The problem with lambda expressions is that they cannot be interpreted as functions in a mathematical sense, i.e. mappings from one set to another.
The reason is the cardinality of the set of functions from a set
A on itself is always larger than the cardinality of
A, so not all functions from
A can be an element of
A. That is, there is a function
f: A -> A for which the expression
f(f) does not make sense.
This is like the "set of all sets not containing itself", which does not make sense logically.
The problem with your example is that
(lambda x.g(x x)) (lambda x.g(x x))
should be equivalent to
g((lambda x.g(x x)) (lambda x.g(x x)))
g is the indicator function of
x x is always
undefined. Hence the first line evaluates to
g (undefined) = 0.
The second line evaluates to
Since for each non-empty set
D there is a function from
D without a fixed point, obviously there can be no model of the lambda calculus. I think it should be even possible to prove that there cannot be an implementation of the Y-combinator in any Turing-complete language.