Reuction steps:

```
Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx)) = ƛf.( f ( ƛx.f(xx) ƛx.f(xx) ) )
= ƛf.( f ( f (ƛx.f(xx) ƛx.f(xx))))
= ƛf.( f ( f ( f (ƛx.f(xx) ƛx.f(xx))))
= ƛf.( f ( f ( f ( f (ƛx.f(xx) ƛx.f(xx))))) = ...
```

So this Lambda term goes into an infinite loop...

**Explanation:**

Let's look on the term `( ƛx.f(xx) ƛx.f(xx) )`

we substitute `ƛx.f(xx)`

with `f'`

which means `(f' f')`

=> activating the term `f'`

on itself.

It might be easier to look at like this:

`( ƛy.f(yy) ƛx.f(xx) )`

now when you activate the `ƛy.f(yy)`

and provide the input (which substitutes `y`

with `ƛx.f(xx)`

) the outcome is: `f(ƛx.f(xx) ƛx.f(xx))`

which in turn, can go over the same process again and again and the lambda-expression will only expend...

**Remark:**

It's wrong to write:

`Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx))`

it should actually be:
`Y = ƛf.(ƛx.f(xx) ƛx.f(xx))`

The difference between `ƛx.f(xx)`

and `(ƛx.f(xx))`

is that the latter is an activation of `ƛx.f(xx)`

- it's meaningless to activate it like this `(ƛx.f(xx))`

since we need an `x`

(input) to activate it on.

**Finally:**

`Y = ƛf.( ƛx.f(xx)) ( ƛx.f(xx)) = ƛf.( f ( ƛx.f(xx) ƛx.f(xx) ) )`

meaning:

`YF = ( ƛx.F(xx)) ( ƛx.F(xx)) = F(ƛx.F(xx)) ( ƛx.F(xx)) = F(YF)`