Isomorphic decomposition of complete graphs into linear forests

## Abstract Necessary conditions for the complete graph on __n__ vertices to have a decomposition into 5‐cubes are that 5 divides __n__ − 1 and 80 divides __n__(__n__ − 1)/2. These are known to be sufficient when __n__ is odd. We prove them also sufficient for __n__ even, thus completing the spectr

## Abstract Let __Z__~__p__~ denote the cyclic group of order __p__ where __p__ is a prime number. Let __X__ = __X__(__Z__~__p__~, __H__) denote the Cayley digraph of __Z__~__p__~ with respect to the symbol __H__. We obtain a necessary and sufficient condition on __H__ so that the complete graph on

## Abstract A short proof is given of the impossibility of decomposing the complete graph on __n__ vertices into __n__‐2 or fewer complete bipartite graphs.

## Abstract For all odd integers __n__ ≥ 1, let __G~n~__ denote the complete graph of order __n__, and for all even integers __n__ ≥ 2 let __G~n~__ denote the complete graph of order __n__ with the edges of a 1‐factor removed. It is shown that for all non‐negative integers __h__ and __t__ and all p

We give necessary and sufficient conditions that the complete graph K, has an isomorphic factorization into Kr X K,. We show that this factorization has an application to clone library screening.

## Abstract Graham and Pollak [3] proved that __n__ −1 is the minimum number of edge‐disjoint complete bipartite subgraphs into which the edges of __K__~__n__~ can be decomposed. Using a linear algebraic technique, Tverberg [2] gives a different proof of that result. We apply his technique to show