tl;dr: It's not that dynamic memory allocation is inherently non-deterministic (as you defined it in terms of identical execution paths); it's that it generally makes your program unpredictable. Specifically, you can't predict whether the allocator might fail in the face of an arbitrary sequence of inputs.
You could have a non-deterministic allocator. This is actually common outside of your real-time world, where operating systems use things like address layout randomization. Of course, that would make your program non-deterministic.
But that's not an interesting case, so let's assume a perfectly deterministic allocator: the same sequence of allocations and deallocations will always result in the same blocks in the same locations and those allocations and deallocations will always have a bounded running time.
Now your program can be deterministic: the same set of inputs will lead to exactly the same execution path.
The problem is that if you're allocating and freeing memory in response to inputs, you can't predict whether an allocation will ever fail (and failure is not an option).
First, your program could leak memory. So if it needs to run indefinitely, eventually an allocation will fail.
But even if you can prove there are no leaks, you would need to know that there's never an input sequence that could demand more memory than is available.
But even if you can prove that the program will never need more memory than is available, the allocator might, depending on the sequence of allocations and frees, fragment memory and thus eventually be unable to find a contiguous block to satisfy an allocation, even though there is enough free memory overall.
It's very difficult to prove that there's no sequence of inputs that will lead to pathological fragmentation.
You can design allocators to guarantee there won't be fragmentation (e.g., by allocating blocks of only one size), but that puts a substantial constraint on the caller and possibly increases the amount of memory required due to the waste. And the caller must still prove that there are no leaks and that there's a satiable upper-bound on total memory required regardless of the sequence of inputs. This burden is so high that it's actually simpler to design the system so that it doesn't use dynamic memory allocation.