Proof. Let $G:=W(T)$, $M:=\rho _1(1\times T)$, $\omega _1:=1_T$, and $D:=G_{\omega _1} = \langle \rho _2(\operatorname {{\mathrm {Aut}}}(T)), \sigma \rangle \cong \operatorname {{\mathrm {Aut}}}(T)\times C_2$. Note that $G=DM$, as $M$ acts transitively on $\Omega$. Let $X:=A\subsetneq \Omega$. Then $\omega _1^{1 \times B} = B < A = \omega _1^{1 \times A}$, and $X^{G}=X^{DM}=\{A^\tau t\mid \tau \in \operatorname {{\mathrm {Aut}}}(T), t\in T\}$. Next, define $\Delta :={\{Y\in X^G\mid Y\cap \omega _1^{1\times A}\neq \varnothing \}}$, and observe that $\Delta = \{A^\tau a\mid \tau \in \operatorname {{\mathrm {Aut}}}(T),\,a\in A\}$. Thus the orbits of $1 \times A$ on $\Delta$ are $\Delta _\tau =\{A^\tau a\mid a\in A\}$ for each $\tau \in \operatorname {{\mathrm {Aut}}}(T)$. Additionally, the stabilizer in $1\times A$ of $A^\tau \in \Delta _\tau$ is $1\times (A\cap A^\tau )$. As $A=B(A\cap A^\tau )$, we observe that $1\times B$ is transitive on $\Delta _\tau$. The result now follows from Theorem 2.2, applied to the groups $G$, $1 \times A$ and $1 \times B$.

Proof. Let $\Sigma$ be the set of right cosets of $A$ in $R$. Then the point stabilizers in the action of $A$ on $\Sigma$ are precisely the subgroups $A \cap A^t$ with $t \in R$. As $B$ is transitive on each orbit in this action, it follows that $A = B(A \cap A^t)$ for all $t \in R$. Hence we are done if $R = \operatorname {{\mathrm {Aut}}}(T)$. Assume therefore that all $\operatorname {{\mathrm {Aut}}}(T)$-conjugates of $A$ are conjugate in $T$. Then for each $\tau \in \operatorname {{\mathrm {Aut}}}(T)$, there exists $t \in T$ such that $A^\tau = A^t$, and so $B(A \cap A^\tau ) = B(A \cap A^t) = A$.

Proof. The set $X:=r^T$ and the multiset $J:=\Omega +s_1^T-s_2^T$ are clearly nontrivial, and (i) implies that $|J| = |\Omega |$. Thus by Definition 2.1, it remains to prove that $\sum _{x \in X^g} \mu _J(x)$ is constant for all $g \in G:=W(T)$. In fact, we will show that $|X^g \cap s_1^T| = |X^g \cap s_2^T|$ for all $g$, and it will follow immediately that $\sum _{x \in X^g} \mu _J(x) = |X|$ for all $g$.

As above, $G_{1_T} = \langle \rho _2(\operatorname {{\mathrm {Aut}}}(T)),\,\sigma \rangle$, and the transitivity of $M:=\rho _1(1 \times T)$ on $\Omega$ implies that $G = G_{1_T}M$. Hence for each $g \in G$, there exist $\tau \in \operatorname {{\mathrm {Aut}}}(T)$, $\varepsilon = \pm 1$ and $t \in T$ such that $X^g = ((r^\tau )^{\varepsilon })^Tt$. Letting $m:=(r^\tau )^\varepsilon$, $i \in \{1,\,2\}$ and $h \in s_i^T$, we observe from [Reference Isaacs16, Problem 3.9] that the set $\{(x,\,y) \mid x \in m^T,\, y \in t^T,\, xy = h\}$ has size

\[ a_{g,i}:=\frac{|m^T||t^T|}{|T|}\sum_{\chi \in \mathrm{Irr}(T)}\frac{\chi(m)\chi(t)\overline{\chi(s_i)}}{\chi(1)}, \]

where $\overline {\chi (s_i)}$ is the complex conjugate of $\chi (s_i)$. Since $a_{g,i}$ is constant for all $h \in s_i^T$, and $|m^Tt^u \cap s_i^T|$ is constant for all $u \in T$, it follows that $|X^g \cap s_i^T| = a_{g,i}|s_i^T|/|t^T|$. As $\chi ((r^\tau )^{-1})\,{=}\, \overline {\chi (r^\tau )}$ for each character $\chi$ of $T$, (i) and (ii) yield $|X^g \,{\cap}\, s_1^T| \,{=}\, |X^g \,{\cap}\, s_2^T|$ for all $g \in G$, as required.

Proof. Let $p$ be the prime dividing $q$, and let $U$ be a Sylow $p$-subgroup of $T$. Then $T$ contains a subgroup $N$ such that $A:=N_T(U)$ and $N$ form a $(B,\,N)$-pair, and the normal subgroup $H:=A \cap N$ of $N$ complements $U$ in $A$ (see [Reference Carter12, Ch. 7.2–9.4]). Since $q \ge 3$ (and since $T$ is not the soluble group $A_1(3) = \operatorname {{\mathrm {PSL}}}_2(3)$), we observe from [Reference Carter12, pp. 121–122] that $|H| > 1$, and so $U$ is a proper subgroup of $A$. Furthermore, as $A$ is the normalizer in $T$ of the Sylow subgroup $U$, all $\operatorname {{\mathrm {Aut}}}(T)$-conjugates of $A$ are conjugate in $T$.

By Lemma 2.4, it suffices to show that $A$ and $U$ have the same orbits in the action of $T$ on the set of right cosets of $A$. For each element $w$ of the Weyl group $W:=N/H$, fix a preimage $n_w \in N$ of $w$ under the natural homomorphism from $N$ to $W$. In addition, let $x$ and $y$ be elements of $T$ so that $Ax$ and $Ay$ lie in a common $A$-orbit. Then the double cosets $AxA$ and $AyA$ are equal. By [Reference Carter12, Theorem 8.4.3], there exist $a_x,\,a_y \in A$, $w_x,\,w_y \in W$ and $u_x,\,u_y \in U < A$ such that $x = a_x n_{w_x} u_x$ and $y = a_y n_{w_y} u_y$. It follows that $A n_{w_x} A = A n_{w_y} A$. As $A$ and $N$ form a $(B,\,N)$-pair, [Reference Carter12, Proposition 8.2.3] yields $n_{w_x} = n_{w_y}$. Thus $AxU = An_{w_x}U = An_{w_y}U = AyU$, i.e. $Ax$ and $Ay$ lie in the same $U$-orbit, as required.

Proof. Note that $T \not \cong {}^2F_4(2)'$. As above, let $p$ be the prime dividing $q$, and let $U$ be a Sylow $p$-subgroup of $T$. By [Reference Carter12, Ch. 13–14], $T$ contains subgroups $N$, $H$ and $W$ analogous to those in the proof of Proposition 3.1, so that $A:=U \mkern 3mu{:}\mkern 3mu H$ and $N$ form a $(B,\,N)$-pair, and $W = N/H$. Furthermore, $H$ is nontrivial for all $q$, as $T$ is not isomorphic to ${}^2A_2(2) = \operatorname {{\mathrm {PSU}}}_3(2)$, ${}^2B_2(2) = \mathrm {Sz}(2)$ or ${}^2F_4(2)$. Although [Reference Carter12] directly states only that $A \le N_T(U)$, we can show that $A = N_T(U)$. Indeed, if this were not the case, then some preimage $n_w \in N$ of a fundamental reflection $w \in W$ would normalise $U$ (see [Reference Carter12, Proposition 8.2.2 & Theorem 8.3.2]). However, we deduce from Proposition 13.6.1 and the proof of Theorem 13.5.4 in [Reference Carter12] that no such $w$ exists, and so $A = N_T(U)$. We now proceed exactly as in the proof of Proposition 3.1, this time using Proposition 13.5.3 of [Reference Carter12] instead of Theorem 8.4.3.

Proof. Since $A_2(2) = \operatorname {{\mathrm {PSL}}}_3(2) \cong \operatorname {{\mathrm {PSL}}}_2(7)$ is addressed by Proposition 3.1, and since the remaining groups $X_\ell (2)$ with $\ell \le 2$ are not simple, we shall assume that $\ell \ge 3$. Let $\Phi \subseteq \mathbb {R}^\ell$ be a root system for $T$, with $\Phi ^+ \subseteq \Phi$ a system of positive roots and $\Pi \subseteq \Phi ^+$ a system of simple roots (see, for example, [Reference Carter12, Ch. 2]). Then $\Phi$ is the disjoint union of $\Phi ^+$ and $-\Phi ^+$, and each node in the Dynkin diagram $D$ corresponding to $T$ is associated with a unique root in $\Pi$ (and vice versa). Hence each diagram automorphism of $D$ induces a permutation of $\Pi$. Let $r$ and $s$ be the simple roots associated with a leaf in $D$ and the adjacent node, respectively. Additionally, let $S$ be the closure of the set $\{s\}$ under the group of diagram automorphisms of $D$, so that $|S| \in \{1,\,2\}$.

Next, let $U$, $N$ and $W$ be as in the proof of Proposition 3.1. In this case, the group $H$ from that proof is trivial, and so $N_T(U) = U$ and $W \cong N$. By [Reference Carter12, Proposition 2.1.8, p. 68 & p. 93], $T$ is generated by a set $\{x_u \mid u \in \Phi \}$ of involutions ($x_u$ is written as $x_u(1)$ in [Reference Carter12]), with $U = \langle x_u \mid u \in \Phi ^+ \rangle$, and $N$ is generated by a set $\{n_v \mid v \in \Pi \}$ of involutions. Let $A := \langle U,\, n_v \mid v \in \Pi \setminus S\rangle$ be the parabolic subgroup of $T$ corresponding to the subset $\Pi \setminus S$ of $\Pi$. Then by [Reference Carter12, Ch. 8.5] and the well-known structure of parabolic subgroups of Chevalley groups, $A$ has shape $[2^m]:(L_{\{r\}} \times L_{\Pi \setminus (\{r\} \cup S)})$ for some positive integer $m$, where $L_{\{r\}} \cong A_1(2) \cong S_3$ and $L_{\Pi \setminus (\{r\} \cup S)}$ are Levi subgroups. Since $q = 2$, all automorphisms of $T$ are products of inner and graph automorphisms. Moreover, $\Pi \setminus S$ is fixed setwise by all diagram automorphisms of $D$, which correspond to the graph automorphisms of $T$, and so all $\operatorname {{\mathrm {Aut}}}(T)$-conjugates of $A$ are conjugate in $T$. In addition, $A$ contains an index two subgroup $B$ of shape $[2^m]:(F \times L_{\Pi \setminus (\{r\} \cup S)})$, where $F := L_{\{r\}}' \cong C_3$. We will show that $AtA = AtB$ for all $t \in T$, and the result will follow from Lemma 2.4.

Since $N_T(U) = U \le A$, we deduce as in the proof of Proposition 3.1 that, for each $t \in T$, there exists $n \in N$ such that $AtA = AnA$. Thus it suffices to prove that $AnA = AnB$ for all $n \in N$ (it will immediately follow that $AnB = AtB$ for the corresponding $t \in T$). We also observe using [Reference Carter12, Ch. 8.5] (and the fact that $F$ has index two in $L_{\{r\}}$) that $x_r \in A \setminus B$ and $x_{-r} x_r \in B$. The former containment implies that $AnA = AnB \cup Anx_rB$. To complete the proof, we will show that $Anx_rB = AnB$.

The Weyl group $W$ acts linearly on $\mathbb {R}^\ell$ and fixes $\Phi$. Let $w$ be the element of $W$ corresponding to $n$. By [Reference Carter12, Lemma 7.2.1(i)], $nx_r = x_{w(r)} n$ and $x_{-w(r)} n = x_{w(-r)} n = nx_{-r}$. If $w(r) \in \Phi ^+$, then $x_{w(r)} \in \langle x_u \mid u \in \Phi ^+ \rangle = U \le A$, and so $Anx_r = An$. Otherwise, $-w(r) \in \Phi ^+$ and $x_{-w(r)} \in A$, yielding $An = An x_{-r}$ and hence $Anx_r = An x_{-r} x_r$, which lies in $AnB$ by the previous paragraph. In either case, we see that $Anx_rB = AnB$, as required.

Proof. Since $A_5 \cong \operatorname {{\mathrm {PSL}}}_2(4) = A_1(4)$ and $A_6 \cong \operatorname {{\mathrm {PSL}}}_2(9) = A_1(9)$ are addressed by Proposition 3.1, we shall assume that $n \ge 7$. Let $\Sigma$ be the set of $3$-subsets of a set of size $n$, and let $\alpha \in \Sigma$. Then $A:=T_\alpha =(S_3\times S_{n-3})\cap T$, and all $\operatorname {{\mathrm {Aut}}}(T)$-conjugates of $A$ are conjugate in $T$. Additionally, $A$ has four orbits on $\Sigma$, namely $\{\alpha \}$ and $\{\beta \in \Sigma \mid |\beta \cap \alpha |=i\}$ for $i \in \{0,\,1,\,2\}$. Since the index two subgroup $B:=A_3 \times A_{n-3}$ of $A$ acts transitively on each of these orbits, and since the action of $T$ on $\Sigma$ is equivalent to its action on the right cosets of $A$, the result follows from Lemma 2.4.

Proof. We observe from the Atlas [Reference Conway, Curtis, Norton, Parker and Wilson13] that $T$ has a maximal subgroup $A$, as specified in Table 1, such that either $T = \mathrm {O'N}$ or all $\operatorname {{\mathrm {Aut}}}(T)$-conjugates of $T_\alpha$ are conjugate in $T$. It is also clear that the group $B$ in the table is a proper normal subgroup of $A$. Note that if $T = \mathrm {M}_{12}$, then $A$ has two normal subgroups isomorphic to $S_5$; in what follows, $B$ may be chosen as either.

Table 1. A maximal subgroup $A$ of a group $T$ from Proposition 3.5, with $B$ a proper normal subgroup of $A$

.

Now, let $R:=\operatorname {{\mathrm {Aut}}}(T)$ if $T = \mathrm {O'N}$, and $R:=T$ otherwise. Additionally, let $\chi$ be the permutation character corresponding to the action of $R$ on the set $\Sigma$ of right cosets of $A$ in $R$. Then for each $t \in R$, the number of points in $\Sigma$ fixed by $t$ is equal to $\chi (t)$. By the Cauchy–Frobenius Lemma, $A$ and $B$ have $c_A:={1}/{|A|}\sum _{a \in A} \chi (a)$ and $c_B:={1}/{|B|}\sum _{b \in B} \chi (b)$ orbits on $\Sigma$, respectively. It is straightforward to compute $c_A$ and $c_B$ in GAP [15] using the Character Table Library [Reference Breuer9] ($c_A$ is most readily calculated as the inner product $[\chi,\,\chi ]$), and in each case we obtain $c_A = c_B$. Thus Lemma 2.4 yields the result.

Proof of Theorem 1.3 Propositions 3.1–3.5 show that (iii) implies (i), which clearly implies (ii). To complete the proof, we will show that if (iii) does not hold, then neither does (ii). If $T \in \{\mathrm {J}_1,\, \mathrm {M}_{22},\, \mathrm {J}_3,\, \mathrm {McL}\}$, then we construct $T$ in Magma [Reference Bosma, Cannon and Playoust7] via the AutomorphismGroupSimpleGroup and Socle functions, and show that (ii) does not hold via fast, direct computations.

Suppose next that $T = \mathrm {Th}$, let $C$ be a proper subgroup of $T$, and let $A$ be a subgroup of $C$. Observe that if $b(T,\,C) = 2$, then (as discussed below the statement of Theorem 1.3) the two-point stabilizer $C \cap C^t$ is trivial for some $t$. Hence $A \,{\cap}\, A^t \,{=}\, 1$, and so $A$ does not satisfy (ii). In general, $b(T,\,A) \le b(T,\,C)$. By [Reference Burness, O'Brien and Wilson11, Theorem 1], $T$ has only two maximal subgroups (up to conjugacy) with corresponding base size greater than two, namely $M_1:={}^3D_4(2) \mkern 3mu{:}\mkern 3mu 3$ and $M_2:=2^5.\operatorname {{\mathrm {PSL}}}_5(2)$, and $b(T,\,M_1) = b(T,\,M_2) = 3$. Hence any proper subgroup $A$ of $T$ satisfying (ii) is a non-simple subgroup of $M_1$ or $M_2$ with $b(T,\,A) = 3$.

Now, let $\Sigma$ be the set of right cosets in $T$ of a proper subgroup $A$, and let $c$ be the number of orbits of $A$ on $\Sigma$. If $b(T,\,A) \ge 3$, then $|A \cap A^t| \ge 2$ for all $t \in T$, and it follows from the Orbit-Stabiliser Theorem that $c|A|/2 \ge |\Sigma |$. If $A$ is a maximal subgroup of either $M_1$ or $M_1' \cong {}^3D_4(2)$, then the character table of $A$ is included in The GAP Character Table Library. Thus for every such $A \ne M_1'$, we can compute $c$ as in the proof of Proposition 3.5, and we see that in fact $c|A|/2 < |\Sigma |$, and hence $b(T,\,A) = 2$. To show that $b(T,\,A) = 2$ for each maximal subgroup $A$ of $M_2$, we construct $T$ and $M_2$ in Magma as subgroups of $\operatorname {{\mathrm {GL}}}_{248}(2)$ using the respective generating pairs $\{x,\,y\}$ and $\{w_1,\,w_2\}$ given in [Reference Wilson, Walsh, Tripp, Suleiman, Parker, Norton, Nickerson, Linton, Bray and Abbott19]. Magma calculations (with a runtime of less than 10 minutes and a memory usage of 1.5 GB) then show that $A \cap A^y = 1$ for all representatives $A$ of the conjugacy classes of maximal subgroups of $M_2$ returned by the MaximalSubgroups function. Therefore, $M_1$ and $M_2$ are the only non-simple subgroups of $T$ with corresponding base size at least three. Further character table computations in GAP show that if $A \in \{M_1,\,M_2\}$, then for each proper normal subgroup $B$ of $A$, the number of $B$-orbits on $\Sigma$ is greater than the number of $A$-orbits. An additional application of the Orbit-Stabiliser Theorem yields $B(A \cap A^t) < A$ for some $t \in T$. Therefore, (ii) does not hold.

Finally, suppose that $T = \mathbb {M}$. As above, any proper subgroup $A$ of $T$ satisfying (ii) also satisfies $b(T,\,A) \ge 3$. By [Reference Burness10, Theorem 3.1], the unique (up to conjugacy) proper subgroup $A$ of $T$ with $b(T,\,A) \ge 3$ is the maximal subgroup $K:=2.\mathbb {B}$, with $b(T,\,K) = 3$. Since $K$ is quasisimple, its centre $Z$ of order two is its unique nontrivial proper normal subgroup, and $Z$ lies in each maximal subgroup of $K$. Hence $Z(K \cap K^t) < K$ for all $t \in T \setminus K$, and so (ii) does not hold.

Proof of Theorem 1.2 As each spreading primitive group is synchronizing, Theorem 1.1 implies that a spreading primitive group of diagonal type has socle $T \times T$, for some non-abelian finite simple group $T$. For each $T$, let $\Omega := T$, and let $W(T)$ be the subgroup of $\operatorname {{\mathrm {Sym}}}(\Omega )$ defined in § 2. Recall also that each subgroup of a non-spreading group is non-spreading. Thus it suffices to show that $W(T)$ is non-spreading for each $T$. If $T \notin \{\mathrm {J}_1,\,\mathrm {M}_{22},\, \mathrm {J}_3,\, \mathrm {McL},\,\mathrm {Th},\,\mathbb {M}\}$, then this is an immediate consequence of Theorem 1.3 and Corollary 2.3.

For each of the six remaining groups $T$, let $r$, $s_1$ and $s_2$ be members of the conjugacy classes of $T$ given in Table 2. By inspecting the character table for $T$ in [Reference Conway, Curtis, Norton, Parker and Wilson13], we observe that these elements satisfy Properties (i) and (ii) of Lemma 2.5. Therefore, that lemma shows that $W(T)$ is non-spreading.