In Haskell, we can write down almost word for word the mathematical definition of the sieve of Eratosthenes, "primes are natural numbers above 1 without any composite numbers, where composites are found by enumeration of each prime's multiples":
primes = 2 : minus [3..] (foldr (\p r-> p*p : union [p*p+p, p*p+2*p..] r)
primes !! 10000 is near-instantaneous.
The above code is easily tweaked into working on odds only,
primes = 2:3:minus [5,7..] (foldr (\p r -> p*p : union [p*p+2*p, p*p+4*p..] r)  (tail primes)). Time complexity is much improved (to just about a log factor above optimal) by folding in a tree-like structure, and space complexity is drastically improved by multistage primes production, in
primes = 2 : _Y ( (3:) . sieve 5 . _U . map (\p-> [p*p, p*p+2*p..]) )
_Y g = g (_Y g) -- non-sharing fixpoint combinator
_U ((x:xs):t) = x : (union xs . _U . pairs) t -- ~= nub.sort.concat
pairs (xs:ys:t) = union xs ys : pairs t
sieve k s@(x:xs) | k < x = k : sieve (k+2) s -- ~= [k,k+2..]\\s,
| otherwise = sieve (k+2) xs -- when s⊂[k,k+2..]
(In Haskell the parentheses are used for grouping, a function call is signified just by juxtaposition,
(:) is a cons operator for lists, and
(.) is a functional composition operator:
(f . g) x = (\y-> f (g y)) x = f (g x)).