A simple Turing machine can add two integers-- *any* two integers. A finite dictionary cannot.

**EDIT:**

(I'm editing my answer because soandos made a point too good to answer in a cramped comment box.)

Good Question! Suppose we have an infinite dictionary, listing {key, value} pairs where the keys are all possible combinations of Turing machines and their finite inputs (or equivalently, all possible finite input sequences to a universal Turing machine), in order of increasing size. The values are the corresponding final states, with a leading bit to indicate [HALTS, DOES NOT HALT]. I argue that this *is* Turing-complete. (The act of looking up an entry is trivially simple and I don't think we have to argue about it).

The unsolvability of the Halting Problem has an equivalent in JSoldi's Dictionary: if we want to be able to look up the [HALT, DOES NOT HALT] bit of any entry below a certain size, we need only a finite part of the dictionary. But to implement that much of the dictionary as a Turing machine, we would need a machine larger than that limiting size-- it's entry would not be in that portion of the dictionary. For any size of machine there is a machine that can answer the Halting Question for all machines of that size-- but *that* machine is bigger, so it can't answer the question about itself. Likewise any finite volume of the dictionary is completely repeated in an entry somewhere (in fact, infinitely many entries), but that entry is not in that volume.