PLaSK User Manual

FreeCarrier2D Class

class gain.freecarrier.FreeCarrier2D(name="")

Quantum-well gain using free-carrier approximation for two-dimensional Cartesian geometry.

Subclasses

Spectrum Gain spectrum object.

Methods

get_energy_levels([T]) Get energy levels in quantum wells.
get_fermi_levels(n[, T, reg]) Get quasi Fermi levels.
initialize() Initialize solver.
invalidate() Set the solver back to uninitialized state.
spectrum(…) Get gain spectrum at given point.

Attributes

Receivers

inCarriersConcentration Receiver of the carriers concentration required for computations [1/cm³].
inTemperature Receiver of the temperature required for computations [K].

Providers

outGain Provider of the computed material gain [1/cm].

Other

T0 Reference temperature.
geometry Geometry provided to the solver
id Id of the solver object.
initialized True if the solver has been initialized.
lifetime Average carriers lifetime.
matrix_element Momentum matrix element.
mesh Mesh provided to the solver
strained Boolean attribute indicating if the solver should consider strain in the active region.

Descriptions

Method Details

FreeCarrier2D.get_energy_levels(T=None)

Get energy levels in quantum wells.

Compute energy levels in quantum wells for electrons, heavy holes and light holes.

Parameters:T (float or None) – Temperature to get the levels. If this argument is None, the estimates for temperature T0 are returned.
Returns:
List with dictionaries with keys el, hh, and lh with levels for
electrons, heavy holes and light holes. Each list element corresponds to one active region.
Return type:list
FreeCarrier2D.get_fermi_levels(n, T=None, reg=0)

Get quasi Fermi levels.

Compute quasi-Fermi levels in specified active region.

Parameters:
  • n (float) – Carriers concentration to determine the levels for [1/cm3].
  • T (float or None) – Temperature to get the levels. If this argument is None, the estimates for temperature T0 are returned.
  • reg (int) – Active region number.
Returns:

Two-element tuple with quasi-Fermi levels for electrons and holes.

Return type:

tuple

FreeCarrier2D.initialize()

Initialize solver.

This method manually initialized the solver and sets initialized to True. Normally calling it is not necessary, as each solver automatically initializes itself when needed.

Returns:solver initialized state prior to this method call.
Return type:bool
FreeCarrier2D.invalidate()

Set the solver back to uninitialized state.

This method frees the memory allocated by the solver and sets initialized to False.

FreeCarrier2D.spectrum(point)
FreeCarrier2D.spectrum(c0, c1)

Get gain spectrum at given point.

Parameters:
  • point (vec) – Point to get gain at.
  • c1 (c0,) – Coordinates of the point to get gain at.
Returns:

Spectrum object.

Return type:

FreeCarrier2D.Spectrum

Receiver Details

FreeCarrier2D.inCarriersConcentration

Receiver of the carriers concentration required for computations [1/cm³].

You will find usage details in the documentation of the receiver class CarriersConcentrationReceiver2D.

Example

Connect the reveiver to a provider from some other solver:

>>> solver.inCarriersConcentration = other_solver.outCarriersConcentration

See also

Receciver class: plask.flow.CarriersConcentrationReceiver2D

Provider class: plask.flow.CarriersConcentrationProvider2D

Data filter: plask.filter.CarriersConcentrationFilter2D

FreeCarrier2D.inTemperature

Receiver of the temperature required for computations [K].

You will find usage details in the documentation of the receiver class TemperatureReceiver2D.

Example

Connect the reveiver to a provider from some other solver:

>>> solver.inTemperature = other_solver.outTemperature

See also

Receciver class: plask.flow.TemperatureReceiver2D

Provider class: plask.flow.TemperatureProvider2D

Data filter: plask.filter.TemperatureFilter2D

Provider Details

FreeCarrier2D.outGain(n=0, mesh, wavelength, interpolation='default')

Provider of the computed material gain [1/cm].

Parameters:
  • deriv (str) – Gain derivative to return. can be ‘’ (empty) or ‘conc’. In the latter case, the gain derivative over carriers concentration is returned.
  • mesh (mesh) – Target mesh to get the field at.
  • interpolation (str) – Requested interpolation method.
  • wavelength (float) – The wavelength at which the gain is computed [nm].
Returns:

Data with the material gain on the specified mesh [1/cm].

You may obtain the number of different values this provider can return by testing its length.

Example

Connect the provider to a receiver in some other solver:

>>> other_solver.inGain = solver.outGain

Obtain the provided field:

>>> solver.outGain(0, mesh, wavelength)
<plask.Data at 0x1234567>

Test the number of provided values:

>>> len(solver.outGain)
3

See also

Provider class: plask.flow.GainProvider2D

Receciver class: plask.flow.GainReceiver2D

Attribute Details

FreeCarrier2D.T0

Reference temperature.

In this temperature levels estimates are computed.

FreeCarrier2D.geometry

Geometry provided to the solver

FreeCarrier2D.id

Id of the solver object. (read only)

Example

>>> mysolver.id
mysolver:category.type
FreeCarrier2D.initialized

True if the solver has been initialized. (read only)

Solvers usually get initialized at the beginning of the computations. You can clean the initialization state and free the memory by calling the invalidate() method.

FreeCarrier2D.lifetime

Average carriers lifetime.

This parameter is used for gain spectrum broadening. (float [ps])

FreeCarrier2D.matrix_element

Momentum matrix element.

Value of the squared matrix element in gain computations. If it is not set it is estimated automatically. (float [eV×m0])

FreeCarrier2D.mesh

Mesh provided to the solver

FreeCarrier2D.strained

Boolean attribute indicating if the solver should consider strain in the active region.

If set to True then there must a layer with the role substrate in the geometry. The strain is computed by comparing the atomic lattice constants of the substrate and the quantum wells.