If by append you mean "add a single element to the end of the list", and you implement that by
xs ++ [x], then yes that's horribly slow for huge lists because each
++ is O(n), making the total O(n^2).
In that case, you can speed this up simply by using cons to add an element to the front of the list instead of the end. That makes the whole process of building the list O(n). Then you can use
reverse to reverse it, which is also O(n), but you only have to do it once, so you're still O(n).
If your processing either isn't affected by the order or can be done in reverse order with slight modifications, you can elide the
reverse anyway. And in that case you can also exploit laziness to only build the elements as you process them, meaning you don't need the whole list in memory, which could potentially speed up your code a bit as well depending on the memory behaviour of your code; if each list element fits in the CPU cache you may get a large speed up this way.
If by append you mean "concatenate a list onto the end of another list", you can do the same thing by using some sort of "reverse prepend" operation, where you cons elements from the new list onto the front of the target list one element at a time; this gives you list concatenation that is linear in the size of each new list rather than the list you're building up, so it's O(n) overall in the total number of elements you process, rather than O(n^2).
Alternatively you could build up a list of lists in reverse order using cons, then process that with some sort of reverse-flatten operation, which should also be O(n).
It's still harder to see how to avoid the reversing completely in this case (multi-element append), unless your final processing is completely order-independent.
Of course, if your need for high performance goes beyond just avoiding super-linear operations, then you may have to look at different data structures altogether than list.