「$usemunpfunc」：修訂間差異

於 2018年3月26日 (一) 02:21 的修訂

Function for organic material. We usually assume the carrier mobility is depend on electrical field and follow Poole-Frenkel field dependent mobility equation.

Mobility follow this equation

$μ = μ_{0} e x p (β \sqrt{E})$

Where　

$μ_{0}$ is the zero-field mobility
$β$ is the factor of mobility increasing
$E$ is the electric field.

Format

$usemunpfunc
1 μe βe μh βh

Parameter Explanation

 $μ_{n} = μ_{0} e x p (β \sqrt{E})$ ,   $μ_{p} = μ_{0} e x p (β \sqrt{E})$

μe : electron zero-field mobility. $(c m^{2} e V^{- 1} s^{- 1})$
βe : electron beta. $(e V^{- 1 / 2})$
μh : hole zero-field mobility. $(c m^{2} e V^{- 1} s^{- 1})$
βh : hole beta. $(e V^{- 1 / 2})$

$usemunpfunc
11 μe βe μh βh  $v_{n, s a t}$   $v_{p, s a t}$

Parameter Explanation

μe : electron zero-field mobility. $(c m^{2} e V^{- 1} s^{- 1})$
βe : electron beta. $(e V^{- 1 / 2})$
μh : hole zero-field mobility. $(c m^{2} e V^{- 1} s^{- 1})$
βh : hole beta. $(e V^{- 1 / 2})$
$v_{n, s a t}$ saturate electron velocity (cm/s)
$v_{p, s a t}$ saturate hole velocity (cm/s)

  $μ_{n, t e m p} = μ_{0} e x p (β \sqrt{E})$ ,   $μ_{p, t e m p} = μ_{0} e x p (β \sqrt{E})$

 If  $μ_{n, t e m p} \times E > v_{n, s a t}, t h e n μ_{n} = \frac{v_{n, s a t}}{E}$ 
 If  $μ_{p, t e m p} \times E > v_{p, s a t}, t h e n μ_{p} = \frac{v_{p, s a t}}{E}$

@@ 第43行： / 第43行： @@
    <math>\mu_{n,temp}=\mu_0 exp(\beta\sqrt{E})</math>,  <math>\mu_{p,temp}=\mu_0 exp(\beta\sqrt{E})</math>
-   If <math> \mu_{n,temp} \times E > v_{n,sat}, then {\mu_n} = \frac{1\v_{n,sat}}{E} </math>
+   If <math> \mu_{n,temp} \times E > v_{n,sat}, then \mu_n = \frac{v_{n,sat}}{E} </math>
-   If <math> \mu_{n,temp} \times E > v_{n,sat}, then {\mu_n} = \frac{1\v_{n,sat}}{E} </math>
+   If <math> \mu_{p,temp} \times E > v_{p,sat}, then \mu_p = \frac{v_{p,sat}}{E} </math>

「$usemunpfunc」：修訂間差異

於 2018年3月26日 (一) 02:21 的修訂

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