I was playing with the (beautiful) polynomial `x^4 - 10x^2 + 1`

.
Look what happens:

```
In[46]:= f[x_] := x^4 - 10x^2 + 1
a = Sqrt[2];
b = Sqrt[3];
Simplify[f[ a + b]]
Simplify[f[ a - b]]
Simplify[f[-a + b]]
Simplify[f[-a - b]]
Out[49]= 0
Out[50]= 0
Out[51]= 0
Out[52]= 0
In[53]:= Solve[f[x] == 0, x]
Out[53]= {{x->-Sqrt[5-2 Sqrt[6]]},{x->Sqrt[5-2 Sqrt[6]]},{x->-Sqrt[5+2 Sqrt[6]]},{x->Sqrt[5+2 Sqrt[6]]}}
In[54]:= Simplify[Solve[f[x] == 0, x]]
Out[54]= {{x->-Sqrt[5-2 Sqrt[6]]},{x->Sqrt[5-2 Sqrt[6]]},{x->-Sqrt[5+2 Sqrt[6]]},{x->Sqrt[5+2 Sqrt[6]]}}
In[55]:= FullSimplify[Solve[f[x] == 0, x]]
Out[55]= {{x->Sqrt[2]-Sqrt[3]},{x->Sqrt[5-2 Sqrt[6]]},{x->-Sqrt[5+2 Sqrt[6]]},{x->Sqrt[2]+Sqrt[3]}}
```

`Sqrt[5-2 Sqrt[6]]`

is equal to `Sqrt[3]-Sqrt[2]`

.

However, Mathematica's `FullSimplify`

does not simplify `Sqrt[5-2 Sqrt[6]]`

.

**Question: Should I use other more specialized functions to algebraically solve the equation? If so, which one?**

GuideBook for Symbolics: "The meaning of`Automatic`

in the`ComplexityFunction`

option setting is basically to minimize the`LeafCount`

. Some exceptions are made for numbers." For example,`Simplify[Exp[Log[12] + 13 (Sqrt[2] + 1)^2 Log[6] - 2*13 Sqrt[2] Log[6]]]`

isn't an`Integer`

, although`Integer`

s have`LeafCount`

`1`

. – Andrew MacFie Dec 20 '11 at 15:51