Counting Spanning Trees of Threshold Graphs

Cayley's formula states that there are $n^{n-2}$ spanning trees in the complete graph on $n$ vertices; it has been proved in more than a dozen different ways over its 150 year history. The complete graphs are a special case of threshold graphs, and using Merris' Theorem and the Matrix Tree Theorem, there is a strikingly simple formula for counting the number of spanning trees in a threshold graph on $n$ vertices; it is simply the product, over $i=2,3, ...,n-1$, of the number of vertices of degree at least $i$. In this manuscript, we provide a direct combinatorial proof for this formula which does not use the Matrix Tree Theorem; the proof is an extension of Joyal's proof for Cayley's formula. Then we apply this methodology to give a formula for the number of spanning trees in any difference graph.