The third function is very different from the second one, since in it every time you make a withdraw you compute as result value `100 - amount`

(the parameter of the function), while in the second one there is an initial balance, 100, and each time that you make a withdraw, it is detracted from the *current* balance.

```
(define new-withdraw
(let ((balance 100))
(lambda (amount) ;;
(if (>= balance amount)
(begin (set! balance (- balance amount))
balance)
"Insufficient funds"))))
> (new-withdraw 40)
;Value: 60
> (new-withdraw 30)
;Value: 30 ; equal to 60 - 30
(define (new-withdraw-2 amount)
(let ((balance 100))
(if (>= balance amount)
(begin (set! balance (- balance amount))
balance)
"Insufficient funds")))
> (new-withdraw-2 40)
;Value: 60
>(new-withdraw-2 30)
;Value: 70 ; equal to 100 - 30
```

So, `new-withdraw-2`

does not model a bank account, and the function is just an elaborate way of defining `f (x) = 100 - x`

.

Why these two functions differ so much, even if they seems similar at a superficial glance?

The difference is given by the semantics of the `let`

: in the first case, in `new-withdraw`

the `let`

introduces a new variable `balance`

, which establishes a new “environment”, and then return a new function (the inner `lambda`

), for which the variable `balance`

is external. So the returned function, each time that it is called, accesses the *same* variable and decreases its value. The next time it will be called, it will found, through the *same* variable, the value decreased in the previous call.
Objects such as the inner function are called “closures”, as the function and is external environment are strictly connected, with the environment forming a state “hidden” in the function, and persistent between the different calls of the function.

In the second case, instead, the `let`

is inside the function `new-withdraw-2`

: this means that each time the function is called, a *new* variable `balance`

is defined, which establishes a new environment, local to the function, the variabile is initialized to 100, and then it is decreased (with `set!`

). But when the function is terminated, returning the new balance, the local environment of the function is lost, and the next time the function will be called a new environment will be established again, with the variabile `balance`

initialized again to 100.