Proof. For a simple group G, each nontrivial irreducible character is faithful. Then $| {\mathrm{cod}}(G)|=| {\mbox {cd}}(G)|$ and the result follows from [Reference Aziziheris, Shafiei and Shirjian3, Theorem 1.1].

Proof. Let N be a maximal normal subgroup of G. We set $q=3^{2f+1}$ . Since $ {\mathrm{cod}}(G)= {\mathrm{cod}}({}^2G_2(q))$ , we see that G is perfect. Then $G/N$ is a nonabelian simple group. Since $ {\mathrm{cod}}(G/N)\subseteq {\mathrm{cod}}(G)$ , we see that $| {\mathrm{cod}}(G/N)|$ is either $4, 5, 6, 7, 8, 9, 10$ or $11$ .

Suppose $| {\mbox {cod}}(G/N)| = 4$ . Then $G/N\cong {\mbox {PSL}}(2,k)$ , where $k=2^t \geq 4$ , and $ {\mbox {cod}}(G/N)=\{1, k(k-1), k(k+1), k^2-1\}$ . Since $k^2-1$ is the only nontrivial odd codegree, it must be the same as either $3^{5f+3}(q^2- q + 1)$ or $q^3( q+1-3m)$ or $q^3(q +1 + 3m )$ . Note that $(k+1,k-1)=1$ . Suppose that $k^2-1 = 3^{5f+3} (q^2- q + 1)$ . If $3^{5f+3} | k-1$ , then $k+1 | q^2-q+1$ . Clearly $q^2-q+1 < 3^{5f+3}$ , which implies that $ k+1 < k-1$ , which is a contradiction. If $ 3^{5f+3} | k+1$ , then $ k-1 | q^2-q+1$ . Clearly $ 3^{5f+3} - (q^2-q+1) = 3^{5f+3}-3^{4f+2}+ 3^{2f+1}-1> 2$ , which implies that $ (k+1)- (k-1)> 2$ , which is a contradiction. Suppose $k^2-1 = q^3( q+1-3m)$ . If $q^3 | k-1$ , then $k+1 | ( q+1-3m)$ . Obviously, we have $q^3> q+1-3m$ , which implies that $k-1> k+1$ , which is a contradiction. If $q^3 | k+1$ , then $k-1 | ( q+1-3m)$ . Clearly $q^3 - (q+1-3m) = (3^{6f+3}- 3^{2f+1}-1 ) + 3^{f+1}> 2$ , which implies that $k+1 - (k-1)> 2$ , which is a contradiction. Suppose $k^2-1 = q^3 (q+1+3m)$ . If $q^3 | k-1$ , then $k+1 | ( q+1+3m)$ . Since $q^3> q+1+3m$ , we have $k-1> k+1$ , which is a contradiction. If $q^3 | k+1$ , then $k-1 | ( q+1+3m)$ . Clearly $q^3 - (q+1+3m) = 3^{6f+3}-( 3^{2f+1}+1 + 3^{f+1} )> 2$ , which implies that $k+1 - (k-1)> 2$ , which is a contradiction.

Suppose $| {\mathrm{cod}}(G/N)|=5$ . Then $G/N \cong {\mathrm{PSL}}(2,k)$ , where $k>5$ is an odd prime power. We note that $2 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $| {\mathrm{cod}}(G/N)| =6$ . Then $G/N \cong {}^2B_2(2^{2t+1}) $ or $ {\mathrm{PSL}}(3,4) $ .

Suppose $G/N \cong {}^2B_2(s)$ with $s=2^{2t+1}$ and $r=2^t$ , $t \ge 1$ . The only nontrivial odd codegree in $ {\mathrm{cod}}({}^2B_2(s))$ is $(s - 1)(s^2 + 1)$ . Thus, $(s - 1)(s^2 + 1)$ could be equal to either $3^{5f+3} (q^2- q + 1)$ , $q^3( q+1-3m)$ or $q^3(q +1 + 3m )$ . Note that ${(s - 1 , s^2 + 1) =1}$ . Suppose $(s - 1)(s^2 + 1) = 3^{5f+3} (q^2- q + 1)$ . If $3^{5f+3} | s-1$ , then $s^2 + 1 | q^2- q + 1$ . Clearly $3^{5f+3}> q^2-q+1$ , which implies that $s-1> s^2+1$ , which is a contradiction. If $3^{5f+3} | s^2+1$ , we have a contradiction since $s^2-1$ is divisible by 3. Suppose $(s - 1) (s^2 + 1) = q^3 (q + 1 - 3m)$ . If $q^3 | s-1$ , then $ s^2 +1 | q+1-3m$ . Clearly $q^3> q+1-3m$ , which implies that $s-1> s^2+1$ , which is a contradiction. If $q^3 | s^2+1$ , then $s-1 | q+1-3m$ . This implies that $q^3 \leq (q+2-3m)^2+1$ , which is a contradiction. Suppose $(s - 1)(s^2 + 1) = q^3 (q + 1 + 3m)$ . If $q^3 | s-1$ , then $s^2 +1 | q+1+3m$ . Clearly $q^3> q+1+3m$ , which implies that $s-1> s^2+1$ , which is a contradiction. If $q^3 | s^2+1$ , then $s-1 | q+1+3m$ . This implies that $q^3 \leq (q+2+3m)^2 + 1$ , which is a contradiction.

Suppose $G/N \cong {\mathrm{PSL}}(3,4)$ . Note that $3^2{\cdot } 5{\cdot } 7$ is the only nontrivial odd codegree in $ {\mathrm{cod}}(G/N)$ . Thus, $3^2{\cdot } 5{\cdot } 7$ could be equal to either $3^{5f+3} (q^2- q + 1)$ , $q^3( q+1-3m)$ or $q^3(q +1 + 3m )$ . By considering the power of $3$ in those numbers, we see that each is impossible.

Suppose $| {\mathrm{cod}}(G/N)| = 7$ . Then $G/N \cong {\mathrm{PSL}}(3,3)$ , ${\operatorname {Alt}}_7$ , $M_{11}$ or $J_1$ .

Suppose $G/N \cong {\mathrm{PSL}}(3,3)$ . Note that $3 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong {\operatorname {Alt}}_7$ . Then $2^3 {\cdot } 3^2 \in {\mathrm{cod}}(G/N)$ . Since the powers of $3$ of all the terms that are divisible by $3$ in $ {\mathrm{cod}}(G)$ are greater than $2$ , this is a contradiction.

Suppose $G/N \cong M_{11}$ . Note that $5 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong J_1$ . Note that $ {\mathrm{cod}}(J_1)$ has two nontrivial odd codegrees $7{\cdot } 11{\cdot } 19$ and $3{\cdot } 5{\cdot } 11{\cdot } 19$ . The odd codegrees in $ {\mathrm{cod}}(G)$ are $3^{5f+3}(q^2-q+1)$ , $q^3 ( q+1 - 3m)$ and $q^3 ( q+1 + 3m)$ . By considering the power of $3$ in those numbers, we see that each is impossible.

Suppose $| {\mathrm{cod}}(G/N)|=8$ . Then $G/N \cong { {\mathrm{PSL}}}(3,s)$ , where $4< s\not \equiv 1\ (\bmod \ 3)$ , $ {\mathrm{PSU}}(3,s)$ , where $4 < s \not \equiv -1\ (\bmod \ 3)$ , or $G_2(2)'$ .

Suppose $ {\mathrm{cod}}(G/N) = {\mathrm{cod}}( {\mathrm{PSU}}(3,s))$ with $4 < s \not \equiv -1\ (\bmod \ 3)$ . Note that $3 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong G_2(2)'$ . Note that $3 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong {\mathrm{PSL}}(3,s)$ for some $4 < s \not \equiv 1\ (\bmod \ 3)$ . Note that $s-1, s+1 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ , and the only nontrivial integers in $\operatorname {ratio}( {\mathrm{cod}}(G))$ are $q-1$ , q, $q+1$ , where q is a power of $3$ and $q \geq 27$ . This will force $s=q$ , which is a contradiction since $q^3(q-1)^2 \not \in {\mathrm{cod}}(G)$ .

Suppose $| {\mathrm{cod}}(G/N)| = 9$ . Then $G/N \cong { {\mathrm{PSL}}}(3,s)$ , where $4<s\equiv 1\ (\bmod \ 3)$ , or $ {\mathrm{PSU}}(3,s)$ , where $4<s \equiv -1\ (\bmod \ 3)$ .

Suppose $G/N \cong {\mathrm{PSL}}(3, s)$ with $4 < s\equiv 1\ (\bmod \ 3)$ . Note that $3 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong {\mathrm{PSU}}(3,s)$ with $4 < s \equiv -1\ (\bmod \ 3)$ . Note that $s-1, s+1 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ , and the only nontrivial integers in $\operatorname {ratio}( {\mathrm{cod}}(G))$ are $q-1$ , q, $q+1$ , where q is a power of $3$ and $q \geq 27$ . This will force $s=q$ , which is a contradiction since $q^3(q+1)^2 \not \in {\mathrm{cod}}(G)$ .

Suppose $| {\mathrm{cod}}(G/N)| = 10$ . Then $G/N \cong M_{22}$ . Note that $11 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the only nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is q, where $q \geq 27$ .

Suppose $| {\mathrm{cod}}(G/N)| = 11$ . Then $G/N \cong { {\mathrm{PSL}}}(4,2), M_{12}, M_{23}$ or ${}^2G_2(3^{2s+1})$ , where $s\geq 1$ .

Suppose $G/N \cong {\mathrm{PSL}}(4, 2)$ . Note that $2 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong M_{12}$ . Note that $5 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong M_{23}$ . Note that $8 \in \operatorname {ratio}( {\mathrm{cod}}(G/N))$ . This is a contradiction since the smallest nontrivial integer in $\operatorname {ratio}( {\mathrm{cod}}(G))$ is $q- 1$ , where $q \geq 27$ .

Suppose $G/N \cong {}^2G_2(3^{2s+1})$ , $s\ge 1$ . Comparing the smallest nontrival odd codegree of each set, we see that $q=3^{2s+1}$ . Thus, $G/N \cong {}^2G_2(3^{2f+1})$ .

Proof. Let G be a group with $ {\mathrm{cod}}(G) = {\mathrm{cod}}({}^2G_2(q))$ . Let N be a maximal normal subgroup of G. Then, $G/N \cong {}^2G_2(q)$ by Lemma 3.1. Assume to the contrary that G is a minimal counterexample. By the choice of G, N is a minimal normal subgroup of G. Otherwise there exists a nontrivial normal subgroup L of G such that L is included in N. Then $ {\mathrm{cod}}(G/L)= {\mathrm{cod}}(G)$ for $ {\mathrm{cod}}(G)= {\mathrm{cod}}(G/N)\subseteq {\mathrm{cod}}(G/L) \subseteq {\mathrm{cod}}(G)$ and $G/L\cong {}^2G_2(q)$ because G is a minimal counterexample, which is a contradiction.

Step 1: N is the unique minimal normal subgroup of G. Otherwise, assume M is another minimal normal subgroup of G. Then $G=N\times M$ because $G/N$ is simple and $N\cong M\cong {}^2G_2(q)$ because M is also a maximal normal subgroup of G. Choose $\psi _1\in \mbox {Irr}(N)$ and $\psi _2\in \mbox {Irr}(M)$ such that $ {\mathrm{cod}}(\psi _1)= {\mathrm{cod}}(\psi _2)=\max ( {\mathrm{cod}}({}^2G_2(q)))$ . Set $\chi =\psi _1 \cdot \psi _2\in \mbox {Irr}(G)$ . Then $ {\mathrm{cod}}(\,\chi )=(\max ( {\mathrm{cod}}({}^2G_2(q))))^2\notin {\mathrm{cod}}(G)$ , which is a contradiction.

Set $\mbox {Irr}(G|N)=\{\,\chi \in \mbox {Irr}(G)|\,N$ is not contained in the kernel of $\chi \}$ .

Step 2: $\chi $ is faithful for each $\chi \in \mbox {Irr}(G|N)$ . Since N is not contained in the kernel of $\chi $ for each $\chi \in \mbox {Irr}(G|N)$ , the kernel of $\chi $ is trivial by Step 1.

Step 3: N is elementary abelian. Assume to the contrary that N is not abelian. Then $N=S^n$ , where S is a nonabelian simple group and $n\in \mathbb {N}$ . By Theorems 2, 3 and 4 and Lemma 5 in [Reference Bianchi, Chillag, Lewis and Pacifici5], we see that there exists a nonprincipal character $\psi \in \mbox {Irr}(N)$ that extends to some $\chi \in \mbox {Irr}(G)$ . Then $\ker (\,\chi )=1$ by Step 2 and $ {\mathrm{cod}}(\,\chi )=|G|/\chi (1)=|G/N|\cdot |N|/\psi (1)$ . This is a contradiction since $|G/N|$ is divisible by $ {\mathrm{cod}}(\,\chi )$ .

Step 4: It is enough to assume that $\mathbf {C}_G(N)=N$ . We note that ${\textbf {{C}}}_G(N) \unlhd G$ . As N is abelian by Step 3, either ${\textbf {{C}}}_G(N) = G$ or ${\textbf {{C}}}_G(N) =~N$ .

We now prove the result in the case ${\textbf {{C}}}_G(N) = G$ . Assume so. Then N is contained in the centre ${\textbf {Z}}(G)$ of G. Since G is perfect, ${\textbf {Z}}(G)=N$ and N is isomorphic to a subgroup of the Schur multiplier of $G/N$ [Reference Isaacs10, Corollary 11.20]. This forces N to be trivial as ${}^2G_2(q)$ has trivial Schur multiplier, and we are done.

Step 5: Let $\lambda $ be a nonprincipal character in $\mbox {Irr}(N)$ and $\theta \in \mbox {Irr}(I_G(\lambda )|\lambda )$ . We show that ${|I_G(\lambda )|}/{\theta (1)} \in {\mathrm{cod}}(G)$ . Also, $\theta (1)$ divides $|I_G(\lambda )/N|$ and $|N|$ divides $|G/N|$ . Let $\lambda $ be a nonprincipal character in $\mbox {Irr}(N)$ . Given $\theta \in \mbox {Irr}(I_G(\lambda )|\lambda )$ . Note that $\chi =\theta ^G\in \mbox {Irr}(G)$ and $\chi (1)=|G:I_G(\lambda )|\cdot \theta (1)$ by Clifford theory (see [Reference Isaacs10, Ch. 6]). Then $\ker (\,\chi )=1$ by Step 2 and $ {\mathrm{cod}}(\,\chi )={|I_G(\lambda )|}/{\theta (1)}$ . In particular, $\theta (1)$ divides $|I_G(\lambda )/N|$ , and then $|N|$ divides ${|I_G(\lambda )|}/{\theta (1)}$ . Since $ {\mathrm{cod}}(G)= {\mathrm{cod}}(G/N)$ and $|G/N|$ is divisible by every element in $ {\mathrm{cod}}(G/N)$ , we have $|N|\mid |G/N|$ .

Step 6: Final contradiction. By Step 3, N is an elementary abelian r-subgroup for some prime r and we assume $|N|=r^n$ , $n\in \mathbb {N}$ . By the normaliser–centraliser theorem, $n> 1$ .

Let $\lambda \in \mbox {Irr}(N)$ be a nonprincipal character and $T:=I_G(\lambda )$ . By Step 5, ${|T|}/{\theta (1)}\in {\mathrm{cod}}(G)$ for all $\theta \in \mbox {Irr}(T|\lambda )$ .

Since N is abelian by Step 1, $|\mbox {Irr}(N)|=|N|$ . Therefore, $|N|=|\mbox {Irr}(N)|> |G:T|$ since $|G:T|$ is the number of conjugates of $\lambda $ in G which are all contained in $\mbox {Irr}(N)$ .

We now show that $q^3$ is the largest power of a prime that divides the order of ${}^2G_2(q)$ . Note that the order of ${}^2G_2(q)$ is $q^3(q^3+1)(q-1)$ . We first observe that $q^3+1=2^k$ has no integer solution, and thus $q^3+1$ is divisible by a prime greater than or equal to $5$ . We also note that either $q^3+1$ or $q-1$ is divisible by $4$ but not both, and thus the largest power of $2$ that divides $(q^3+1)(q-1)$ is less than $q^3$ . Suppose that r is an odd prime that divides $(q^3+1)(q-1)$ . Since $\gcd (q+1,q-1)=2$ , the largest power of r that divides $(q^3+1)(q-1)$ is also less than $q^3$ . Thus, $q^3$ is the largest power of a prime that divides the order of ${}^2G_2(q)$ . Thus, $|N| \leq q^3$ .

Let K be a maximal subgroup of ${}^2G_2(q)$ such that $T/N \leq K$ . If K is of type P in Lemma 2.3, then $|G:T| \ge q^3+1$ , and it is clear that $q^3+1>q^3$ , which is a contradiction. If K is of type $ C_{R_{0}(i)}$ , then $|G:T| \ge q^2 (q^2 - q + 1)> q^3 $ , which is a contradiction. If K is of type $N_{R_{0} \langle i ,j \rangle }$ , then $|G:T| \ge { q^3( q^2 - q + 1 ) ( q - 1) }/{ 12 (q+1) }$ , thus $|G:T|> q^3$ , which is a contradiction. If K is of type $M^{+}W^{+}$ , then $|G:T| \ge { q^3( q^2 - q + 1 ) ( q - 1) }/{ 6 ( q +\! \sqrt { 3q } + 1 )}$ , and thus $|G:T|> q^3$ , which is a contradiction. If K is of type $M^{-}W^{-}$ , then $|G:T| \ge { q^3( q^2 - q + 1 ) ( q - 1) }/{ 6 ( q -\! \sqrt { 3q } + 1 )}$ , and thus $|G:T|> q^3$ , which is a contradiction. If K is of type $C_{R_0}(\Psi _{ \alpha })$ , then $|G:T| \ge {q^3(q^3+1)(q-1)}/{q_0^3(q_0^3+1)(q_0-1)}$ , where $q=q_0^{\alpha }$ , $\alpha $ a prime. Thus, $|G:T|> q^ {3}$ , which is a contradiction.