I'm going to give two slightly indirect answers.
First, consider the following code:
module Lambda where
derivApprox f h x = ( (f (x + h)) - (f x) ) / h
I've compiled this while telling GHC to dump an intermediate representation, which is roughly a simplified version of Haskell used as part of the compilation process, to get this:
:: forall a. GHC.Real.Fractional a => (a -> a) -> a -> a -> a
\ (@ a) ($dFractional :: GHC.Real.Fractional a) ->
$dNum :: GHC.Num.Num a
$dNum = GHC.Real.$p1Fractional @ a $dFractional } in
\ (f :: a -> a) (h :: a) (x :: a) ->
(GHC.Num.- @ a $dNum (f (GHC.Num.+ @ a $dNum x h)) (f x))
If you look past the messy annotations and verbosity, you should be able to see that the compiler has turned everything into lambda expressions. We can consider this an indication that you probably don't need to do so manually.
Conversely, let's consider a situation where you might need lambdas. Here's a function that uses a fold to compose a list of functions:
composeAll :: [a -> a] -> a -> a
composeAll = foldr (.) id
What's that? Not a lambda in sight! In fact, we can go the other way, as well:
composeAll' :: [a -> a] -> a -> a
composeAll' xs x = foldr (\f g x -> f (g x)) id xs x
Not only is this full of lambdas, it's also taking two arguments to the main function and, what's more, applying
foldr to all of them. Compare the type of
(a -> b -> b) -> b -> [a] -> b, to the above; apparently it takes three arguments, but above we've applied it to four! Not to mention that the accumulator function takes two arguments, but we have a three argument lambda here. The trick, of course, is that both are returning a function that takes a single argument; and we're simply applying that argument on the spot, instead of juggling lambdas around.
All of which, hopefully, has convinced you that the two forms are equivalent. Lambda forms are never necessary, or perhaps always necessary, because who can tell the difference?