As suggested in the comments, your question can be phrased as determining the number of unlabeled trees on n vertices. Notice this differs significantly from the question of counting *labeled trees* (of which there are n^{n-2}) or *labeled graphs* (of which there are 2^\binom{n}{2}).

The Online Encyclopedia of Integer Sequences has a lot of good data about this problem (including code to generate the sequence): https://oeis.org/A000055. In particular, it gives a generating function A(x) for these numbers, which is the best solution known to date (from a mathematician's perspective):

A(x) = 1 + T(x) - T^2(x)/2 + T(x^2)/2, where T(x) = x + x^2 + 2x^3 + ...

If you are not familiar with generating functions, think of it as a carefully designed polynomial whose coefficients form the desired sequence. That is, the coefficient of x^n in this polynomial would be the number of unlabeled trees on n vertices.

As a final plug, you may find this reference useful: http://austinmohr.com/work/trees. It gives some counts and images for trees of up to ten vertices.