How does the chromatic number of a random graph vary?

<p>The chromatic number &chi;(G) of a graph G is a fundamental parameter, whose study was originally motivated by applications (&chi;(G) is the minimum number of internally compatible groups the vertices can be divided into, if the edges represent incompatibility). As with other graph parameters, it is also studied from a purely theoretical point of view, and here a key question is: what is its typical value? More precisely, how does &chi;(Gn,1/2), the chromatic number of a graph chosen uniformly at random from all graphs on n vertices, behave?</p> <p>This quantity is a random variable, so one can ask (i) for upper and lower bounds on its typical values, and (ii) for bounds on how much it varies: what is the width (e.g., standard deviation) of its distribution? On (i) there has been considerable progress over the last 45 years; on (ii), which is our focus here, remarkably little. One would like both upper and lower bounds on the width of the distribution, and ideally a description of the (appropriately scaled) limiting distribution. There is a well known upper bound of Shamir and Spencer of order &radic; n, improved slightly by Alon to &radic; n/ log n, but no non-trivial lower bound was known until 2019, when the first author proved that the width is at least n 1/4&minus;o(1) for infinitely many n, answering a longstanding question of Bollob&acute;as.</p> <p>In this paper we have two main aims: first, we shall prove a much stronger lower bound on the width. We shall show unconditionally that, for some values of n, the width is at least n 1/2&minus;o(1), matching the upper bounds up to the error term. Moreover, conditional on a recently announced sharper explicit estimate for the chromatic number, we improve the lower bound to order &radic; n log log n/ log3 n, within a logarithmic factor of the upper bound.</p> <p>Secondly, we will describe a number of conjectures as to what the true behaviour of the variation in &chi;(Gn,1/2) is, and why. The first form of this conjecture arises from recent work of Bollob&acute;as, Heckel, Morris, Panagiotou, Riordan and Smith. We will also give much more detailed conjectures, suggesting that the true width, for the worst case n, matches our lower bound up to a constant factor. These conjectures also predict a Gaussian limiting distribution.</p>