$callexciton

Function for calculate the exciton distribution. We usually use this equation for organic material. Behavior of exciton will follow this equation. You can see the detail in Subroutine_exciton1D.

${\displaystyle \frac{d{n}_{ex}}{dt}=D{\mathrm{\nabla }}^2{n}_{ex}(r)-\frac{n_{ex}(r)}{\tau }-\gamma {n_{ex}(r)}^2+G}$

Where　

• ${\displaystyle D}$ is diffusion coefficient.
• ${\displaystyle \tau }$ is relaxation time of exciton.
• ${\displaystyle \gamma }$ is annihilation rate constant.
• ${\displaystyle G}$ is exciton generation rate.

Format

$callexciton
n
a 4 b c d f
d kr knr gamma g

Parameter Explanation

• n : the number of tables we usually set n as 5.
• a : The type of exciton solver mode

 1: Time-dependent triplet solver 
 123: Time-dependent triplet and singlet solver (For TADF OLEDs model)
 3: Triplet Exciton Solver (For PhOLEDs model)
 6: Singlet and Triplet Exciton Solver (For TADF OLEDs model)
 4: Triplet Exciton Solver with exciton blocking boundary 

• b : Start time (For time-dependent solver)
• c : dt (For time-dependent solver)
• d : End time (For time-dependent solver)
• e : savenum (For time-dependent solver)
• D : diffusion coefficient. ${\displaystyle (c{m}^2{s}^{-1})}$
• kr : radiatvie rate constant ${\displaystyle (s^{-1})}$
• knr :non-radiative rate constant ${\displaystyle (s^{-1})}$
• gamma : quenching coefficient. ${\displaystyle (c{m}^2{s}^{-1})}$
• g : generation rate if you wanna let whole recombination rate change into exciton you should set g as 1.

Example

$callexciton
5
2e-14 20000 3000 1e-12 1
2e-14 20000 3000 1e-12 1
2e-14 20000 3000 1e-12 1
2e-14 20000 3000 1e-12 1
2e-14 20000 3000 1e-12 1

static TTA model (mode 7)

Format

$callexciton
7
711
DS DT krS knrS krT knrT kisc krisc keS khS keT khT kST gammaTS gammaTT a DrefS DrefT ES ET 

Parameter Explanation

Subroutine_exciton1D,