Here's a solution based on purely numpy that is also applicable to curves other than Gaussian.

```
def get_intersection_locations(y1,y2,test=False,x=None):
"""
return indices of the intersection point/s.
"""
idxs=np.argwhere(np.diff(np.sign(y1 - y2))).flatten()
if test:
x=range(len(y1)) if x is None else x
plt.figure(figsize=[2.5,2.5])
ax=plt.subplot()
ax.plot(x,y1,color='r',label='line1',alpha=0.5)
ax.plot(x,y2,color='b',label='line2',alpha=0.5)
_=[ax.axvline(x[i],color='k') for i in idxs]
_=[ax.text(x[i],ax.get_ylim()[1],f"{x[i]:1.1f}",ha='center',va='bottom') for i in idxs]
ax.legend(bbox_to_anchor=[1,1])
ax.set(xlabel='x',ylabel='density')
return idxs
```

```
# single intersection
x = np.arange(-10, 10, 0.001)
y1=sc.stats.norm.pdf(x,-2,2)
y2=sc.stats.norm.pdf(x,2,3)
get_intersection_locations(y1=y1,y2=y2,x=x,test=True) # returns indice/s array([10173])
```

```
# double intersection
x = np.arange(-10, 10, 0.001)
y1=sc.stats.norm.pdf(x,-2,1)
y2=sc.stats.norm.pdf(x,2,3)
get_intersection_locations(y1=y1,y2=y2,x=x,test=True)
```

Based on an answer to a similar question.