What @gusbro said. Further, you need to rearrange the order of operations and add a couple of additional special cases to deal with lists of differing lengths:
list_sum(  ,  ,  ) .
list_sum(  , [Y|Ys] , [Z|Zs] ) :- Z is 0+Y , list_sum(  , Ys , Zs ) .
list_sum( [X|Xs] ,  , [Z|Zs] ) :- Z is X+0 , list_sum( Xs ,  , Zs ) .
list_sum( [X|Xs] , [Y|Ys] , [Z|Zs] ) :- Z is X+Y , list_sum( Xs , Ys , Zs ) .
You need to move the evaluation (
Z is X+Y) in my example above, so that
Z is evaluated before the recursion. This accomplishes two things:
First, it makes the predicate tail-recursive, meaning the solution is iterative and therefore doesn't consume stack space. In your code, the evaluations aren't performed until after the entire recursion is done. Each intermediate sum is kept on the stack and is evaluated right-to-left on your way back up. This means you'll blow your stack on a large list.
Second, evaluating each result before recursing down means you fail fast. The first sum that doesn't unify with the result fails the entire operation. Your solution fails slow. Consider 10,000,000 item lists where the first item doesn't sum to the first item in the result list: you'll traverse all 10,000,000 items, then — assuming you didn't blow your stack — you start evaluating sums right-to-left. Your predicate won't fail until the very last evalution.