Update: This answer is assuming that edges are not local minima, as they are not defined as such by the four comparisons in the original problem statement. In this case this answer is correct (it is not possible). If you redefine the question such that edges can be local minima, than every matrix contains at least one local minima - and hence you can use a a divide-and-conquer approach.
If edge cells cannot be local minima:
There is no solution to the question as stated. An N-by-N array takes O(N^2) time just to read the elements. As there could be a single local minimum "hiding" anywhere in the matrix, this is provably necessary to do.
If you meant to ask for an O(N^2) algorithm, than simply walking each element and comparing it to its 4 neighbours takes O(N^2) time.
Either you have misremembered the interview question (and there was more to it), or this is just a trivial coding exercise.
1. Construct a NxN matrix such that each cell has the value M[i,j] = N*i + j.
2. Select a random x,y (1 < x < N and 1 < y < N) and assign M[x,y] = -1
This matrix has exactly one local minima (M[x,y]), and its location is independent of the values in the other cells. Therefore the other cells provide no information about its location, and so it is impossible to have any system to search for it that has better than an expected (N^2/2) cells searched = O(N^2).
(In other words you may as well be searching a near all zero matrix M[i,j] = 0 except for M[x,y] = -1 for the minima.)
This proof depends on being able to construct a matrix with no local minima in step 1. If edge cells are possible local minima than every matrix must have one, and this proof no longer holds.