The answer to all performance questions is "benchmark it and find out". Always. So your real-world runtime results are your answer - empirically, that's how it behaves. You can find out the why using something like valgrind's callgrind/cachegrind tools.
Now, I'm going to ignore the fact you talk about hashing - I think you're aware that if the cost of the hash computation is a significant fraction of the cost of running the function body, memoization isn't going to help. So imagine the hash has zero cost for the purposes of the below.
That all said, one of the biggest factors in the performance of CPU-intensive code is the cache hit rate. This is whether your processor, when it looks for information, has to go out to RAM to fetch it; if it's already hot in the cache, the access latency is thousands of times lower and the CPU gets its work done more quickly (I'm simplifying a bit, because not all memory hits cause a pipeline stall, but this is the gist of it).
So, although "using more memory" doesn't directly correlate to a decrease in performance (I mean, the act of using it does, but I'm assuming you're not talking about how much it costs to allocate objects here), when you have a wider swath of RAM in which things you need could lie, the odds of getting a cache hit are lower and that can severely lower the runtime speed of your code.
Memoization is only a win when your function takes a nontrivial amount of time to execute. That's usually the case, but it is a trade-off, and even under ideal circumstances, memoizing ten function calls down to five will never give you the 50% theoretical speed-up.
This counterintuitive behavior ("but Borealid, I'm doing more work, how can it be faster?!") is a prime example of why you should always double-check to see that an "optimization" you put in place actually boosts performance. Premature optimization is the root of all evil.