Here's a way you can do it using append
and map

(define (choose n l)
(cond ((zero? n)
(list null))
((null? l)
null)
(else
(append (map (lambda (comb)
(cons (car l) comb))
(choose ( n 1)
(cdr l)))
(choose n
(cdr l))))))
It provides a valid result for any natural n
, including zero 
(choose 3 '(a b c))
;; '((a b c))
(choose 2 '(a b c))
;; '((a b) (a c) (b c))
(choose 1 '(a b c))
;; '((a) (b) (c))
(choose 0 '(a b c))
;; '(())
It provides a valid result when n
exceeds the size of l
too 
(choose 4 '(a b c))
;; '()
Possible implementations for append
and map

(define (append a b)
(if (null? a)
b
(cons (car a)
(append (cdr a)
b))))
(define (map f l)
(if (null? l)
null
(cons (f (car l))
(map f
(cdr l)))))
If you wish for elements to be repeated, you only need change one expression 
(define (choose n l)
(cond ((zero? n)
(list null))
((null? l)
null)
(else
(append (map (lambda (comb)
(cons (car l) comb))
(choose ( n 1)
l)) ;; change (cdr l) to l
(choose n
(cdr l))))))
The combinations now contain repeated elements 
(choose 3 '(a b c))
;; '((a a a) (a a b) (a a c) (a b b) (a b c) (a c c) (b b b) (b b c) (b c c) (c c c))
(choose 2 '(a b c))
;; '((a a) (a b) (a c) (b b) (b c) (c c))
(choose 1 '(a b c))
;; '((a) (b) (c))
(choose 0 '(a b c))
;; '(())
Notice the significant difference in the scenario where n
exceeds l

(choose 4 '(a b c))
;; '((a a a a)
;; (a a a b)
;; (a a a c)
;; (a a b b)
;; (a a b c)
;; (a a c c)
;; (a b b b)
;; (a b b c)
;; (a b c c)
;; (a c c c)
;; (b b b b)
;; (b b b c)
;; (b b c c)
;; (b c c c)
;; (c c c c))