Long cycles and spectral radii in planar graphs

Abstract

There is a rich history of studying the existence of cycles in planar graphs. The famous Tutte theorem on the Hamilton cycle states that every 4-connected planar graph contains a Hamilton cycle. Later on, Thomassen (1983), Thomas and Yu (1994) and Sanders (1996) respectively proved that every 4-connected planar graph contains a cycle of length n-1, n-2 and n-3. Chen, Fan and Yu (2004) further conjectured that every 4-connected planar graph contains a cycle of length for ∈\n,n-1,…,n-25\ and they verified that ∈ \n-4, n-5, n-6\. When we remove the ``4-connected" condition, how to guarantee the existence of a long cycle in a planar graph? A natural question asks by adding a spectral radius condition: What is the smallest constant C such that for sufficiently large n, every graph G of order n with spectral radius greater than C contains a long cycle in a planar graph? In this paper, we give a stronger answer to the above question. Let G be a planar graph with order n≥ 1.8× 1017 and k≤ 2(n-3)-8 be a non-negative integer, we show that if (G)≥ (K2(Pn-2k-4 2Pk+1)) then G contains a cycle of length for every ∈ \n-k, n-k-1, …, 3\ unless G K2(Pn-2k-4 2Pk+1).

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