To be clear as to why `MemberQ[expr,Complex]`

will not necessarily return `True`

for reals (and may or may not return `True`

for complex expressions). `MemberQ`

is not asking if something is a member of the set of reals or anything like that.

`MemberQ[expr,form]`

returns `True`

if one of the elements of level 1 of `expr`

matches `form`

. Level 1 is what you get second from top if you do `TreeForm`

. Also, by default, `MemberQ`

does not look at heads. Thus:

```
l = List[1 + I];
MemberQ[l, Complex, Heads -> True]
MemberQ[List@l, Complex, Heads -> True]
(*
->
True
False
*)
```

(the `Heads->True`

part is to make `MemberQ`

also look at heads of expressions). To understand why, look at `TreeForm@l`

and `Treeform[List@l]`

:

Thus, there is a `Complex`

at the first level in the first case, and no `Complex`

at level 1 in the second. This is why we get `True`

and `False`

above. One can use

```
MemberQ[List@l, Complex, -1, Heads -> True]
(*
-> True
*)
```

to match on all levels.

Finally, to see that `MemberQ`

really is a structural question, try `MemberQ[1 + Exp[3*I], Complex, Heads -> True]`

which gives `False`

even though the first argument is obviously complex.

So to sum up, `MemberQ`

has little to do with mathematics; it's a construct to test patterns in lists (or any expression, the head does not matter).

In any case, if one is going to use structural tests, `FreeQ`

is the easiest way, while `Element`

is the way to do this with mathematical tests.

`(-1)^(1/3)`

or just explicit`Complex[a, b] == a + I b`

objects which Yoda's answer addresses? – Simon Jun 29 '11 at 22:16