if one employs 'Ecos2' pulse shape, since otherwise the time integral of the electric field does not vanish. | ||
+ | There is no such restriction for the 'Acos2' pulse shape. | ||
+ | |||
+ | It is possible to use two pulses simultaneously to simulate pump-probe experiments, adding information for two pulses. | ||
+ | To specify the second pulse, change from 1 to 2 in the namelist variables, like <code>ae_shape2</code>. | ||
+ | The time delay between two pulses is specified by the variable 't1_t2'. | ||
+ | |||
+ | For a periodic system specified by <code>iperiodic = 3</code>, one may add <code>trans_longi</code>. | ||
+ | It has the value, <code>'tr'</code>(transverse) or <code>'lo'</code>(longitudinal), that specifies the treatment of the | ||
+ | polarization in the time evolution calculation. The default is <code>'tr'</code>. | ||
+ | For a periodic system, it is also specify 'Acos3', 'Acos4', 'Acos6', 'Acos8' for <code>ae_shape1</code>. | ||
+ | |||
+ | === &analysis === | ||
+ | |||
+ | Mandatory: none | ||
+ | |||
+ | The following namelists specify whether the output files are created or not after the calculation. | ||
+ | In the ground state calculation of isolated systems (Tutorial-1): | ||
+ | |||
+ | &analysis | ||
+ | out_psi = 'y' | ||
+ | out_dns = 'y' | ||
+ | out_dos = 'y' | ||
+ | out_pdos = 'y' | ||
+ | out_elf = 'y' | ||
+ | / | ||
+ | |||
+ | In the time evolution calculation of isolated systems (Tutorial-3): | ||
+ | |||
+ | &analysis | ||
+ | out_dns_rt = 'y' | ||
+ | out_elf_rt = 'y' | ||
+ | out_estatic_rt = 'y' | ||
+ | / | ||
+ | |||
+ | In the following namelists, variables related to time-frequency Fourier analysis are specified. | ||
− | + | &analysis | |
− | + | nenergy=1000 | |
− | + | de=0.001 | |
− | + | / | |
− | |||
− | + | <code>nenergy=1000</code> specifies the number of energy steps, and <code>de=0.001</code> specifies the energy spacing in the time-frequency Fourier transformation. | |
− | |||
− | + | === &multiscale === | |
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
+ | This namelist specifies information necessary for Maxwell - TDDFT multiscale calculations. | ||
+ | &multiscale | ||
+ | fdtddim = '1D' | ||
+ | twod_shape = 'periodic' | ||
+ | nx_m = 4 | ||
+ | ny_m = 1 | ||
+ | hX_m = 250d0 | ||
+ | nxvacl_m = -2000 | ||
+ | nxvacr_m = 256 | ||
+ | / | ||
+ | <code>fdtddim</code> specifies the spatial dimension of the macro system. <code>fdtddim='1D'</code> indicates that one-dimensional equation is solved for the macroscopic vector potential. | ||
+ | <code>nx_m = 4</code> specifies the number of the macroscopic grid points in for x-direction in the spatial region where the material exists. | ||
+ | <code>hx_m = 250d0</code> specifies the grid spacing of the macroscopic grid in x-direction. | ||
− | == | + | <code> nxvacl_m = -2000</code> and <code>nxvacr_m = 256</code> indicate the number of grid points in the vacuum region, <code>nxvacl_m</code> for the left and <code>nxvacr_m</code> for the right from the surface of the material. |
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | |||
− | == | + | === ¶llel === |
− | + | When you execute a job with MPI parallelization, you are not required to specify any parameters that describe the assignment of the parallelization; the assignment is carried out automatically. You may also specify the parameters explicitly as below. | |
− | |||
− | |||
− | |||
− | |||
− | + | Mandatory: none | |
− | |||
− | |||
− | |||
− | |||
− | |||
− | == | + | ¶llel |
− | + | nproc_ob = 1 | |
− | + | nproc_domain = 1,1,1 | |
− | + | nproc_domain_s = 1,1,1 | |
− | + | / | |
− | |||
− | + | * <code>nproc_ob</code> specifies the number of MPI parallelization to divide the electron orbitals. The default value is 0 (automatic parallelization). | |
− | + | * <code>nproc_domain(3)</code>specifies the number of MPI parallelization to divide the spatial grids of the electron orbitals in three Cartesian directions. The default values are (0/0/0) (automatic parallelization). | |
− | * | + | * <code>nproc_domain_s(3)'</code> specifies the number of MPI parallelization to divide the spatial grids related to the electron density in three Cartesian directions. The default values are (0/0/0) (automatic parallelization). |
− | |||
− | |||
− | * | ||
− | + | The following conditions must be satisfied. | |
− | * | + | * The total number of processors must be equal to both <code>nproc_ob * nproc_domain(1) * nproc_domain(2) * nproc_domain(3)</code> and also <code>nproc_domain_s(1) * nproc_domain_s(2) * nproc_domain_s(3)</code>. |
− | * | + | * <code>nproc_domain_s(1)</code> is a multiple of <code>nproc_domain(1)</code>, and the same relations to the second and third components. |
− | ** | ||
− | * | ||
− |
Latest revision as of 14:11, 23 November 2017
Contents
- 1 Getting started
- 2 C2H2 (isolated molecules)
- 3 Crystalline silicon (periodic solids)
- 4 Maxwell + TDDFT multiscale simulation
- 5 Namelists and their values
Getting started
Welcome to SALMON Tutorial!
In this tutorial, we explain the use of SALMON from the very beginning, taking a few samples that cover applications of SALMON in several directions. We assume that you are in the computational environment of UNIX/Linux OS. First you need to download and install SALMON in your computational environment. If you have not yet done it, do it following the instruction, download-v.1.0.0 and Install and Run-v.1.0.0.
As described in Install and Run-v.1.0.0, you are required to prepare at least an input file and pseudopotential files to run SALMON. In the following, we present input files for several sample calculations and provide a brief explanation of the namelist variables that appear in the input files. You may modify the input files to execute for your own calculations. Pseudopotential files of elements that appear in the samples are also attached. We also present explanations of main output files.
We present 6 tutorials.
First 3 tutorials (Tutorial-1 ~ 3) are for an isolated molecule, acetylene C2H2. If you are interested in learning electron dynamics calculations in isolated systems, please look into these tutorials. In SALMON, we usually calculate the ground state solution first. This is illustrated in Tutorial-1. After finishing the ground state calculation, two tutorials of electron dynamics calculations are prepared. Tutorial-2 illustrates the calculation of linear optical responses in real time, obtaining polarizability and photoabsorption of the molecule. Tutorial-3 illustrates the calculation of electron dynamics in the molecule under a pulsed electric field.
Next 2 tutorials (Tutorial-4 ~ 5) are for a crystalline solid, silicon. If you are interested in learning electron dynamics calculations in extended periodic systems, please look into these tutorials. Since ground state calculations of small unit-cell systems are not computationally expensive and a time evolution calculation is usually much more time-consuming than the ground state calculation, we recommend to run the ground and the time evolution calculations as a single job. The following two tutorials are organized in that way. Tutorial-4 illustrates the calculation of linear response properties of crystalline silicon to obtain the dielectric function. Tutorial-5 illustrates the calculation of electron dynamics in the crystalline silicon induced by a pulsed electric field.
The final tutorial (Tutorial-6) is for an irradiation and a propagation of a pulsed light in a bulk silicon, coupling Maxwell equations for the electromagnetic fields of the pulsed light and the electron dynamics in the unit cells. This calculation is quite time-consuming and is recommended to execute using massively parallel supercomputers. Tutorial-6 illustrates the calculation of a pulsed, linearly polarized light irradiating normally on a surface of a bulk silicon.
C2H2 (isolated molecules)
Tutorial-1: Ground state of C2H2 molecule
In this tutorial, we learn the calculation of the ground state solution of acetylene (C2H2) molecule, solving the static Kohn-Sham equation. This tutorial will be useful to learn how to set up calculations in SALMON for any isolated systems such as molecules and nanoparticles. It should be noted that at present it is not possible to carry out the geometry optimization in SALMON. Therefore, atomic positions of the molecule are specified in the input file and are fixed during the calculations.
Input files
- To run the code, following files are used:
file name | description |
C2H2_gs.inp | input file that contains namelist variables and their values |
C_rps.dat | pseodupotential file for carbon atom |
H_rps.dat | pseudopotential file for hydrogen atom |
- You may download the above 3 files (zipped file) from:
Download zipped input and pseudopotential files
- In the input file C2H2_gs.inp, namelists variables are specified. Most of them are mandatory to execute the ground state calculation. We present their explanations below:
Explanations of input files (ground state of C2H2 molecule)-v.1.0.0
- This will help you to prepare an input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file SALMON/manual/input_variables.md.
Output files
- After the calculation, following output files are created in the directory that you run the code,
file name | description |
C2H2_info.data | information on ground state solution |
dns.cube | a cube file for electron density |
elf.cube | electron localization function (ELF) |
psi1.cube, psi2.cube, ... | electron orbitals |
dos.data | density of states |
pdos1.data, pdos2.data, ... | projected density of states |
C2H2_gs.bin | binary output file to be used in the real-time calculation |
- You may download the above files (zipped file, except for the binary file C2H2_gs.bin) from:
Download zipped output files
- Main results of the calculation such as orbital energies are included in C2H2_info.data. Explanations of the C2H2_info.data and other output files are described in:
Explanations of output files (ground state of C2H2 molecule)-v.1.0.0
Images
- We show several image that are created from the output files.
image | files used to create the image |
highest occupied molecular orbital (HOMO) | psi1.cube, psi2.cube, ... |
electron density | dns.cube |
electron localization function | elf.cube |
Tutorial-2: Polarizability and photoabsorption of C2H2 molecule
In this tutorial, we learn the linear response calculation in the acetylene (C2H2) molecule, solving the time-dependent Kohn-Sham equation. The linear response calculation provides the polarizability and the oscillator strength distribution of the molecule. This tutorial should be carried out after finishing the ground state calculation that was explained in Tutorial-1. In the calculation, an impulsive perturbation is applied to all electrons in the C2H2 molecule along the molecular axis which we take z axis. Then a time evolution calculation is carried out without any external fields. During the calculation, the electric dipole moment is monitored. After the time evolution calculation, a time-frequency Fourier transformation is carried out for the electric dipole moment to obtain the frequency-dependent polarizability. The imaginary part of the frequency-dependent polarizability is proportional to the oscillator strength distribution and the photoabsorption cross section.
Input files
- To run the code, the input file C2H2_rt_response.inp that contains namelist variables and their values for the linear response calculation is required. The binary file C2H2_gs.bin that is created in the ground state calculation and pseudopotential files are also required. The pseudopotential files should be the same as those used in the ground state calculation.
file name | description |
C2H2_rt_response.inp | input file that contains namelist variables and their values |
C_rps.dat | pseodupotential file for carbon |
H_rps.dat | pseudopotential file for hydrogen |
C2H2_gs.bin | binary file created in the ground state calculation |
- You may download the C2H2_rt_response.inp file (zipped file) from:
Download zipped input file
- In the input file C2H2_rt_response.inp, namelists variables are specified. Most of them are mandatory to execute the linear response calculation. We present their explanations below:
Explanations of input files (polarizability and photoabsorption of C2H2 molecule)-v.1.0.0
- This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file SALMON/manual/input_variables.md.
Output files
- After the calculation, following output files are created in the directory that you run the code,
file name | description |
C2H2_lr.data | polarizability and oscillator strength distribution as functions of energy |
C2H2_p.data | components of dipole moment as functions of time |
- You may download the above files (zipped file) from:
Download zipped output files
- Explanations of the output files are given in:
Explanations of output files (polarizability and photoabsorption of C2H2 molecule)-v.1.0.0
Tutorial-3: Electron dynamics in C2H2 molecule under a pulsed electric field
In this tutorial, we learn the calculation of the electron dynamics in the acetylene (C2H2) molecule under a pulsed electric field, solving the time-dependent Kohn-Sham equation. As outputs of the calculation, such quantities as the total energy and the electric dipole moment of the system as functions of time are calculated. This tutorial should be carried out after finishing the ground state calculation that was explained in Tutorial-1. In the calculation, a pulsed electric field that has cos^2 envelope shape is applied. The parameters that characterize the pulsed field such as magnitude, frequency, polarization direction, and carrier envelope phase are specified in the input file.
Input files
- To run the code, following files are used. The C2H2.data file is created in the ground state calculation. Pseudopotential files are already used in the ground state calculation. Therefore, C2H2_rt_pulse.inp that specifies namelist variables and their values for the pulsed electric field calculation is the only file that the users need to prepare.
file name | description |
C2H2_rt_pulse.inp | input file that contain namelist variables and their values. |
C_rps.dat | pseodupotential file for Carbon |
H_rps.dat | pseudopotential file for Hydrogen |
C2H2.data | binary file created in the ground state calculation |
- You may download the C2H2_rt_pulse.inp file (zipped file) from:
Download zipped input file
- In the input file C2H2_rt_pulse.inp, namelists variables are specified. Most of them are mandatory to execute the calculation of electron dynamics induced by a pulsed electric field. We present explanations of the namelist variables that appear in the input file in:
Explanations of input files (C2H2 molecule under a pulsed electric field)-v.1.0.0
- This will help you to prepare the input file for other systems and other pulsed electric fields that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file SALMON/manual/input_variables.md.
Output files
- After the calculation, following output files are created in the directory that you run the code,
file name | description |
C2H2_p.data | components of the electric dipole moment as functions of time |
C2H2_ps.data | power spectrum that is obtained by a time-frequency Fourier transformation of the electric dipole moment |
- You may download the above files (zipped file) from:
Download zipped output files
- Explanations of the files are described in:
Explanations of output files (C2H2 molecule under a pulsed electric field)-v.1.0.0
Crystalline silicon (periodic solids)
Tutorial-4: Dielectric function of crystalline silicon
In this tutorial, we learn the linear response calculation of the crystalline silicon of a diamond structure. Calculation is done in a cubic unit cell that contains eight silicon atoms. Since the ground state calculation costs much less computational time than the time evolution calculation, both calculations are successively executed. After finishing the ground state calculation, an impulsive perturbation is applied to all electrons in the unit cell along z direction. Since the dielectric function is isotropic in the diamond structure, calculated dielectric function should not depend on the direction of the perturbation. During the time evolution, electric current averaged over the unit cell volume is calculated. A time-frequency Fourier transformation of the electric current gives us a frequency-dependent conductivity. The dielectric function may be obtained from the conductivity using a standard relation.
Input files
- To run the code, following files are used:
file name | description |
Si_gs_rt_response.inp | input file that contain namelist variables and their values. |
Si_rps.dat | pseodupotential file of silicon |
- You may download the above 2 files (zipped file) from:
Download zipped input and pseudopotential files
- In the input file Si_gs_rt_response.inp, namelists variables are specified. Most of them are mandatory to execute the calculation. We present explanations of the namelist variables that appear in the input file in:
Explanations of input files (dielectric function of crystalline silicon)-v.1.0.0
- This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file SALMON/manual/input_variables.md.
Output files
- After the calculation, following output files are created in the directory that you run the code,
file name | description |
Si_gs_info.data | information of ground state calculation |
Si_eigen.data | energy eigenvalues of orbitals |
Si_k.data | information on k-points |
Si_rt.data | electric field, vector potential, and current as functions of time |
Si_force.data | force acting on atoms |
Si_lr.data | Fourier spectra of the dielectric functions |
Si_gs_rt_response.out | standard output file |
- You may download the above files (zipped file) from:
Download zipped output files
- Explanations of the output files are described in:
Explanation of output fiels (dielectric function of crystalline silicon)-v.1.0.0
Tutorial-5: Electron dynamics in crystalline silicon under a pulsed electric field
In this tutorial, we learn the calculation of electron dynamics in a unit cell of crystalline silicon of a diamond structure. Calculation is done in a cubic unit cell that contains eight silicon atoms. Since the ground state calculation costs much less computational time than the time evolution calculation, both calculations are successively executed. After finishing the ground state calculation, a pulsed electric field that has cos^2 envelope shape is applied. The parameters that characterize the pulsed field such as magnitude, frequency, polarization, and carrier envelope phase are specified in the input file.
Input files
- To run the code, following files are used:
file name | description |
Si_gs_rt_pulse.inp | input file that contain namelist variables and their values. |
Si_rps.dat | pseodupotential file for Carbon |
- You may download the above 2 files (zipped file) from:
Download zipped input and pseudopotential files
- In the input file Si_gs_rt_pulse.inp, namelists variables are specified. Most of them are mandatory to execute the calculation. We present explanations of the namelist variables that appear in the input file in:
Explanation of input files (crystalline silicon under a pulsed electric field)-v.1.0.0
- This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file SALMON/manual/input_variables.md.
Output files
- After the calculation, following output files are created in the directory that you run the code,
file name | description |
Si_gs_info.data | information of ground state calculation |
Si_eigen.data | energy eigenvalues of orbitals |
Si_k.data | information on k-points |
Si_rt.data | electric field, vector potential, and current as functions of time |
Si_force.data | force acting on atoms |
Si_lr.data | Fourier transformations of various quantities |
Si_gs_rt_pulse.out | standard output file |
- You may download the above files (zipped file) from:
Download zipped output files
- Explanations of the output files are described in:
Explanation of output files (crystalline silicon under a pulsed electric field)-v.1.0.0
Maxwell + TDDFT multiscale simulation
Tutorial-6: Pulsed-light propagation through a silicon thin film
In this tutorial, we learn the calculation of the propagation of a pulsed light through a thin film of crystalline silicon. We consider a silicon thin film of ?? nm thickness, and an irradiation of a few-cycle, linearly polarized pulsed light normally on the thin film. First, to set up initial orbitals, the ground state calculation is carried out. The pulsed light locates in the vacuum region in front of the thin film. The parameters that characterize the pulsed light such as magnitude and frequency are specified in the input file. The calculation ends when the reflected and transmitted pulses reach the vacuum region.
Input files
- To run the code, following files are used:
file name | description |
Si_gs_rt_multiscale.inp | input file that contain namelist variables and their values. |
Si_rps.dat | pseodupotential file for silicon |
- You may download the above two files (zipped file) from:
Download zipped input and pseudopotential files
- In the input file Si_gs_rt_multiscale.inp, namelists variables are specified. Most of them are mandatory to execute the calculation. We present explanations of the namelist variables that appear in the input file in:
Explanation of input files (pulsed-light propagation through a silicon thin film)-v.1.0.0
- This will help you to prepare the input file for other systems that you want to calculate. A complete list of the namelist variables that can be used in the input file can be found in the downloaded file SALMON/manual/input_variables.md.
Output files
- After the calculation, following output files are created in the directory that you run the code,
file name | description |
Si_gs_info.data | results of the ground state as well as input parameters |
Si_eigen.data | orbital energies in the ground state calculation |
Si_k.data | information on k-points |
Si_Ac_xxxxxx.data | various quantities at a time as functions of macroscopic position |
Si_Ac_M_xxxxxx.data | various quantities at a macroscopic point as functions of time |
Si_Ac_vac.data | vector potential at vacuum position adjacent to the medium |
Si_gs_rt_multiscale.out | standard output file |
- You may download the above files (zipped file) from:
Download zipped output files
- Explanations of the output files are described in:
Explanation of output files (pulsed-light propagation through a silicon thin film)-v.1.0.0
Namelists and their values
We here summarize namelists that appear in this Tutorial. A thorough list of the namelist variables may be found in the downloaded file in 'SALMON/manual/input_variables.md'.
&units
Mandatory: none
&units unit_system='A_eV_fs' /
This namelist specifies the unit system to be used in the input file. Options are 'A_eV_fs' for Angstrom, eV, and fs, and 'a.u.' or 'au' for atomic units. If you do not specify it, atomic unit will be used as default.
For isolated systems (specified by iperiodic = 0
in &system
), the unit of 1/eV is used for the output files of DOS and PDOS if unit_system = 'A_eV_fs'
is specified, while atomic unit is used if not. For other output files, the Angstrom/eV/fs units are used irrespective of the namelist value.
For periodic systems (specified by iperiodic =3
in &system
), the unit system specified by this namelist variable is used for most output files. See the first few lines of output files to confirm the unit system adopted in the file.
&calculation
Mandatory: calc_mode
&calculation calc_mode = 'GS' /
The value of the calc_mode
should be one of 'GS'
, 'RT'
, and 'GS-RT'
.
For isolated systems (specified by iperiodic = 3
in &system
), the ground state ('GS'
) and the real time ('RT'
) calculations should be done separately and sequentially.
For periodic systems (specified by iperiodic = 3
in &system
), both ground state and real time calculations should be carried out as a single task (calc_mode = 'GS_RT'
).
For Maxwell + TDDFT multi-scale calculation, add the following namelist.
use_ms_maxwell = 'y'
&control
Mandatory: none
&control sysname = 'C2H2' /
'C2H2' defined by sysname = 'C2H2'
will be used in the filenames of output files.
If you do not specify it, the file name will start with 'default'.
&functional
&functional xc ='PZ' /
xc ='PZ'
indicates that (adiabatic) local density approximation is adopted (Perdew-Zunger: Phys. Rev. B23, 5048 (1981)).
This is the default choice.
For isolated systems (specified by iperiodic = 0
in &system
), only the default choice of 'PZ' is available at present.
For periodic systems (specified by iperiodic = 3
in &system
), the following functionals may be available in addition to 'PZ':
xc = 'PZM'
Perdew-Zunger LDA with modification to improve sooth connection between high density form and low density one. :J. P. Perdew and Alex Zunger, Phys. Rev. B 23, 5048 (1981).
xc = 'TBmBJ' cval = 1.0
Tran-Blaha meta-GGA exchange with Perdew-Wang correlation. :Fabien Tran and Peter Blaha, Phys. Rev. Lett. 102, 226401 (2009). John P. Perdew and Yue Wang, Phys. Rev. B 45, 13244 (1992). This potential is known to provide a reasonable description for the bandage of various insulators. For this choice, the additional mixing parameter 'cval' may be specified. If cval is set to a minus value, the mixing-parameter will be computed following the formula in the original paper [Phys. Rev. Lett. 102, 226401 (2009)]. The default value for this parameter is 1.0.
&system
Mandatory: iperiodic, al, nstate, nelem, natom
For an isolated molecule (Tutorial-1, 2, 3):
&system iperiodic = 0 al = 16d0, 16d0, 16d0 nstate = 5 nelem = 2 natom = 4 nelec = 10 /
iperiodic = 0
indicates that the isolated boundary condition will be used in the calculation.
al = 16d0, 16d0, 16d0
specifies the lengths of three sides of the rectangular parallelepiped where the grid points are prepared.
nstate = 8
indicates the number of Kohn-Sham orbitals to be solved.
nelec = 10
indicate the number of valence electrons in the system. Since the present code assumes that the system is spin saturated, nstate
should be equal to or larger than nelec/2
.
nelem = 2
and natom = 4
indicate the number of elements and the number of atoms in the system, respectively.
For a periodic system (Tutorial-4, 5):
&system iperiodic = 3 al = 10.26d0,10.26d0,10.26d0 nstate = 32 nelec = 32 nelem = 1 natom = 8 /
iperiodic = 3
indicates that three dimensional periodic boundary condition (bulk crystal) is assumed.
al = 10.26d0, 10.26d0, 10.26d0
specifies the lattice constans of the unit cell.
nstate = 32
indicates the number of Kohn-Sham orbitals to be solved.
nelec = 32
indicate the number of valence electrons in the system.
nelem = 1
and natom = 8
indicate the number of elements and the number of atoms in the system, respectively.
For Maxwell - TDDFT multi scale calculation (Tutorial-6):
&system iperiodic = 3 al = 10.26d0,10.26d0,10.26d0 isym = 8 crystal_structure = 'diamond' nstate = 32 nelec = 32 nelem = 1 natom = 8 /
The difference from the above case is the variables, isym = 8
and crystal_structure = 'diamond'
,
which indicates that the spatial symmetry of the unit cell is used in the calculation.
Although the use of the symmetry substantially reduces the computational cost, it should be used very carefully.
At present, the spatial symmetry has been implemented only for the case of the diamond structure.
&pseudo
Mandatory: pseudo_file, izatom
For C2H2 molecule:
&pseudo izatom(1)=6 izatom(2)=1 pseudo_file(1)='C_rps.dat' pseudo_file(2)='H_rps.dat' lmax_ps(1)=1 lmax_ps(2)=0 lloc_ps(1)=1 lloc_ps(2)=0 /
Parameters related to atomic species and pseudopotentials.
izatom(1) = 6
specifies the atomic number of the element #1.
pseudo_file(1) = 'C_rps.dat'
indicates the filename of the pseudopotential of element #1.
lmax_ps(1) = 1
and lloc_ps(1) = 1
specify the maximum angular momentum of the pseudopotential projector and the angular momentum of the pseudopotential that will be treated as local, respectively.
For crystalline Si:
&pseudo izatom(1)=14 pseudo_file(1) = './Si_rps.dat' lloc_ps(1)=2 /
izatom(1) = 14
indicates the atomic number of the element #1.
pseudo_file(1) = 'Si_rps.dat'
indicates the pseudopotential filename of element #1.
lloc_ps(1) = 2
indicate the angular momentum of the pseudopotential that will be treated as local.
&atomic_coor
Mandatory: atomic_coor or atomic_red_coor (they may be provided as a separate file)
For C2H2 molecule:
&atomic_coor 'C' 0.000000 0.000000 0.599672 1 'H' 0.000000 0.000000 1.662257 2 'C' 0.000000 0.000000 -0.599672 1 'H' 0.000000 0.000000 -1.662257 2 /
Cartesian coordinates of atoms. The first column indicates the element. Next three columns specify Cartesian coordinates of the atoms. The number in the last column labels the element.
&atomic_red_coor
Mandatory: atomic_coor or atomic_red_coor (they may be provided as a separate file)
For a crystalline silicon:
&atomic_red_coor 'Si' .0 .0 .0 1 'Si' .25 .25 .25 1 'Si' .5 .0 .5 1 'Si' .0 .5 .5 1 'Si' .5 .5 .0 1 'Si' .75 .25 .75 1 'Si' .25 .75 .75 1 'Si' .75 .75 .25 1 /
Cartesian coordinates of atoms are specified in a reduced coordinate system. First column indicates the element, next three columns specify reduced Cartesian coordinates of the atoms, and the last column labels the element.
&rgrid
Mandatory: dl or num_rgrid
This namelist provides grid spacing of Cartesian coordinate system.
dl(3)
specify the grid spacing in three Cartesian coordinates.
This is adopted for C2H2 calculation (Tutorial-1).
&rgrid dl = 0.25d0, 0.25d0, 0.25d0 /
num_rgrid(3)
specify the number of grid points in each Cartesian direction.
This is adopted for crystalline Is calculation (Tutorial-4, 5, 6).
&rgrid num_rgrid = 12,12,12 /
&kgrid
Mandatory: none
This namelist provides grid spacing of k-space for periodic systems.
&kgrid num_kgrid = 4,4,4 /
&scf
Mandatory: nscf
This namelists specify parameters related to the self-consistent field calculation.
&scf ncg = 4 nscf = 1000 convergence = 'norm_rho_dng' threshold_norm_rho = 1.d-15 /
ncg = 4
is the number of conjugate-gradient iterations in solving the Kohn-Sham equation. Usually this value should be 4 or 5. nscf = 1000
is the number of scf iterations. For isolated systems specified by &system/iperiodic = 0
, the scf loop in the ground state calculation ends before the number of the scf iterations reaches nscf
, if a convergence criterion is satisfied. There are several options to examine the convergence. If the value of norm_rho_dng
is specified, the convergence is examined by the squared difference of the electron density,
&hartree
Mandatory: none
&hartree meo = 3 num_pole_xyz = 2,2,2 /
meo
specifies the order of multipole expansion of electron density that is used to prepare boundary condition for the Hartree potential.
-
meo=1
: Monopole expansion (spherical boundary condition). -
meo=2
: Multipole expansions around each atom. -
meo=3
: Multipole expansion around the center of mass of electrons in cubits that are defined bynum_pole_xyz
.
num_pole_xyz(3)
defines the division of space when meo = 3
is specified.
A default for meo
is 3
, and defaults for num_pole_xyz
are (0,0,0)
.
When default is set for num_pole_xyz
, the division of space is carried out using a prescribed method.
&tgrid
Mandatory: dt, Nt
&tgrid dt=1.25d-3 nt=5000 /
dt=1.25d-3
specifies the time step of the time evolution calculation.
nt=5000
specifies the number of time steps in the calculation.
&propagation
This namelist specifies the numerical method for time evolution calculations of electron orbitals.
&propagation propagator='etrs' /
propagator = 'etrs'
indicates the use of enforced time-reversal symmetry propagator. M.A.L. Marques, A. Castro, G.F. Bertsch, and A. Rubio, Comput. Phys. Commun., 151 60 (2003).
&propagation propagator='middlepoint' /
propagation='middlepoint'
indicates that Hamiltonian at midpoint of two-times is used.
The default is middlepoint.
&emfield
This namelist specifies the pulse shape of an electric filed applied to the system in time evolution calculations. We explain below separating two cases, #Linear response calculations and #Pulsed electric field calculations.
Linear response calculations
A weak impulsive field is applied at t=0.
For this case, ae_shape1 = 'impulse'
should be described.
Mandatory: ae_shape1
&emfield ae_shape1 = 'impulse' epdir_re1 = 0.d0,0.d0,1.d0 /
epdir_rel(3)
specify a unit vector that indicates the direction of the impulse.
For a periodic system specified by iperiodic = 3
, one may add trans_longi
.
It has the value, 'tr'
(transverse) or 'lo'
(longitudinal), that specifies the treatment of the
polarization in the time evolution calculation. The default is 'tr'
.
&emfield trans_longi = 'tr' ae_shape1 = 'impulse' epdir_re1 = 0.,0.,1. /
The magnitude of the impulse of the pulse may be explicitly specified by, for example, e_impulse = 1d-2
. The default is '1d-2' in atomic unit.
Pulsed electric field calculations
A Pulsed electric field of finite time duration is applied.
For this case, as_shape1
should be specified.
It indicates the shape of the envelope of the pulse.
The options include 'Acos2' and 'Ecos2' (See below for other options).
Mandatory: ae_shape1, epdir_re1, {rlaser_int1 or amplitude1}, omega1, pulse_tw1, phi_cep1
&emfield ae_shape1 = 'Ecos2' epdir_re1 = 0.d0,0.d0,1.d0 rlaser_int_wcm2_1 = 1.d8 omega1=9.28d0 pulse_tw1=6.d0 phi_cep1=0.75d0 /
ae_shape1 = 'Ecos2'
specifies the envelope of the pulsed electric field,
'Ecos2' for the cos^2 envelope for the electric field.
If 'Acos2' is specified, this gives cos^2 envelope for the vector potential.
Note that 'phi_cep1' must be 0.75 (or 0.25) if one employs 'Ecos2' pulse shape, since otherwise the time integral of the electric field does not vanish.
There is no such restriction for the 'Acos2' pulse shape.
epdir_re1 = 0.d0,0.d0,1.d0
specifies the real part of the unit polarization vector of the pulsed electric field.
If only the real part is specified, it describes a linearly polarized pulse.
Using both real ('epdir_re1') and imaginary ('epdir_im1') parts of the polarization vector, circularly (and general ellipsoidary) polarized pulses may be described.
laser_int_wcm2_1 = 1.d8
specifies the maximum intensity of the applied electric field in unit of W/cm^2.
It is also possible to specify the maximum intensity of the pulse by amplitude1
.
omega1=9.26d0
specifies the average photon energy (frequency multiplied with hbar).
pulse_tw1=6.d0
specifies the pulse duration.
Note that it is not the FWHM but a full duration of the cos^2 envelope.
phi_cep1=0.75d0
specifies the carrier envelope phase of the pulse.
As noted above, 'phi_cep1' must be 0.75 (or 0.25) if one employs 'Ecos2' pulse shape, since otherwise the time integral of the electric field does not vanish.
There is no such restriction for the 'Acos2' pulse shape.
It is possible to use two pulses simultaneously to simulate pump-probe experiments, adding information for two pulses.
To specify the second pulse, change from 1 to 2 in the namelist variables, like ae_shape2
.
The time delay between two pulses is specified by the variable 't1_t2'.
For a periodic system specified by iperiodic = 3
, one may add trans_longi
.
It has the value, 'tr'
(transverse) or 'lo'
(longitudinal), that specifies the treatment of the
polarization in the time evolution calculation. The default is 'tr'
.
For a periodic system, it is also specify 'Acos3', 'Acos4', 'Acos6', 'Acos8' for ae_shape1
.
&analysis
Mandatory: none
The following namelists specify whether the output files are created or not after the calculation. In the ground state calculation of isolated systems (Tutorial-1):
&analysis out_psi = 'y' out_dns = 'y' out_dos = 'y' out_pdos = 'y' out_elf = 'y' /
In the time evolution calculation of isolated systems (Tutorial-3):
&analysis out_dns_rt = 'y' out_elf_rt = 'y' out_estatic_rt = 'y' /
In the following namelists, variables related to time-frequency Fourier analysis are specified.
&analysis nenergy=1000 de=0.001 /
nenergy=1000
specifies the number of energy steps, and de=0.001
specifies the energy spacing in the time-frequency Fourier transformation.
&multiscale
This namelist specifies information necessary for Maxwell - TDDFT multiscale calculations.
&multiscale fdtddim = '1D' twod_shape = 'periodic' nx_m = 4 ny_m = 1 hX_m = 250d0 nxvacl_m = -2000 nxvacr_m = 256 /
fdtddim
specifies the spatial dimension of the macro system. fdtddim='1D'
indicates that one-dimensional equation is solved for the macroscopic vector potential.
nx_m = 4
specifies the number of the macroscopic grid points in for x-direction in the spatial region where the material exists.
hx_m = 250d0
specifies the grid spacing of the macroscopic grid in x-direction.
nxvacl_m = -2000
and nxvacr_m = 256
indicate the number of grid points in the vacuum region, nxvacl_m
for the left and nxvacr_m
for the right from the surface of the material.
¶llel
When you execute a job with MPI parallelization, you are not required to specify any parameters that describe the assignment of the parallelization; the assignment is carried out automatically. You may also specify the parameters explicitly as below.
Mandatory: none
¶llel nproc_ob = 1 nproc_domain = 1,1,1 nproc_domain_s = 1,1,1 /
-
nproc_ob
specifies the number of MPI parallelization to divide the electron orbitals. The default value is 0 (automatic parallelization). -
nproc_domain(3)
specifies the number of MPI parallelization to divide the spatial grids of the electron orbitals in three Cartesian directions. The default values are (0/0/0) (automatic parallelization). -
nproc_domain_s(3)'
specifies the number of MPI parallelization to divide the spatial grids related to the electron density in three Cartesian directions. The default values are (0/0/0) (automatic parallelization).
The following conditions must be satisfied.
- The total number of processors must be equal to both
nproc_ob * nproc_domain(1) * nproc_domain(2) * nproc_domain(3)
and alsonproc_domain_s(1) * nproc_domain_s(2) * nproc_domain_s(3)
. -
nproc_domain_s(1)
is a multiple ofnproc_domain(1)
, and the same relations to the second and third components.