`DSolve`

only gives solutions for "generic" parameters, which is why

```
DSolve[y''[x] + a^2 y[x] == 0 && y'[0] == 0 && y'[1] == 0, y, x]
```

only returns the trivial `{{y -> Function[{x}, 0]}}`

.

If you're considering $-a^2$ to be an eigenvalue of the second derivative operator with the 0 velocity boundary conditions, first solve

```
In[1]:= sol = DSolve[y''[x] + a^2 y[x] == 0, y, x]
Out[1]= {{y -> Function[{x}, C[1] Cos[a x] + C[2] Sin[a x]]}}
```

then enforce the boundary conditions using `Reduce`

(where, to simplify the result, I've also assumed that `a != 0`

and that `sol`

is not trivial)

```
In[2]:= Reduce[y'[0] == 0 && y'[1] == 0 &&
a != 0 && (C[1] != 0 || C[2] != 0) /. sol,
a] // FullSimplify
Out[2]= Element[C[3], Integers] && C[2] == 0 && C[1] != 0 &&
((a == 2*Pi*C[3] && a != 0) || Pi + 2*Pi*C[3] == a)
```

which says that the eigenvectors are proportional to $\cos(a x)$ for $a = 2 n \pi$ or $a = (2 n + 1) \pi$ with $n$ an integer.

As for the second equation in your question, it only makes sense to talk about eigenvectors for linear operators. For nonlinear differential equations, eigenvectors are useful for examining the linearized behaviour around critical points.

`Reduce[y'[0]==0&&y'[1]==0&&a!=0&&(C[1]!=0||C[2]!=0)/.DSolve[y''[x]+ a^2 y[x]==0,y,x],a]//FullSimplify`

. As for the second case, it's not a linear operator acting on $y$... so eigenvalues aren't really appropriate... – Simon Nov 19 '11 at 4:22