Writing a recursive function that receives two lists as arguments is no different from implementing a single-argument function: just process each element in turn and advance over both lists, according to the rules of the problem you want to solve. In fact, there isn't anything wrong with the code you posted (assuming both lists have the same length). Here's the result of executing it:

```
(two-list '("1" "2" "3") '("4" "5" "6"))
=> '("14" "25" "36")
```

Perhaps some comments will make it clear:

```
(define two-list ; code 100% equivalent to the one in the question
(lambda (list1 list2) ; here lambda is explicit, it was implicit before
(cond
[(empty? list1) ; if one list is finished then
empty] ; end recursion and return the empty list
[else ; otherwise
(cons (string-append ; cons the result of performing an operation
(first list1) ; over the first list's first element and
(first list2)) ; the second list's first element
(two-list ; finally, advance the recursion
(rest list1) ; over the first list and
(rest list2)))]))) ; over the second list too
```

**UPDATE**

As a proof of concept of what was mentioned in the comments, here's how to implement the same procedure using the Y-Combinator. In this way, we don't need to `define`

anything:

```
(((λ (X) ; Y-Combinator
((λ (proc)
(proc proc))
(λ (proc)
(X (λ (arg1 arg2)
((proc proc) arg1 arg2))))))
(λ (two-list) ; `two-list` procedure it's just a parameter
(λ (list1 list2)
(cond
[(empty? list1) empty]
[else (cons (string-append (first list1) (first list2))
(two-list (rest list1) (rest list2)))]))))
'("1" "2" "3") '("4" "5" "6")) ; here we pass the arguments
=> '("14" "25" "36")
```

alreadyusing`lambda`

, it's just that it's hidden behind a bit of syntactic sugar. I updated my answer with equivalent code to reflect this – Óscar López Jan 22 '14 at 22:50`lambda`

s). Check out the Y-Combinator – Óscar López Jan 22 '14 at 23:12