Colour diversity in spanning structures under Dirac-type conditions

Abstract

Finding spanning structures with many distinct colours in properly edge-coloured graphs is a central theme in extremal combinatorics. A classical result of Andersen shows that every proper edge-colouring of the complete graph Kn contains a Hamilton cycle with n - O(n1/2) distinct colours. In the bipartite setting, the analogous question for perfect matchings is closely related to permutations in Latin squares. In this paper, we investigate how a Dirac-type minimum degree condition forces colour diversity in spanning structures. For every constant 1/2 < c 1, we prove the following. Every properly edge-coloured graph G on n vertices with δ(G) cn contains a Hamilton cycle with at least cn - O(n1/2) distinct colours. Every subset of an n× n Latin square with at least cn cells in each row and each column contains a permutation with at least cn - O(n2/3) distinct symbols. Both bounds are best possible up to the error term.