poisson{ }¶
- Calling sequence
poisson{ }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Dependencies
Exactly one of import_potential{ }, electric_field{ }, between_fermi_levels{ }, and charge_neutral{ } must be specified.
- Functionality
Presence of this group is triggering initialization of the Poisson equation. Calling it is required if Poisson equation is to be solved during a simulation. It gathers keywords controlling initialization of the electrostatic potential, numerical parameters of solvers, and related outputs.
- Examples
poisson{ between_fermi_levels{} }
poisson{ electric_field{...} }
Nested keywords
debuglevel¶
- Calling sequence
poisson{ debuglevel }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{integer}\)
values:
{-1, 0, 1, 2, ...}
default:
1
unit: \(\mathrm{-}\)
- Functionality
The higher this integer number, the more information on the numerical solver is printed to the screen output. Increasing the respective debuglevel to 2 or more significantly increases the volume of the diagnostic output displayed in nextnanomat (or a shell window). As result of the additional I/O load, particularly 1D simulations will slow down correspondingly (especially for
current{ }
andpoisson{ }
)- Example
poisson{ debuglevel = 2 between_fermi_levels{} }
import_potential{ }¶
- Calling sequence
poisson{ import_potential{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Dependencies
The global group import{ } must be present.
- Functionality
Import electrostatic potential from file or analytic function and use it as initial guess for solving the Poisson equation. If no Poisson equation is solved, the imported data determines the electrostatic potential that is used throughout the simulation, i.e. in this case an electrostatic potential can be read in that is fixed during the rest of the simulation and is used as input to the Schrödinger equation and for the calculation of the densities. The solution obtained from a problem solved previously using a different meshing is accepted.
- Example
poisson{ import_potential{...} } import{...}
import_potential{ import_from }¶
- Calling sequence
poisson{ import_potential{ import_from } }
- Properties
usage: \(\mathrm{\textcolor{WildStrawberry}{required\;within\;the\;group}}\)
type: \(\mathrm{character\;string}\)
- Functionality
Reference to imported data in import{ }. The data may have more than one component (e.g. vector field).
- Example
poisson{ import_potential{ import_from = "qpc_landscape" } } import{ file{ name = "qpc_landscape" ... } }
import_potential{ component_number }¶
- Calling sequence
poisson{ import_potential{ component_number } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{integer}\)
values:
{1, 2, 3, 4, ...}
default:
1
unit: \(\mathrm{-}\)
- Functionality
If imported data is a vector field, one may want to specify the component.
- Example
poisson{ import_potential{ import_from = "qpc_landscape" component_number = 2 } } import{ file{ name = "qpc_landscape" ... } }
electric_field{ }¶
- Calling sequence
poisson{ electric_field{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Dependencies
electric_field{ direction } must be defined if simulate2D{ } or simulate3D{ } is already present.
- Functionality
If
electric_field{}
is defined, this value in units of [V] is being added to the electrostatic potential.- Examples
poisson{ electric_field{...} } global{ simulate1D{ } }
poisson{ electric_field{ direction = ... ... } } global{ simulate2D{ } }
electric_field{ direction }¶
- Calling sequence
poisson{ electric_field{ direction } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{vector\;of\;3\;real\;numbers}\)
values: no constraints
default:
[1.0, 0.0, 0.0]
unit: \(\mathrm{-}\)
- Functionality
Orientation of electric field vector with respect to \((x,y,z)\) simulation coordinate system. For 1D simulations, the direction can be omitted and in this case the default will be used.
- Examples
poisson{ electric_field{ direction = [ -1.0, 0.0, 0.0 ] ... } }
poisson{ electric_field{ direction = [ 0.0, 0.5, 0.5 ] ... } } global{ simulate3D{ } }
electric_field{ strength }¶
- Calling sequence
poisson{ electric_field{ strength } }
- Properties
usage: \(\mathrm{\textcolor{WildStrawberry}{required\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
unit: \(\mathrm{V/m}\)
- Functionality
Defines a constant electric field in the structure. If electric_field is defined, and the absolute value is larger than zero, then it is being used for the electrostatic potential calculation.
- Example
poisson{ electric_field{ direction = [ -1.0, 0.0, 0.0 ] strength = 0.42 } }
electric_field{ reference_potential }¶
- Calling sequence
poisson{ electric_field{ reference_potential } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values: no constraints
unit: \(\mathrm{V}\)
- Functionality
Note
If
poisson{ }
group is not called at all, then electric potential \(\phi=0\) is assumed everywhere.- Example
poisson{ electric_field{ direction = [ -1.0, 0.0, 0.0 ] strength = 0.42 reference_potential = -1.3 } }
between_fermi_levels{ }¶
- Calling sequence
poisson{ between_fermi_levels{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
When this group is used then the average value of quasi-Fermi levels is taken as the \(\phi_{i=0}\) at every non-Dirichlet point of the simulation grid. Non-Dirichlet points are the grid points in the regions of the simulation, for which Dirichlet boundary conditions (in this case for potential) are not imposed. The group between_fermi_levels{} is used by default if the poisson{ } group is not specified in the input file at all.
- Example
poisson{ between_fermi_levels{} }
charge_neutral{ }¶
- Calling sequence
poisson{ between_fermi_levels{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
The recommended keyword for specifying \(\phi_{i=0}\) is charge_neutral{}. By using it, \(\phi_{i=0}\) is evaluated by requirement of charge neutrality at every point of the simulation grid. The potential is determined by solving charge neutrality equation with the bisection algorithm.
- Example
poisson{ charge_neutral{} }
newton_solver{ }¶
- Calling sequence
poisson{ newton_solver{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
The Newton solver is used for solving the nonlinear Poisson equation. It is solved with a Newton iteration using inexact line search.The Poisson equation is nonlinear because the charge carrier density \(\rho\) depends on the electrostatic potential \(\phi\), i.e. \(\rho(\phi)\). For each Newton step a system of linear equations, \(A \cdot x = b\), is solved with a linear solver, in order to obtain a gradient. This gradient is used for the inexact line search. Generally, low temperature simulations make the Poisson equation extremely nonlinear at the beginning of the iteration and thus require more line search steps than usual. Using
debuglevel = 2
displays information on the line searchs steps (search_steps): In the .log file of your simulation, you can find more information on the convergence of the Newton solver Parameters for solver of nonlinear poisson equation are as follows:
newton_solver{ iterations }¶
- Calling sequence
poisson{ newton_solver{ iterations } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{integer}\)
values:
{1, 2, 3, 4, ...}
default:
30
unit: \(\mathrm{-}\)
- Functionality
Number of iterations for Newton solver
- Example
poisson{ between_fermi_levels{} newton_solver{} }
newton_solver{ search_steps }¶
- Calling sequence
poisson{ newton_solver{ search_steps } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{integer}\)
values:
{1, 2, 3, ..., 50}
default:
30
unit: \(\mathrm{-}\)
- Functionality
—
- Example
poisson{ between_fermi_levels{} newton_solver{ search_steps = 40 } }
newton_solver{ residual }¶
- Calling sequence
poisson{ newton_solver{ residual } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
[0.0, ...)
default:
1e3
for 1D;1e1
for 2D;1e-4
for 3Dunit: \(\mathrm{cm^{-2}\,}\) (1D) / \(\mathrm{cm^{-1}\,}\) (2D) / \(\mathrm{none\,}\) (3D)
- Functionality
—
- Example
poisson{ between_fermi_levels{} newton_solver{ residual = 1e2 } }
newton_solver{ gradient_shift }¶
- Calling sequence
poisson{ newton_solver{ gradient_shift } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
[-1e-6, 1e-6]
default:
1e-11
unit: \(\mathrm{-}\)
- Functionality
Slightly nudges the gradient in case it is effectively zero
- Example
poisson{ between_fermi_levels{} newton_solver{ residual = -1e-8 } }
linear_solver{ }¶
- Calling sequence
poisson{ linear_solver{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Parameters for linear equation solver in Newton algorithm.
- Example
poisson{ between_fermi_levels{} linear_solver{} }
linear_solver{ iterations }¶
- Calling sequence
poisson{ linear_solver{ iterations } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{integer}\)
values:
{1, 2, 3, 4, ...}
default:
1000
unit: \(\mathrm{-}\)
- Functionality
number of iterations for linear equation solver
- Example
poisson{ between_fermi_levels{} linear_solver{ iterations = 2000 } }
linear_solver{ abs_accuracy }¶
- Calling sequence
poisson{ linear_solver{ abs_accuracy } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
[0.0, ...)
default:
1e1
for 1D;1e-3
for 2D;1e-8
for 3Dunit: \(\mathrm{cm^{-2}\,}\) (1D) / \(\mathrm{cm^{-1}\,}\) (2D) / \(\mathrm{none\,}\) (3D)
- Functionality
—
- Example
poisson{ between_fermi_levels{} linear_solver{ abs_accuracy = 1e-2 } }
linear_solver{ rel_accuracy }¶
- Calling sequence
poisson{ linear_solver{ rel_accuracy } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
[0.0, 1e-2]
default:
1e-13
unit: \(\mathrm{-}\)
- Functionality
—
- Example
poisson{ between_fermi_levels{} linear_solver{ rel_accuracy = 1e-15 } }
linear_solver{ dkr_value }¶
- Calling sequence
poisson{ linear_solver{ dkr_value } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
(..., 0.5]
default:
0.0
unit: \(\mathrm{-}\)
- Functionality
A parameter to speed up calculations, affects preconditioning. Negative values are ignored but will switch to a slightly slower but more stable preconditioner.
- Example
poisson{ between_fermi_levels{} linear_solver{ dkr_value = 0.1 } }
linear_solver{ use_cscg }¶
- Calling sequence
poisson{ linear_solver{ use_cscg } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
Forces the slower but occasionally more robust CSCG (Composite Step Conjugate Gradient) linear solver to be used rather than the cg (Conjugate Gradient) linear solver. May occasionally prevent a diagonalization failure.
- Example
poisson{ between_fermi_levels{} linear_solver{ use_cscg = yes } }
linear_solver{ force_diagonal_preconditioner }¶
- Calling sequence
poisson{ linear_solver{ force_diagonal_preconditioner } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
Forces the use of a slower but more robust diagonal preconditioner. Should be used only for debugging purposes, enabling will make code much slower or prevent convergence. Try setting it to yes in case preconditioning fails or the linear solver diverges. If set to yes, iterations may have to be further increased.
- Example
poisson{ between_fermi_levels{} linear_solver{ force_diagonal_preconditioner = yes } }
linear_solver{ force_iteration }¶
- Calling sequence
poisson{ linear_solver{ force_iteration } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
Only for debugging purposes, enabling will make code much slower or prevent convergence
- Example
poisson{ between_fermi_levels{} linear_solver{ force_iteration = yes } }
bisection{ }¶
- Calling sequence
poisson{ bisection{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Parameters for bisection search. Used for the initial solution of the Poisson equation when
charge_neutral = yes
is set. Bisection is performed in order to achieve local charge neutrality at each grid point:\[\rho = p - n + sum(N_{D,ionized}) - sum(N_{A,ionized}) = 0\]Thus, a true classical charge neutrality is computed for classical carrier and doping situations.
Additionally, bisection is also used to determine the electrostatic potential at which contacts become charge neutral, which is also needed for ohmic contacts and charge-neutral contacts. The bisection for these contacts is performed in any case, i.e. independently to the bisection used when
charge_neutral = yes
is set. The bisection method is a well known algorithm for finding the root of a function. The delta is the so-called convergence tolerance parameter. Specifically in nextnano++ we use this method to find the initial solution of the Poisson equation that generally converges very fast using the default parameters and no extra tuning is required.- Example
poisson{ between_fermi_levels{} bisection{} }
bisection{ delta }¶
- Calling sequence
poisson{ bisection{ delta } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
[0.0, ...)
default:
10.0
unit: \(\mathrm{eV}\)
- Functionality
Range of bisection search.
- Example
poisson{ between_fermi_levels{} bisection{ delta = 7.0 } }
bisection{ residual }¶
- Calling sequence
poisson{ bisection{ residual } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{real\;number}\)
values:
[0.0, ...)
default:
1e3
unit: \(\mathrm{cm^{-3}}\)
- Functionality
—
- Example
poisson{ between_fermi_levels{} bisection{ residual = 1e1 } }
bisection{ iterations }¶
- Calling sequence
poisson{ bisection{ iterations } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{integer}\)
values:
{1, 2, 3, ..., 100}
default:
40
unit: \(\mathrm{-}\)
- Functionality
—
- Example
poisson{ between_fermi_levels{} bisection{ iterations = 60 } }
bisection{ robust }¶
- Calling sequence
poisson{ bisection{ robust } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
When
robust=yes
then a slower charge neutrality algorithm designed to be stable for large band gaps or low temperatures.Note
The bisection algorithm is also used for initializing quasi-Fermi levels in Ohmic and charge-neutral contacts. In this case, the values specified in the input file may become internally modified. -
iterations
is always increased to be at least 40 - residual is reduced to be at most 1e3 cm-3 - robust is always equal yesTherefore, the contact setup ignores bisection definitions which provide lower accuracy than these default settings.
The intrinsic density in GaN at T=300 K is of the order 1e-10 cm^-3, even smaller in AlN. Extremely low carrier densities may be also expected at low temperatures. In such cases the residual needs to be adjusted to obtain reasonable initialization of the contacts.
Attention
Reducing the default value of
residual
may result in significantly longer initialization times, especially in 3D simulations.- Example
poisson{ between_fermi_levels{} bisection{ robust = yes } }
output_potential{ }¶
- Calling sequence
poisson{ output_potential{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Prints out the electrostatic potential in
[eV]
.- Example
poisson{ between_fermi_levels{} output_potential{} }
output_electric_field{ }¶
- Calling sequence
poisson{ output_electric_field{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Prints out the electric field in kv/cm.
- Example
poisson{ between_fermi_levels{} output_electric_field{} }
output_electric_displacement{ }¶
- Calling sequence
poisson{ output_electric_displacement{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Prints out the output electric displacement
- Example
poisson{ between_fermi_levels{} output_electric_displacement{} }
output_electric_polarization{ }¶
- Calling sequence
poisson{ output_electric_polarization{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Prints out the output electric polarization
- Example
poisson{ between_fermi_levels{} output_electric_polarization{} }
output_dielectric_tensor{ }¶
- Calling sequence
poisson{ output_dielectric_tensor{ } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
items: \(\mathrm{maximum\;1}\)
- Functionality
Prints out the output dielectric tensor in simulation coordinate system, as it is used while setting up the sparse matrix for the Poisson solver.
- Example
poisson{ between_fermi_levels{} output_dielectric_tensor{} }
output_dielectric_tensor{ boxes }¶
- Calling sequence
poisson{ output_dielectric_tensor{ boxes } }
- Properties
usage: \(\mathrm{\textcolor{ForestGreen}{optional\;within\;the\;group}}\)
type: \(\mathrm{choice}\)
choices:
yes
;no
default:
no
- Functionality
For each grid point, in 1D two points are printed out to mimic abrupt discontinuities at interfaces (in 2D four points, in 3D eight points)
- Example
poisson{ between_fermi_levels{} output_dielectric_tensor{ boxes = yes } }