The language L can be recognized by a DFA with n+1 states.

Observe that the length of any string in L is congruent to 0 mod n.

Label n of the states with integers 0, 1, 2, ... n-1, representing each possible remainder. An additional state, S, is the start state. S has a single transition, to state 1. If the machine is currently in state i, on input it moves to state (i+1) mod n. State 0 is
the only accepting state. (If the empty string were part of L, we could eliminate S and make state 0 the start state).

Suppose there were a DFA with fewer than n+1 states that still recognized L. Consider the sequence of states S_{0}, S_{1}, ... S_{n} encountered while processing the string **a**^{n}. S_{n} must be an accepting state, since **a**^{n} is in L. But since there are fewer than n+1 distinct states in this DFA, by the pigeonhole principle there must have been some state that was visited at least twice. Removing that loop gives another path (and another accepted string), with length < n, from S_{0} to S_{n}. But L contains no strings shorter than n, contradicting our assumption. Therefore no DFA with fewer than n+1 states recognizes L.