Yes, it is because you "increase the stack of functions to be called to get the next element, by one after each "iteration" " - i.e. add a new filter on top of stack of filters each time after getting each prime. That's way too many filters.
This means that each produced prime gets tested by all its preceding primes - but only those below its square root are really needed. For instance, to get the 10001-th prime,
104743, there will be 10000 filters created, at run-time. But there are just 66 primes below
323, the square root of
104743, so only 66 filters were really needed. All the 9934 others will be there needlessly, taking up memory, hard at work producing absolutely no added value.
This is the key deficiency of that "functional sieve", which seems to have originated in the 1970s code by David Turner, and later have found its way into the SICP book and other places. It is not that it's a trial division sieve (rather than the sieve of Eratosthenes). That's far too remote a concern for it. Trial division, when optimally implemented, is perfectly capable of producing the 10000th prime very fast.
The key deficiency of that code is that it does not postpone the creation of filters to the right moment, and ends up creating far too many of them.
Talking complexities now, the "old sieve" code is O(n2), in
n primes produced. The optimal trial division is O(n1.5/log0.5(n)), and the sieve of Eratosthenes is O(n*log(n)*log(log(n))). As empirical orders of growth the first is seen typically as
~ n^2, the second as
~ n^1.45 and the third
You can find Python generators-based code for optimal trial division implemented in this answer (2nd half of it). It was originally discussed here dealing with the Haskell equivalent of your sieve function.
Just as an illustration, a "readable pseudocode" :) for the old sieve is
primes = sieve [2..] where
sieve (x:xs) = x : sieve [ y | y <- xs, rem y x > 0 ]
-- list of 'y's, drawn from 'xs',
-- such that (y % x > 0)
and for optimal trial division (TD) sieve, synchronized on primes' squares,
primes = sieve [2..] primes where
sieve (x:xs) ps = x : (h ++ sieve [ y | y <- t, rem y p > 0 ] qs)
(p:qs) = ps -- 'p' is head elt in 'ps', and 'qs' the rest
(h,t) = span (< p*p) xs -- 'h' are elts below p^2 in 'xs'
-- and 't' are the rest
and for a sieve of Eratosthenes, devised by Richard Bird, as seen in that JFP article mentioned in another answer here,
primes = 2 : minus [3..]
(foldr (\p r-> p*p : union [p*p+p, p*p+2*p..] r)  primes)
-- function of 'p' and 'r', that returns
-- a list with p^2 as its head elt, ...
Short and fast. (
minus a b is a list
a with all the elts of
b progressively removed from it;
union a b is a list
a with all the elts of
b progressively added to it without duplicates; both dealing with ordered, non-decreasing lists).
foldr is the right fold of a list. Because it is linear this runs at
~ n^1.33, to make it run at
~ n^1.2 the tree-like folding function
foldi can be used).
The answer to your second question is also a yes. Your second code, re-written in same "pseudocode",
ps = 2 : [i | i <- [3..], all ((> 0).rem i) (takeWhile ((<= i).(^2)) ps)]
is very similar to the optimal TD sieve above - both arrange for each candidate to be tested by all primes below its square root. While the sieve arranges that with a run-time sequence of postponed filters, the latter definition re-fetches the needed primes anew for each candidate. One might be faster than another depending on a compiler, but both are essentially the same.
And the third is also a yes: the sieve of Eratosthenes is better,
ps = 2 : 3 : minus [5,7..] (unionAll [[p*p, p*p+2*p..] | p <- drop 1 ps])
unionAll = foldi union'  -- one possible implementation
union' (x:xs) ys = x : union xs ys
-- unconditionally produce first elt of the 1st arg
-- to avoid run-away access to infinite lists
It looks like it can be implemented in Scala too, judging by the similarity of other code snippets. (Though I don't know Scala).
unionAll here implements tree-like folding structure (click for a picture and full code) but could also be implemented with a sliding array, working segment by segment along the streams of primes' multiples.
TL;DR: yes, yes, and yes.