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Clustered colouring of graph classes with bounded treedepth or pathwidth

Published online by Cambridge University Press:  05 July 2022

Sergey Norin
Affiliation:
Department of Mathematics and Statistics, McGill University, Montréal, Canada. Supported by NSERC grant 418520
Alex Scott
Affiliation:
Mathematical Institute, University of Oxford, Oxford, UK
David R. Wood*
Affiliation:
School of Mathematics, Monash University, Melbourne, Australia. Supported by the Australian Research Council
*
*Corresponding author. Email: [email protected]
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Abstract

The clustered chromatic number of a class of graphs is the minimum integer $k$ such that for some integer $c$ every graph in the class is $k$ -colourable with monochromatic components of size at most $c$ . We determine the clustered chromatic number of any minor-closed class with bounded treedepth, and prove a best possible upper bound on the clustered chromatic number of any minor-closed class with bounded pathwidth. As a consequence, we determine the fractional clustered chromatic number of every minor-closed class.

Type
Paper
Copyright
© The Author(s), 2022. Published by Cambridge University Press

1. Introduction

This paper studies improper vertex colourings of graphs with bounded monochromatic degree or bounded monochromatic component size. This topic has been extensively studied recently [Reference Alon, Ding, Oporowski and Vertigan1Reference Dujmović, Esperet, Morin, Walczak and Wood6, Reference Dvořák and Norin7, Reference Edwards, Kang, Kim, Oum and Seymour8, Reference Esperet and Joret9Reference Mohar, Reed and Wood18, Reference Norin, Scott, Seymour and Wood19Reference van den Heuvel and Wood21]; see [Reference Wood22] for a survey.

A $k$ -colouring of a graph $G$ is a function that assigns one of $k$ colours to each vertex of $G$ . In a coloured graph, a monochromatic component is a connected component of the subgraph induced by all the vertices of one colour.

A colouring has defect $d$ if each monochromatic component has maximum degree at most $d$ . The defective chromatic number of a graph class $\mathcal{G}$ , denoted by $\chi _{\Delta }(\mathcal{G})$ , is the minimum integer $k$ such that, for some integer $d$ , every graph in $\mathcal{G}$ is $k$ -colourable with defect $d$ .

A colouring has clustering $c$ if each monochromatic component has at most $c$ vertices. The clustered chromatic number of a graph class $\mathcal{G}$ , denoted by $\chi _{\star }(\mathcal{G})$ , is the minimum integer $k$ such that, for some integer $c$ , every graph in $\mathcal{G}$ has a $k$ -colouring with clustering $c$ . We shall consider such colourings, where the goal is to minimise the number of colours, without optimising the clustering value.

Every colouring of a graph with clustering $c$ has defect $c-1$ . Thus, $ \chi _{\Delta }(\mathcal{G}) \leqslant \chi _{\star }(\mathcal{G})$ for every class $\mathcal{G}$ .

The following is a well-known and important example in defective and clustered graph colouring. Let $T$ be a rooted tree. The depth of $T$ is the maximum number of vertices on a root–to–leaf path in $T$ . The closure of $T$ is obtained from $T$ by adding an edge between every ancestor and descendant in $T$ . For $h,k\geqslant 1$ , let $C\langle{h,k}\rangle$ be the closure of the complete $k$ -ary tree of depth $h$ , as illustrated in Figure 1.

Figure 1. The standard example $C\langle{4,2}\rangle$ .

It is well known and easily proved (see [Reference Wood22]) that there is no $(h-1)$ -colouring of $C\langle{h,k}\rangle$ with defect $k-1$ , which implies there is no $(h-1)$ -colouring of $C\langle{h,k}\rangle$ with clustering $k$ . This says that if a graph class $\mathcal{G}$ includes $C\langle{h,k}\rangle$ for all $k$ , then the defective chromatic number and the clustered chromatic number are at least $h$ . Put another way, define the tree-closure-number of a graph class $\mathcal{G}$ to be

\begin{equation*}\text {tcn}(\mathcal {G}) \;:\!=\; \min \{ h\;:\; \exists k\, C\langle {h,k}\rangle \not \in \mathcal {G} \} =\max \{ h\;:\; \forall k\, C\langle {h,k}\rangle \in \mathcal {G} \} +1; \end{equation*}

then

\begin{equation*} \chi _{\star }(\mathcal {G}) \geqslant \chi _{\Delta }(\mathcal {G}) \geqslant \text {tcn}(\mathcal {G}) - 1. \end{equation*}

Our main result, Theorem 1 below, establishes a converse result for minor-closed classes with bounded treedepth. First we explain these terms. A graph $H$ is a minor of a graph $G$ if a graph isomorphic to $H$ can be obtained from some subgraph of $G$ by contracting edges. A class of graphs $\mathcal{M}$ is minor-closed if for every graph $G\in \mathcal{M}$ every minor of $G$ is in $\mathcal{M}$ , and $\mathcal{M}$ is proper minor-closed if, in addition, some graph is not in $\mathcal{M}$ . The connected treedepth of a graph $H$ , denoted by $\overline{\rm td}(H)$ , is the minimum depth of a rooted tree $T$ such that $H$ is a subgraph of the closure of $T$ . This definition is a variant of the more commonly used definition of the treedepth of $H$ , denoted by $\text{td}(H)$ , which equals the maximum connected treedepth of the connected components of $H$ . (See [Reference Nešetřil and Ossona de Mendez23] for background on treedepth.) If $H$ is connected, then $\text{td}(H)=\overline{\rm td}(H)$ . In fact, $\text{td}(H)=\overline{\rm td}(H)$ unless $H$ has two connected components $H_1$ and $H_2$ with $\text{td}(H_1)=\text{td}(H_2)=\text{td}(H)$ , in which case $\overline{\rm td}(H)=\text{td}(H)+1$ . It is convenient to work with connected treedepth to avoid this distinction. A class of graphs has bounded treedepth if there exists a constant $c$ such that every graph in the class has treedepth at most $c$ .

Theorem 1. For every minor-closed class $\mathcal{G}$ with bounded treedepth,

\begin{equation*} \chi _{\Delta }(\mathcal {G}) = \chi _{\star }(\mathcal {G}) = \mathrm{tcn}(\mathcal {G}) -1. \end{equation*}

Our second result concerns pathwidth. A path-decomposition of a graph $G$ consists of a sequence $(B_1,\ldots,B_n)$ , where each $B_i$ is a subset of $V(G)$ called a bag, such that for every vertex $v\in V(G)$ , the set $\{i\in [1,n]\;:\; v\in B_i\}$ is an interval, and for every edge $vw\in E(G)$ there is a bag $B_i$ containing both $v$ and $w$ . Here $[a,b]\;:\!=\;\{a,a+1,\ldots,b\}$ . The width of a path decomposition $(B_1,\ldots,B_n)$ is $\max \{|B_i|\;:\; i\in [1,n] \}-1$ . The pathwidth of a graph $G$ is the minimum width of a path-decomposition of $G$ . Note that paths (and more generally caterpillars) have pathwidth 1. A class of graphs has bounded pathwidth if there exists a constant $c$ such that every graph in the class has pathwidth at most $c$ .

Theorem 2. For every minor-closed class $\mathcal{G}$ with bounded pathwidth,

\begin{equation*} \chi _{\Delta }(\mathcal {G}) \leqslant \chi _{\star }(\mathcal {G}) \leqslant 2 \mathrm{tcn}( \mathcal {G} )-2. \end{equation*}

Theorems 1 and 2 are, respectively, proved in Sections 2 and 3. These results are best possible and partially resolve a number of conjectures from the literature, as we now explain.

Ossona de Mendez et al. [Reference Ossona de Mendez, Oum and Wood20] studied the defective chromatic number of minor-closed classes. For a graph $H$ , let $\mathcal{M}_H$ be the class of $H$ -minor-free graphs (that is, not containing $H$ as a minor). Ossona de Mendez et al. [Reference Ossona de Mendez, Oum and Wood20] proved the lower bound, $\chi _{\Delta }(\mathcal{M}_H) \geqslant \overline{\rm td}(H)-1$ and conjectured that equality holds.

Conjecture 3 ([Reference Ossona de Mendez, Oum and Wood20]). For every graph $H$ ,

\begin{equation*} \chi _{\Delta }(\mathcal {M}_H)=\overline {\rm td}(H)-1. \end{equation*}

Conjecture 3 is known to hold in some special cases. Edwards et al. [Reference Edwards, Kang, Kim, Oum and Seymour8] proved it if $H=K_t$ ; that is, $\chi _{\Delta }(\mathcal{M}_{K_t})=t-1$ , which can be thought of as a defective version of Hadwiger’s Conjecture; see [Reference van den Heuvel and Wood21] for an improved bound on the defect in this case. Ossona de Mendez et al. [Reference Ossona de Mendez, Oum and Wood20] proved Conjecture 3 if $\overline{\rm td}(H)\leqslant 3$ or if $H$ is a complete bipartite graph. In particular, $\chi _{\Delta }(\mathcal{M}_{K_{s,t}})=\min \{s,t\}$ .

Norin et al. [Reference Norin, Scott, Seymour and Wood19] studied the clustered chromatic number of minor-closed classes. They showed that for each $k\geqslant 2$ , there is a graph $H$ with treedepth $k$ and connected treedepth $k$ such that $\chi _{\star }(\mathcal{M}_{H}) \geqslant 2k-2$ . Their proof in fact constructs a set $\mathcal{X}$ of graphs in $\mathcal{M}_H$ with bounded pathwidth (at most $2k-3$ to be precise) such that $\chi _{\star }(\mathcal{X}) \geqslant 2k-2$ . Thus, the upper bound on $\chi _{\star }(\mathcal{G})$ in Theorem 2 is best possible.

Norin et al. [Reference Norin, Scott, Seymour and Wood19] conjectured the following converse upper bound (analogous to Conjecture 3):

Conjecture 4 ([Reference Norin, Scott, Seymour and Wood19]). For every graph $H$ ,

\begin{equation*} \chi _{\star }(\mathcal {M}_H)\leqslant 2\overline {\rm td}(H)-2. \end{equation*}

While Conjectures 3 and 4 remain open, Norin et al. [Reference Norin, Scott, Seymour and Wood19] showed in the following theorem that $\chi _{\Delta }(\mathcal{M}_H)$ and $\chi _{\star }(\mathcal{M}_H)$ are controlled by the treedepth of $H$ :

Theorem 5 ([Reference Norin, Scott, Seymour and Wood19]). For every graph $H$ , $\chi _{\star }(\mathcal{M}_H)$ is tied to the (connected) treedepth of $H$ . In particular,

\begin{equation*} \overline {\rm td}(H)-1 \leqslant \chi _{\star }(\mathcal {M}_H) \leqslant 2^{\overline {\rm td}(H)+1}-4. \end{equation*}

Theorem 1 gives a much more precise bound than Theorem 5 under the extra assumption of bounded treedepth.

Our third main result concerns fractional colourings. For real $t \geqslant 1$ , a graph $G$ is fractionally $t$ -colourable with clustering $c$ if there exist $Y_1,Y_2, \ldots, Y_s \subseteq V(G)$ and $\alpha _1,\ldots,\alpha _s \in [0,1]$ such thatFootnote 1 :

  • Every component of $G[Y_i]$ has at most $c$ vertices,

  • $\sum _{i=1}^s \alpha _i \leqslant t$ ,

  • $\sum _{i\,:v \in Y_i}\alpha _i \geqslant 1$ for every $v \in V(G)$ .

The fractional clustered chromatic number $\chi ^f_{\star }(\mathcal{G})$ of a graph class $\mathcal{G}$ is the infimum of $t\gt 0$ such that there exists $c=c(t,\mathcal{G})$ such that every $G \in \mathcal{G}$ is fractionally $t$ -colourable with clustering $c$ .

Fractionally $t$ -colourable with defect $d$ and fractional defective chromatic number $\chi ^f_{\Delta }(\mathcal{G})$ are defined in exactly the same way, except the condition on the component size of $G[Y_i]$ is replaced by “the maximum degree of $G[Y_i]$ is at most $d$ ”.

The following theorem determines the fractional clustered chromatic number and fractional defective chromatic number of any proper minor-closed class.

Theorem 6. For every proper minor-closed class $\mathcal{G}$ ,

\begin{equation*} \chi ^f_{\Delta}{\kern-1pt}(\mathcal {G})= \chi ^f_{\star }(\mathcal {G}) = \mathrm{tcn}(\mathcal {G}) -1. \end{equation*}

This result is proved in Section 4.

We now give an interesting example of Theorem 6.

Corollary 7. For every surface $\Sigma$ , if $\mathcal{G}_\Sigma$ is the class of graphs embeddable in $\Sigma$ , then

\begin{equation*} \chi ^f_{\Delta}{\kern-1pt}(\mathcal {G}_\Sigma )= \chi ^f_{\star }(\mathcal {G}_\Sigma ) = 3. \end{equation*}

Proof. Note that $C\langle{3,k}\rangle$ is planar for all $k$ . Thus, $\text{tcn}(\mathcal{G}_\Sigma )\geqslant 4$ . Say $\Sigma$ has Euler genus $g$ . It follows from Euler’s formula that $K_{3,2g+3}\not \in \mathcal{G}_\Sigma$ . Since $K_{3,2g+3} \subseteq C\langle{4,2g+3}\rangle$ , we have $C\langle{4,2g+3}\rangle \not \in \mathcal{G}_\Sigma$ . Thus, $\text{tcn}(\mathcal{G}_\Sigma )= 4$ . The result follows from Theorem 6.

In contrast to Corollary 7, Dvořák and Norin [Reference Dvořák and Norin7] proved that $\chi _{\star }(\mathcal{G}_\Sigma )=4$ . Note that Archdeacon [Reference Archdeacon2] proved that $\chi _{\Delta }(\mathcal{G}_\Sigma )=3$ ; see [Reference Cowen, Goddard and Jesurum5] for an improved bound on the defect.

2. Treedepth

Say $G$ is a subgraph of the closure of some rooted tree $T$ . For each vertex $v\in V(T)$ , let $T_v$ be the maximal subtree of $T$ rooted at $v$ (consisting of $v$ and all its descendants), and let $G[T_v]$ be the subgraph of $G$ induced by $V(T_v)$ .

The weak closure of a rooted tree $T$ is the graph $G$ with vertex set $V(T)$ , where two vertices $v,w\in V(T)$ are adjacent in $G$ whenever $v$ is a leaf of $T$ and $w$ is an ancestor of $v$ in $T$ . As illustrated in Figure 2, let $W\langle{h,k}\rangle$ be the weak closure of the complete $k$ -ary tree of height $h$ .

Figure 2. The weak closure $W\langle{4,2}\rangle$ .

Note that $W\langle{h,k}\rangle$ is a proper subgraph of $C\langle{h,k}\rangle$ for $h\geqslant 3$ . On the other hand, Norin et al. [Reference Norin, Scott, Seymour and Wood19] showed that $W\langle{h,k}\rangle$ contains $C\langle{h,k-1}\rangle$ as a minor for all $h,k\geqslant 2$ . Therefore, Theorem 1 is an immediate consequence of the following lemma.

Lemma 8. For all $d,k,h\in \mathbb{N}$ there exists $c=c(d,k,h)\in \mathbb{N}$ such that for every graph $G$ with treedepth at most $d$ , either $G$ contains a $W\langle{h,k}\rangle$ -minor or $G$ is $(h-1)$ -colourable with clustering $c$ .

Proof. Throughout this proof, $d$ , $k$ and $h$ are fixed, and we make no attempt to optimise $c$ .

We may assume that $G$ is connected. So $G$ is a subgraph of the closure of some rooted tree of depth at most $d$ . Choose a tree $T$ of depth at most $d$ rooted at some vertex $r$ , such that $G$ is a subgraph of the closure of $T$ , and subject to this, $\sum _{v\in V(T)} \text{dist}_T(v,r)$ is minimal. Suppose that $G[T_v]$ is disconnected for some vertex $v$ in $T$ . Choose such a vertex $v$ at maximum distance from r. Since $G$ is connected, $v\neq r$ . By the choice of $v$ , for each child $w$ of $v$ , the subgraph $G[T_w]$ is connected. Thus, for some child $w$ of $v$ , there is no edge in $G$ joining $v$ and $G[T_w]$ . Let $u$ be the parent of $v$ . Let $T'$ be obtained from $T$ by deleting the edge $vw$ and adding the edge $uw$ , so that $w$ is a child of $u$ in $T'$ . Note that $G$ is a subgraph of the closure of $T'$ (since $v$ has no neighbour in $G[T_w]$ ). Moreover, $\text{dist}_{T'}(x,r) = \text{dist}_T(x,r)-1$ for every vertex $x\in V(T_w)$ , and $\text{dist}_{T'}(y,r) = \text{dist}_T(y,r)$ for every vertex $y\in V(T)\setminus V(T_w)$ . Hence, $\sum _{v\in V(T')} \text{dist}_{T'}(v,r)\lt \sum _{v\in V(T)} \text{dist}_T(v,r)$ , which contradicts our choice of $T$ . Therefore, $G[T_v]$ is connected for every vertex $v$ of $T$ .

Consider each vertex $v\in V(T)$ . Define the level $\ell (v)\;:\!=\; \text{dist}_T(r,v) \in [0,d-1]$ . Let $T^+_v$ be the subtree of $T$ consisting of $T_v$ plus the $vr$ -path in $T$ , and let $G[T^+_v]$ be the subgraph of $G$ induced by $V(T^+_v)$ . For a subtree $X$ of $T$ rooted at vertex $v$ , define the level $\ell (X)\;:\!=\;\ell (v)$ .

A ranked graph (for fixed $d$ ) is a triple $(H,L,\preceq )$ where:

  • $H$ is a graph,

  • $L\;:\;V(H)\rightarrow [0,d-1]$ is a function,

  • $\preceq$ is a partial order on $V(H)$ such that $L(v) \lt L(w)$ whenever $v \prec w$ .

Here and throughout this proof, $v\prec w$ means that $v\preceq w$ and $v\neq w$ . Up to isomorphism, the number of ranked graphs on $n$ vertices is at most $2^{\binom{n}{2}}\,d^n\, 3^{\binom{n}{2}}$ . For a vertex $v$ of $T$ , a ranked graph $(H,L,\preceq )$ is said to be contained in $G[T^+_v]$ if there is an isomorphism $\phi$ from $H$ to some subgraph of $G[T^+_v]$ such that:

  1. (A) for each vertex $v\in V(H)$ we have $L(v)=\ell (\phi (v))$ , and

  2. (B) for all distinct vertices $v,w\in V(H)$ we have that $v\prec w$ if and only if $\phi (v)$ is an ancestor of $\phi (w)$ in $T$ .

Say $(H,L,\preceq )$ is a ranked graph and $i\in [0,d-1]$ . Below we define the $i$ -splice of $(H,L,\preceq )$ to be a particular ranked graph $(H',L',\preceq{\kern-2pt}')$ , which (intuitively speaking) is obtained from $(H,L,\preceq )$ by copying $k$ times the subgraph of $H$ induced by the vertices $v$ with $L(v)\gt i$ . Formally, let

\begin{align*} V(H') \;:\!=\; & \{ (v,0) \;:\; v \in V(H), L(v) \in [0,i] \} \;\cup \\ & \{ (v,j) \;:\; v \in V(H), L(v) \in [i+1,d], j \in [1,k] \}.\\ E(H') \;:\!=\; & \{ (v,0)(w,0) \;:\; vw \in E(H), L(v) \in [0,i], L(w) \in [0,i] \} \;\cup \\ & \{ (v,0)(w,j) \;:\; vw \in E(H), L(v) \in [0,i], L(w) \in [i+1,d], j \in [1,k] \} \; \cup \\ & \{ (v,j)(w,j) \;:\; vw \in E(H), L(v)\in [i+1,d], L(w) \in [i+1,d], j \in [1,k] \}. \end{align*}

Define $L'((v,j)) \;:\!=\; L(v)$ for every vertex $(v,j)\in V(H')$ . Now define the following partial order $\preceq{\kern-2pt}'$ on $V(H')$ :

  • $(v,j)\preceq{\kern-2pt}' (v,j)$ for all $(v,j)\in V(H')$ ;

  • if $v \prec w$ and $L(v),L(w) \in [0,i]$ , then $(v,0) \prec ' (w,0)$ ;

  • if $v \prec w$ and $L(v)\in [0,i]$ and $L(w) \in [i+1,d]$ , then $(v,0) \prec ' (w,j)$ for all $j\in [1,k]$ ; and

  • if $v \prec w$ and $L(v),L(w) \in [i+1,d]$ , then $(v,j) \prec ' (w,j)$ for all $j\in [1,k]$ .

Note that if $(v,a)\prec ' (w,b)$ , then $a\leqslant b$ and $v\prec w$ (implying $(L(v)\lt L(w)$ ). It follows that $\prec '$ is a partial order on $V(H')$ such that $L'((v,a)) \lt L'((w,b))$ whenever $(v,a) \prec ' (w,b)$ . Thus, $(H',L',\preceq{\kern-2pt}')$ is a ranked graph.

For $\ell \in [0,d-1]$ , let

\begin{equation*} N_\ell \;:\!=\; (d+1)(h-1)(k+1)^{d-1-\ell }. \end{equation*}

For each vertex $v$ of $T$ , define the profile of $v$ to be the set of all ranked graphs $(H,L,\preceq )$ contained in $G[T_v^+]$ such that $|V(H)| \leqslant N_{\ell (v)}$ . Note that if $v$ is a descendant of $u$ , then the profile of $v$ is a subset of the profile of $u$ . For $\ell \in [0,d-1]$ , if $N=N_\ell$ then let

\begin{equation*} M_\ell \;:\!=\; 2^{ 2^{\binom {N}{2}}\,d^N\, 3^{\binom {N}{2}} }. \end{equation*}

Then there are at most $M_\ell$ possible profiles of a vertex at level $\ell$ .

We now partition $V(T)$ into subtrees. Each subtree is called a group. (At the end of the proof, vertices in a single group will be assigned the same colour.) We assign vertices to groups in non-increasing order of their distance from the root. Initialise this process by placing each leaf $v$ of $T$ into a singleton group. We now show how to determine the group of a non-leaf vertex. Let $v$ be a vertex not assigned to a group at maximum distance from $r$ . So each child of $v$ is assigned to a group. Let $Y_v$ be the set of children $y$ of $v$ , such that the number of children of $v$ that have the same profile as $y$ is in the range $[1,k-1]$ . If $Y_v =\emptyset$ start a new singleton group $\{v\}$ . If $Y_v\neq \emptyset$ then merge all the groups rooted at vertices in $Y_v$ into one group including $v$ . This defines our partition of $V(T)$ into groups. Each group $X$ is rooted at the vertex in $X$ closest to $r$ in $T$ . A group $Y$ is above a distinct group $X$ if the root of $Y$ is on the path in $T$ from the root of $X$ to $r$ .

The next claim is the key to the remainder of the proof.

Claim 1. Let $uv\in E(T)$ where $u$ is the parent of $v$ , and $u$ is in a different group to $v$ . Then for every ranked graph $(H,L,\preceq )$ in the profile of $v$ , the $\ell (u)$ -splice of $(H,L,\preceq )$ is in the profile of $u$ .

Proof. Since $(H,L,\preceq )$ is in the profile of $v$ , there is an isomorphism $\phi$ from $H$ to some subgraph of $G[T^+_v]$ such that for each vertex $x\in V(H)$ we have $L(x)=\ell (\phi (x))$ , and for all distinct vertices $x,y\in V(H)$ we have that $x\prec y$ if and only if $\phi (x)$ is an ancestor of $\phi (y)$ in $T$ .

Since $u$ and $v$ are in different groups, there are $k$ children $y_1,\ldots,y_k$ of $u$ (one of which is $v$ ) such that the profiles of $y_1,\ldots,y_k$ are equal. Thus, $(H,L,\preceq )$ is in the profile of each of $y_1,\ldots,y_k$ . That is, for each $j\in [1,k]$ , there is an isomorphism $\phi _j$ from $H$ to some subgraph of $G[T^+_{y_j}]$ such that for each vertex $x\in V(H)$ we have $L(x)=\ell (\phi _j(x))$ , and for all distinct vertices $x,y\in V(H)$ we have that $x\prec y$ if and only if $\phi _j(x)$ is an ancestor of $\phi _j(y)$ in $T$ .

Let $(H',L',\preceq{\kern-2pt}')$ be the $\ell (u)$ -splice of $(H,L,\preceq )$ . We now define a function $\phi '$ from $V(H')$ to $V( G[ T^+_u] )$ . For each vertex $(x,0)$ of $H'$ (thus with $x\in V(H)$ and $L(x)\in [0,\ell (u)]$ ), define $\phi '((x,0)) \;:\!=\; \phi (x)$ . For every other vertex $(x,j)$ of $H'$ (thus with $x\in V(H)$ and $L(x)\in [\ell (u)+1,d-1]$ and $j\in [1,k]$ ), define $\phi '((x,j)) \;:\!=\; \phi _j(x)$ .

We now show that $\phi '$ is an isomorphism from $H'$ to a subgraph of $G[T^+_u]$ . Consider an edge $(x,a)(y,b)$ of $H'$ . Thus, $xy\in E(H)$ . It suffices to show that $\phi '((x,a))\phi '((y,b))\in E(G[T^+_u])$ . First suppose that $a=b=0$ . So $L(x)\in [0,\ell (u)]$ and $L(y)\in [0,\ell (u)]$ . Thus $\phi '((x,a))=\phi (x)$ and $\phi '((y,b))=\phi (y)$ . Since $\phi$ is an isomorphism to a subgraph of $G[ T^+_v]$ , we have $\phi (x)\phi (y) \in E(G[ T^+_v] )$ , which is a subgraph of $G[ T^+_u]$ . Hence, $\phi '((x,a))\phi '((y,b)) \in E(G[ T^+_u] )$ , as desired. Now suppose that $a=0$ and $b\in [1,k]$ . Thus, $\phi '((x,a))=\phi (x)$ and $\phi '((y,b))=\phi _b(y)$ . Moreover, both $\ell (\phi (x))$ and $\ell (\phi _b(x))$ equal $L(x)\in [0,\ell (u)]$ . There is only vertex $z$ in $T^+_v$ with $\ell (z)$ equal to a specific number in $[0,\ell (u)]$ . Thus, $\phi '((x,a))=\phi (x)=\phi _b(x)$ ( $=z$ ). Since $\phi _b$ is an isomorphism to a subgraph of $G[ T^+_{y_b}]$ , we have $\phi _b(x)\phi _b(y) \in E(G[ T^+_{y_b}] )$ , which is a subgraph of $G[ T^+_u]$ . Hence, $\phi '((x,a))\phi '((y,b)) \in E(G[ T^+_u] )$ , as desired. Finally, suppose that $a=b\in [1,k]$ . Thus, $\phi '((x,a))=\phi _a(x)$ and $\phi '((y,b))=\phi _b(y)=\phi _a(y)$ . Since $\phi _a$ is an isomorphism to a subgraph of $G[ T^+_{y_a}]$ , we have $\phi _a(x)\phi _a(y) \in E(G[ T^+_{y_a}] )$ , which is a subgraph of $G[ T^+_u]$ . Hence, $\phi '((x,a))\phi '((y,b)) \in E(G[ T^+_u] )$ , as desired. This shows that $\phi '$ is an isomorphism from $H'$ to a subgraph of $G[T^+_u]$ .

We now verify property (A) for $(H',L',\preceq{\kern-2pt}')$ . For each vertex $(x,0)$ of $H'$ (thus with $x\in V(H)$ and $L(x)\in [0,\ell (u)]$ ) we have $L'((x,0))=L(x)= \ell (\phi (x)) = \ell (\phi '((x,0)))$ , as desired. For every other vertex $(x,j)$ of $H'$ (thus with $x\in V(H)$ and $L(x)\in [\ell (u)+1,d-1]$ and $j\in [1,k]$ ) we have $L'((x,j))=L(x)= \ell (\phi _j(x)) = \ell (\phi '((x,j)))$ , as desired. Hence, property (A) is satisfied for $(H',L',\preceq{\kern-2pt}')$ .

We now verify property (B) for $(H',L',\preceq{\kern-2pt}')$ . Consider distinct vertices $(x,a),(y,b)\in V(H')$ . First suppose that $a=0$ and $b=0$ . Then $(x,a) \prec ' (y,b)$ if and only if $x \prec y$ if and only if $\phi (x)$ is an ancestor of $\phi (y)$ in $T$ if and only if $\phi '((x,a))$ is an ancestor of $\phi '((y,b))$ in $T$ , as desired. Now suppose that $a=0$ and $b\in [1,k]$ . Then $(x,a) \prec ' (y,b)$ if and only if $x \prec y$ if and only if $\phi (x)$ is an ancestor of $\phi _b(y)$ in $T$ if and only if $\phi '((x,a))$ is an ancestor of $\phi '((y,b))$ in $T$ , as desired. Now suppose that $a=b\in [1,k]$ . Then $(x,a) \prec ' (y,b)$ if and only if $x \prec y$ if and only if $\phi _a(x)$ is an ancestor of $\phi _b(y)$ in $T$ if and only if $\phi '((x,a))$ is an ancestor of $\phi '((y,b))$ in $T$ , as desired. Finally, suppose that $a,b\in [1,k]$ and $a\neq b$ . Then $(x,a)$ and $(y,b)$ are incomparable under $\prec '$ , and $\phi '((x,a))$ and $\phi '((y,b))$ in $T$ are unrelated in $T$ , as desired. Hence, property (B) is satisfied for $(H',L',\preceq{\kern-2pt}')$ .

So $\phi '$ is an isomorphism from $H'$ to a subgraph of $G[T^+_u]$ satisfying properties (A) and (B). Thus $(H',L',\preceq{\kern-2pt}')$ is contained in $G[T^+_u]$ , as desired. Since $(H,L,\preceq )$ is in the profile of $v$ , we have $|V(H)| \leqslant (d+1)(h-1)(k+1)^{h-\ell (v)}$ . Since $|V(H')|\leqslant (k+1) |V(H)|$ and $\ell (u)=\ell (v)-1$ , we have $|V(H')| \leqslant (d+1)(h-1)(k+1)^{h+1-\ell (v)} = (d+1)(h-1)(k+1)^{h-\ell (u)}$ . Thus, $(H',L',\preceq{\kern-2pt}')$ is in the profile of $u$ .

The proof now divides into two cases. If some group $X_0$ is adjacent in $G$ to at least $h-1$ other groups above $X_0$ , then we show that $G$ contains $W\langle{h,k}\rangle$ as a minor. Otherwise, every group $X$ is adjacent in $G$ to at most $h-2$ other groups above $X$ , in which case we show that $G$ is $(h-1)$ -colourable with bounded clustering.

Finding the minor

Suppose that some group $X_0$ is adjacent in $G$ to at least $h-1$ other groups $X_1,\ldots,X_{h-1}$ above $X_0$ . We now show that $G$ contains $W\langle{h,k}\rangle$ as a minor; refer to Figure 3. For $i\in [1,h-1]$ , since $X_i$ is above $X_0$ , the root $v_i$ of $X_i$ is on the $v_0r$ -path in $T$ . Without loss of generality, $v_0,v_1,\ldots,v_{h-1}$ appear in this order on the $v_0r$ -path in $T$ . For $i\in [1,h-1]$ , let $w_i$ be a vertex in $X_i$ adjacent to some vertex $z_i$ in $X_0$ ; since $G$ is a subgraph of the closure of $T$ , $w_i$ is on the $v_0r$ -path in $T$ . For $i\in [0,h-2]$ , let $u_i$ be the parent of $v_i$ in $T$ (which exists since $v_{h-2}\neq r$ ). So $u_i$ is not in $X_i$ (but may be in $X_{i+1}$ ). Note that $v_0,u_0,w_1,v_1,u_1,\ldots,w_{h-2},v_{h-2},u_{h-2},w_{h-1},v_{h-1}$ appear in this order on the $v_0r$ -path in $T$ , where $v_0,v_1,\ldots,v_{h-1}$ are distinct (since they are in distinct groups).

Let $P_j$ be the $z_jr$ -path in $T$ for $j\in [1,h-1]$ . Let $H_0$ be the graph with $V(H_0)\;:\!=\;V( P_1\cup \ldots \cup P_{h-1} )$ and $E(H_0) \;:\!=\; \{z_jw_j\;:\;j\in [1,h-1]\}$ . Define the function $L_0\;:\;V(H_0)\to [0,d-1]$ by $L_0(x)\;:\!=\;\ell (x)$ for each $x\in V(H_0)$ . Define the partial order $\preceq _0$ on $V(H_0)$ , where $x\prec _0 y$ if and only if $x$ is ancestor of $y$ in $T$ . Thus, $(H_0,L_0,\preceq _0)$ is a ranked graph. By construction, $(H_0,L_0,\preceq _0\!)$ is contained in $G[T^+_{v_0}]$ . Since $H_0$ has less than $(d+1)(h-1)$ vertices, $H_0$ is in the profile of $v_0$ . For $i=0,1,\ldots,h-2$ , let $(H_{i+1},L_{i+1},\prec _{i+1})$ be the $\ell (u_i)$ -splice of $(H_i,L_i,\prec _i\!)$ .

By induction on $i$ , using Claim 1 at each step and since $G[T^+_{u_i}]\subseteq G[T^+_{v_{i+1}}\!]$ , we conclude that for each $i\in [0,h-1]$ , the ranked graph $(H_i,L_i,\preceq _i)$ is in the profile of $v_i$ . In particular, $(H_{h-1},L_{h-1},\prec _{h-1})$ is in the profile of $v_{h-1}$ , and $H_{h-1}$ is isomorphic to a subgraph of $G$ . Note that each vertex of $H_{h-1}$ is of the form $(((\ldots (x,d_1),d_2),\ldots ),d_{h-1})$ for some $x\in V(H_0)$ and $d_1,\ldots,d_{h-1}\in [0,k]$ . For brevity, call such a vertex $x\langle{d_1,\ldots,d_{h-1}\rangle }$ . Note that if $x=w_j$ for some $j\in [1,h-1]$ , then $d_1=\ldots =d_j=0$ (since $w_j$ is above $u_i$ whenever $i\lt j$ , and $(H_{i+1},L_{i+1},\prec _{i+1}\!)$ is the $\ell (u_i)$ -splice of $(H_i,L_i,\preceq _i\!)$ ).

Figure 3. Construction of a $W\langle{4,k}\rangle$ minor (where $u_i$ might be in $X_{i+1}$ ).

For $x\in V(H_0)$ , let $\Lambda _x$ be the set of vertices $x\langle{d_1,\ldots,d_{h-1}\rangle }$ in $H_{h-1}$ . By construction, no two vertices in $\Lambda _x$ are comparable under $\preceq _{h-1}$ . Therefore, by property (B), $V(T_a)\cap V(T_b)=\emptyset$ for all distinct $a,b\in \Lambda _x$ . In particular, $V(T_{a})\cap V(T_b)=\emptyset$ for all distinct $a,b\in \Lambda _{v_0}$ . As proved above, $G[T_a]$ is connected for each $a\in V(T)$ . Let $G'$ be the graph obtained from $G$ by contracting $G[T_a]$ into a single vertex $\alpha{\kern-1pt}\langle{d_1,\ldots,d_{h-1}\rangle }$ , for each $a=v_0\langle{d_1,\ldots,d_{h-1}\rangle } \in \Lambda _{v_0}$ . So $G'$ is a minor of $G$ .

Let $U$ be the tree with vertex set

\begin{equation*} \{\langle { d_1,\ldots,d_{h-1} \rangle }\;:\; \exists j\in [0,h-1] \;d_1=\ldots =d_j=0\text { and }d_{j+1},\ldots,d_{h-1} \in [1,k] \}, \end{equation*}

where the parent of $(0,\ldots,0,d_{j+1},d_{j+2},\ldots,d_{h-1})$ is $(0,\ldots,0,d_{j+2},\ldots,d_{h-1})$ . Then $U$ is isomorphic to the complete $k$ -tree of height $h$ rooted at $\langle 0,\ldots,0\rangle$ . We now show that the weak closure of $U$ is a subgraph of $G$ , where each vertex $\langle 0,\ldots,0,d_{j+1},\ldots,d_{h-1}\rangle$ of $U$ with $j\in [1,h-1]$ is mapped to vertex $w_j\langle 0,\ldots,0,d_{j+1},\ldots,d_{h-1}\rangle$ of $G'$ , and each other vertex $\langle d_1,\ldots,d_{h-1}\rangle$ of $U$ is mapped to $\alpha \langle d_1,\ldots,d_{h-1}\rangle$ of $G'$ . For all $d_1,\ldots,d_{h-1}\in [1,k]$ and $j\in [1,h-1]$ the vertex $z_j\langle{d_1,\ldots,d_{h-1}\rangle }$ of $G$ is contracted into the vertex $\alpha \langle{d_1,\ldots,d_{h-1}\rangle }$ of $G'$ . By construction, $z_j\langle{d_1,\ldots,d_{h-1}\rangle }$ is adjacent to $w_j\langle{0,\ldots,0,d_{j+1},\ldots,d_{h-1}\rangle }$ in $G$ . So $\alpha \langle{d_1,\ldots,d_{h-1}\rangle }$ is adjacent to $w_j\langle{0,\ldots,0,d_{j+1},\ldots,d_{h-1}\rangle }$ in $G'$ . This implies that the weak closure of $U$ (that is, $W\langle{h,k}\rangle$ ) is isomorphic to a subgraph of $G$ ’, and is therefore a minor of $G$ .

Finding the colouring

Now assume that every group $X$ is adjacent in $G$ to at most $h-2$ other groups above $X$ . Then $(h-1)$ -colour the groups in order of distance from the root, such that every group $X$ is assigned a colour different from the colours assigned to the neighbouring groups above $X$ . Assign each vertex within a group the same colour as that assigned to the whole group. This defines an $(h-1)$ -colouring of $G$ .

Consider the function $s\;:\;[0,d-1]\to \mathbb{N}$ recursively defined by

\begin{equation*} s(\ell ) \;:\!=\; \begin {cases} 1 & \text { if }\ell =d-1\\ (k-1) \cdot M_{\ell +1} \cdot s(\ell +1) & \text { if } \ell \in [0,d-2]. \end {cases} \end{equation*}

Then every group at level $\ell$ has at most $s(\ell )$ vertices. By construction, our $(h-1)$ -colouring of $G$ has clustering $s(0)$ , which is bounded by a function of $d$ , $k$ and $h$ , as desired.

3. Pathwidth

The following lemma of independent interest is the key to proving Theorem 2. Note that Eppstein [Reference Eppstein24] independently discovered the same result (with a slightly weaker bound on the path length). The decomposition method in the proof has been previously used, for example, by Dujmović, Joret, Kozik, and Wood [Reference Dujmović, Joret, Kozik and Wood25, Lemma 17].

Lemma 9. Every graph with pathwidth at most $w$ has a vertex 2-colouring such that each monochromatic path has at most $(w+3)^w$ vertices.

Proof. We proceed by induction on $w\geqslant 1$ . Every graph with pathwidth 1 is a caterpillar, and is thus properly 2-colourable. Now assume $w\geqslant 2$ and the result holds for graphs with pathwidth at most $w-1$ . Let $G$ be a graph with pathwidth at most $w$ . Let $(B_1,\ldots,B_n)$ be a path-decomposition of $G$ with width at most $w$ . Let $t_1,t_2,\ldots,t_m$ be a maximal sequence such that $t_1=1$ and for each $i\geqslant 2$ , $t_i$ is the minimum integer such that $B_{t_i} \cap B_{t_{i-1}}=\emptyset$ . For odd $i$ , colour every vertex in $B_{t_i}$ ‘red’. For even $i$ , colour every vertex in $B_{t_i}$ ‘blue’. Since $B_{t_i} \cap B_{t_{i-1}}=\emptyset$ for $i\geqslant 2$ , no vertex is coloured twice. Let $G'$ be the subgraph of $G$ induced by the uncoloured vertices. By the choice of $B_{t_i}$ , for $i\geqslant 2$ each bag $B_j$ with $j\in [t_{i-1}+1,t_i-1]$ intersects $B_{t_{i-1}}$ . Thus, $(B_1\cap V(G'),\ldots,B_n\cap V(G'))$ is a path-decomposition of $G'$ of width at most $w-1$ . By induction, $G'$ has a vertex 2-colouring such that each monochromatic path has at most $(w+3)^{w-1}$ vertices. Since $B_{t_i}\cup B_{t_{i+2}}$ separates $B_{t_i+1}\cup \ldots \cup B_{t_{i+2}-1}$ from the rest of $G$ , each monochromatic component of $G$ is contained in $B_{t_i+1}\cup \ldots \cup B_{t_{i+2}-1}$ for some $i\in [0,n-2]$ . Consider a monochromatic path $P$ in $G[ B_{t_i+1}\cup \ldots \cup B_{t_{i+2}-1} ]$ . Then $P$ has at most $w+1$ vertices in $B_{t_{i+1}}$ . Note that $P- B_{t_{i+1}}$ is contained in $G'$ . Thus, $P$ consists of up to $w+2$ monochromatic subpaths in $G'$ plus $w+1$ vertices in $B_{t_{i+1}}$ . Hence, $P$ has at most $(w+2) (w+3)^{w-1} + (w+1) \lt (w+3)^{w}$ vertices.

Nešetřil and Ossona de Mendez [Reference Nešetřil and Ossona de Mendez23] showed that if a graph $G$ contains no path on $k$ vertices, then $\text{td}(G)\lt k$ (since $G$ is a subgraph of the closure of a DFS spanning tree with height at most $k$ ). Thus Lemma 9 implies:

Corollary 10. Every graph with pathwidth at most $w$ has a vertex 2-colouring such that each monochromatic component has treedepth at most $(w+3)^w$ .

Proof of Theorem 2.Let $\mathcal{G}$ be a minor-closed class of graphs, each with pathwidth at most $w$ . Let $h$ be the minimum integer such that $C\langle{h,k}\rangle \not \in \mathcal{G}$ for some $k\in \mathbb{N}$ . Consider $G\in \mathcal{G}$ . Thus, $W\langle{h,k+1}\rangle$ is not a minor of $G$ (since $C\langle{h,k}\rangle$ is a minor of $W\langle{h,k+1}\rangle$ , as noted above). By Corollary 10, $G$ has a vertex 2-colouring such that each monochromatic component $H$ of $G$ has treedepth at most $(w+3)^w$ . Thus, $W\langle{h,k+1}\rangle$ is not a minor of $H$ . By Lemma 8, $H$ is $(h-1)$ -colourable with clustering $c((w+3)^w,k+1,h)$ . Taking a product colouring, $G$ is $(2h-2)$ -colourable with clustering $c((w+3)^w,k+1,h)$ . Hence, $ \chi _{\Delta }(\mathcal{G}) \leqslant \chi _{\star }(\mathcal{G}) \leqslant 2h-2$ .

Note that Lemma 9 cannot be extended to the setting of bounded tree-width graphs: Esperet and Joret (see [[Reference Liu and Oum14], Theorem 4.1]) proved that for all positive integers $w$ and $d$ there exists a graph $G$ with tree-width at most $w$ such that for every $w$ -colouring of $G$ there exists a monochromatic component of $G$ with diameter greater than $d$ (and thus with a monochromatic path on more than $d$ vertices, and thus with treedepth at least $\log _2 d$ ).

4. Fractional colouring

This section proves Theorem 6. The starting point is the following key result of Dvořák and Sereni [Reference Dvořák and Sereni26].Footnote 2

Theorem 11 ([Reference Dvořák and Sereni26]). For every proper minor-closed class $\mathcal{G}$ and every $\delta \gt 0$ there exists $d \in \mathbb{N}$ satisfying the following. For every $G \in \mathcal{G}$ there exist $s \in \mathbb{N}$ and $X_1,X_2, \ldots, X_s \subseteq V(G)$ such that:

  • $\mathrm{td}(G[X_i]) \leqslant d$ , and

  • every $v \in V(G)$ belongs to at least $(1 - \delta )s$ of these sets.

We now prove a lower bound on the fractional defective chromatic number of the closure of complete trees of given height.

Lemma 12. Let $\mathcal{C}_h \;:\!=\; \{C \langle h,k\rangle \}_{k \in \mathbb{N}}$ . Then $\chi ^f_{\Delta}{\kern-2pt}(\mathcal{C}_h) \geqslant h$ .

Proof. We show by induction on $h$ that if $C \langle h,k\rangle$ is fractionally $t$ -colourable with defect $d$ , then $t\geqslant h - (h-1)d/k$ . This clearly implies the lemma. The base case $h=1$ is trivial.

For the induction step, suppose that $G\;:\!=\;C \langle h,k\rangle$ is fractionally $t$ -colourable with defect $d$ . Thus, there exist $Y_1,Y_2, \ldots, Y_s \subseteq V(G)$ and $\alpha _1,\ldots,\alpha _s \in [0,1]$ such that:

  • every component of $G[Y_i]$ has maximum degree at most $d$ ,

  • $\sum _{i=1}^s \alpha _i \leqslant t$ , and

  • $\sum _{i{\kern1pt}:v \in Y_i}\alpha _i \geqslant 1$ for every $v \in V(G)$ .

Let $r$ be the vertex of $G$ corresponding to the root of the complete $k$ -ary tree and let $H_1,\ldots,H_k$ be the components of $G - r$ . Then each $H_i$ is isomorphic to $C \langle h-1,k\rangle$ . Let $J_0 \;:\!=\; \{j \;:\; r \in Y_j \}$ , and let $J_i \;:\!=\; \{j \;:\; Y_j \cap V(H_i) \neq \emptyset \}$ for $i\in [1,k]$ . Denote $\sum _{j \in J_i} \alpha _j$ by $\alpha (J_i)$ for brevity. Thus, $\alpha (J_0) \geqslant 1$ . For $i\in [1,k]$ , the subgraph $H_i$ is $\alpha (J_i)$ -colourable with defect $d$ , and thus $\alpha (J_i) \geqslant h-1 - (h-2)d/k$ by the induction hypothesis. Thus,

\begin{equation*} (k-d)\alpha (J_0) + \sum _{i=1}^{k}\alpha (J_i) \geqslant (k-d)+k(h-1) - (h-2)d = kh-(h-1)d. \end{equation*}

If $j \in J_0$ then $Y_j$ intersects at most $d$ of $H_1,\ldots,H_k$ (since $G[Y_j]$ has maximum degree at most $d$ ). Thus, every $\alpha _j$ appears with coefficient at most $k$ in the left side of the above inequality, implying

\begin{equation*} (k-d)\alpha (J_0) + \sum _{i=1}^{k}\alpha (J_i) \leqslant k \sum _{i=1}^s \alpha _i \leqslant kt. \end{equation*}

Combining the above inequalities yields the claimed bound on $t$ .

Proof of Theorem 6.By Lemma 12,

\begin{equation*} \chi ^f_{\star }(\mathcal {G}) \geqslant \chi ^f_{\Delta }(\mathcal {G}) \geqslant \text {tcn}(\mathcal {G}) -1. \end{equation*}

It remains to show that $\chi ^f_{\star }(\mathcal{G}) \leqslant \text{tcn}(\mathcal{G}) -1$ . Equivalently, we need to show that for all $h,k \in \mathbb{N}$ and $\varepsilon \gt 0$ , if $C\langle{h,k}\rangle \not \in \mathcal{G}$ then there exists $c$ such that every graph in $\mathcal{G}$ is fractionally $(h-1+\varepsilon )$ -colourable with clustering $c$ . This is trivial for $h=1$ , and so we assume $h \geqslant 2$ .

Let $d \in \mathbb{N}$ satisfy the conclusion of Theorem 11 for the class $\mathcal{G}$ and $\delta = 1 - \frac{1}{1+\varepsilon/(h-1)}$ . Choose $c=c(d,k+1,h)$ to satisfy the conclusion of Lemma 8. We show that $c$ is as desired.

Consider $G \in \mathcal{G}$ . By the choice of $d$ there exists $s \in \mathbb{N}$ and $X_1,X_2, \ldots, X_s \subseteq V(G)$ such that:

  • $\text{td}(G[X_i]) \leqslant d$ , and

  • every $v \in V(G)$ belongs to at least $(1 - \delta )s$ of these sets.

Since $C\langle{h,k}\rangle \not \in \mathcal{G}$ , we have $W\langle{h,k+1}\rangle \not \in \mathcal{G}$ , and by the choice of $c$ , for each $i\in [1,s]$ there exists a partition $(Y^1_i,Y^2_i,\ldots,Y^{h-1}_i)$ of $X_i$ such that every component of $G[Y^j_i]$ has at most $c$ vertices. Every vertex of $G$ belongs to at least $(1 - \delta )s$ sets $Y^{j}_i$ where $i\in [1,s]$ and $j\in [1,h-1]$ . Considering these sets with equal coefficients $\alpha ^{j}_i \;:\!=\; \frac{1}{(1 - \delta )s}$ , we conclude that $G$ is fractionally $\frac{h-1}{1-\delta }$ -colourable with clustering $c$ , as desired (since $\frac{h-1}{1-\delta }=h-1+\varepsilon$ ).

Acknowledgement

This work was partially completed while SN was visiting Monash University supported by a Robert Bartnik Visiting Fellowship. SN thanks the School of Mathematics at Monash University for its hospitality. Thanks to the referee for several helpful comments.

Footnotes

1 If $c=1$ , then this corresponds to a (proper) fractional $t$ -colouring, and if the $\alpha _i$ are integral, then this yields a $t$ -colouring with clustering $c$ .

2 Dvořák and Sereni [Reference Dvořák and Sereni26] expressed their result in the terms of “treedepth fragility”. The sentence “proper minor-closed classes are fractionally treedepth-fragile” after Theorem 31 in [Reference Dvořák and Sereni26] is equivalent to Theorem 11. Informally speaking, Theorem 11 shows that the fractional “treedepth” chromatic number of every minor-closed class equals 1.

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Figure 0

Figure 1. The standard example $C\langle{4,2}\rangle$.

Figure 1

Figure 2. The weak closure $W\langle{4,2}\rangle$.

Figure 2

Figure 3. Construction of a $W\langle{4,k}\rangle$ minor (where $u_i$ might be in $X_{i+1}$).