Consider a differential equation, do be precise, the Polanyi-Wigner equation:

```
dy/dt = - v*(y(t))^n * exp(-E/(kt))/b (*)
```

This equation describes the desorption behavior of particles from a surface. An experimental technique called thermal desorption spectroscopy plots `dy/dt`

thus making it possible to extract kinetic information such as the desorption Energy E, the desorption order `n`

and the pre-exponential factor `v`

from experimental data.
It is oftentimes interesting to look upon the desorption energy E in dependence of dy/dt and y:

```
E(y) = -kt*ln((dy/dt * b)/(v*(y(t))^n)) (**)
```

As we can see, a thermal desorption spectrum which is describable by eq (`*`

) should, when eq (`**`

) is applied, lead to a constant desorption energy `E(y)`

.

Its quite simple to solve eq (`*`

) by applying `odeint`

:

```
def polwig_single(coverage,E,n,v, beta, Tmin,Tmax):
k=8.6173/100000.
def f(y, t):
Si = y[0]
# the Polanyi-Wigner Equation
f0 = -v*np.power(Si,n)*np.exp(-E/(k*t))/beta
return [f0]
S0 = coverage
y0 = [S0]
t = np.linspace(Tmin, Tmax, 10*(Tmax-Tmin))
soln = odeint(f, y0, t)
S = soln[:, 0]
S1=[0 if x<0 else x for x in S]
pw=-np.gradient(S1)
return[S1,pw]
```

However, if I try to solve eq (`**`

) with this definition:

```
def inv_pol_wig(pw,S,n,v,beta,Tmin,Tmax):
t = np.linspace(Tmin, Tmax, 10*(Tmax-Tmin)) # time grid
k=8.6173/100000# Boltzmann constant
list1=[x / y for x,y in zip(pw,S)]
list2=[beta * elem0 for elem0 in list1]
list3=[elem1 / v for elem1 in list2]
list4=[np.log(elem2) for elem2 in list3]
Edes=[-(k * t) * elem3 for t,elem3 in zip(t,list4)]
return[Edes]
```

I run into problems, I only got a constant desorption energy when I assume a too large `v`

(by a factor 10). Do I make some mistake?

--Edit: I have found a small mistake in the code of inv_pol_wig as I forgot to include the desorption order `n`

:

```
def inv_pol_wig(pw,S,n,v,beta,Tmin,Tmax):
t = np.linspace(Tmin, Tmax, 10*(Tmax-Tmin)) # time grid
k=8.6173/100000# Boltzmann constant
list1=[x / np.power(y,n) for x,y in zip(pw,S)]
list2=[beta * elem0 for elem0 in list1]
list3=[elem1 / v for elem1 in list2]
list4=[np.log(elem2) for elem2 in list3]
Edes=[-(k * t) * elem3 for t,elem3 in zip(t,list4)]
return[Edes]
```

Unfortunately, this debug does not fix the problem.

-- Edit Nr. 2: Still no solution, though I made some troubleshooting and changed the polwig_single-function:

```
def polwig_single(coverage,E,n,v, beta, Tmin,Tmax):
k=8.6173/100000.
def f(y, t):
Si = y[0]
# the Polanyi-Wigner Equation
f0 = -v*np.power(Si,n)*np.exp(-E/(k*t))/beta
return [f0]
S0 = coverage
y0 = [S0]
t = np.linspace(Tmin, Tmax, 10*(Tmax-Tmin))
soln = odeint(f, y0, t)
S = soln[:, 0]
S1=S
pw=-np.gradient(S1)
return[S1,pw]
```