Proof of Theorem 1.1.

We complete the proof by induction on $|G|+|N|$ . Take $\lambda \in \mathrm{Irr}(N)$ with $\mathrm{Irr}_p(\lambda ^G) \neq \emptyset $ . Let E be a maximal normal subgroup of G such that $N \leq E$ and $G/E$ is not p-solvable. Then, $G/E$ admits the unique minimal normal subgroup $M/E$ and it is easy to check that $M/E$ is not p-solvable. Assume that $\{\mu _1, \ldots , \mu _t\} \subseteq \mathrm{Irr}(\lambda ^E)$ such that every element of $\mathrm{Irr}(\lambda ^E)$ is conjugate to exactly one of the elements in $\{\mu _1, \ldots , \mu _t\}$ . If $N \neq E$ , then from the hypothesis, $\mathrm{Irr}_p(\mu _i^G)=\emptyset $ or $\mathrm{acd}_p(\mu _i^G) \geq f(p)$ , for $1 \leq i \leq t$ . As $\mathrm{Irr}(\lambda ^G) =\dot {\cup }_{i=1}^t \mathrm{Irr}(\mu _i^G)$ and $\mathrm{Irr}_p(\lambda ^G) \neq \emptyset $ , we conclude that $\mathrm{Irr}_p(\mu _j^G) \neq \emptyset $ for some j with $1 \leq j \leq t$ . So, it follows from Lemma 2.1 that $\mathrm{acd}_p(\lambda ^G) \geq f(p) $ , as desired. Next, suppose that $N=E$ . If $\lambda $ is extendible to $\chi \in \mathrm{Irr}(G)$ , then Gallagher’s theorem [Reference Isaacs4, Corollary 6.17] implies that $\mathrm{Irr}(\lambda ^G)=\{\chi \mu : \mu \in \mathrm{Irr}(G/N)\}$ and for every $\mu _1,\mu _2 \in \mathrm{Irr}(G/N)$ with $\mu _1 \neq \mu _2$ , we have $\chi \mu _1 \neq \chi \mu _2$ . Thus, either $p \mid \chi (1)$ and $\mathrm{acd}_p(\lambda ^G)=\chi (1) \mathrm{acd}(G/N)$ or $p \nmid \chi (1)$ and $\mathrm{acd}_p(\lambda ^G)=\chi (1) \mathrm{acd}_p(G/N)$ . Obviously, $\mathrm{acd}(G/N) \geq 1$ . So, in the former case, $\mathrm{acd}_p(\lambda ^G) \geq p> f(p)$ , as needed. Since $G/N$ is not p-solvable, Lemma 2.2 yields $\mathrm{acd}_p(G/N) \geq f(p)$ . Hence, if $p \nmid \chi (1)$ , then $\mathrm{acd}_p(\lambda ^G)=\chi (1) \mathrm{acd}_p(G/N) \geq f(p)$ , as desired. Finally, suppose that $\lambda $ is not extendible to G. Then, for every $\chi \in \mathrm{Irr}(\lambda ^G)$ , $\chi (1)> \lambda (1) \geq 1$ . This means that $p \mid \chi (1) $ for every $\chi \in \mathrm{Irr}_p(\lambda ^G)$ . Therefore, $\mathrm{acd}_p(\lambda ^G) \geq p> f(p)$ . Now, the proof is complete.

Proof of Theorem 1.2.

First, assume that $\mathrm{Irr}_p(G|N) \neq \emptyset $ . As $\mathrm{acd}_p(G|N) < f(p) < p $ , we see that $\mathrm{Irr}_p(G|N)$ contains a linear character $\chi $ . Then, $\chi _N \neq 1_N $ and as $\chi (1)=1$ , we have $\chi _N \in \mathrm{Irr}(N)$ . This implies that N admits some linear characters which are extendible to G and they are nonprincipal. Assume that $\{\mu _1,\ldots , \mu _t\}$ is the set of all linear characters of N which are extendible to G and are nonprincipal. Since the $\mu_i$ s are extendible to G, none of them are G-conjugate. If $1 \leq i \neq j \leq t$ and there exists $\chi \in \mathrm{Irr}(\mu _i^G) \cap \mathrm{Irr}(\mu _j^G)$ , then $\mu _i$ and $\mu _j$ are irreducible constituents of $\chi _N$ . It follows from Clifford’s correspondence that $\mu _i$ and $\mu _j$ are G-conjugate, which is a contradiction with our former assumption on the $\mu _i$ s. This shows that

(2.1) $$ \begin{align} \mathrm{Irr}(\mu_i^G) \cap \mathrm{Irr}(\mu_j^G)=\emptyset \quad\mathrm{for~} 1 \leq i \neq j \leq t. \end{align} $$

Let $1 \leq i \leq t$ . Our assumption on the $\mu _i$ guarantees the existence of a linear character $\chi _i \in \mathrm{Irr}(G) $ such that $(\chi _i)_N=\mu _i$ . By Gallagher’s theorem [Reference Isaacs4, Corollary 6.17], $\mathrm{Irr}(\mu _i^G)=\{\chi _i \varphi : \varphi \in \mathrm{Irr}(G/N)\}$ and for distinct characters $\varphi _1,\varphi _2 \in \mathrm{Irr}(G/N)$ , $\chi _i\varphi _1 \neq \chi _i \varphi _2$ . Since  $\chi _i(1)=1$ ,

(2.2) $$ \begin{align} \mathrm{Irr}_p(\mu_i^G)=\{\chi_i \varphi: \varphi \in \mathrm{Irr}_p(G/N)\}. \end{align} $$

As $\mu _i \neq 1_N$ , $\chi _i \in \mathrm{Irr}(G|N)$ . Therefore,

$$ \begin{align*} \mathrm{Irr}_p(\mu_i^G) \subseteq \mathrm{Irr}_p(G|N). \end{align*} $$

In view of (2.1), $\bigcup _{i=1}^t\mathrm{Irr}(\mu _i^G)$ is disjoint. Take

$$ \begin{align*} \mathfrak{A}=\mathrm{Irr}_p(G|N) - \dot{\cup}_{i=1}^t\mathrm{Irr}(\mu_i^G). \end{align*} $$

If $\chi \in \mathrm{Irr}(G|N)$ is linear, then $\chi _N \neq 1_N$ and $\chi _N(1)=\chi (1)=1$ . Thus, $\chi _N \in \mathrm{Irr}(N)$ is nonprincipal. It follows from our assumption on the $\mu _i$ that $\chi _N \in \{\mu _1,\ldots , \mu _t\}$ . Therefore, $\chi \in \mathrm{Irr}(\mu _j^G)$ for some $1 \leq j \leq t$ . This implies that $\chi (1) \geq p$ for every $\chi \in \mathfrak {A}$ . Therefore,

(2.3) $$ \begin{align} \mathrm{acd}_p(\mathfrak{A}) \geq p> f(p). \end{align} $$

By (2.1) and (2.2), $|\dot {\cup }_{i=1}^t \mathrm{Irr}_p(\mu _i^G)|=t|\mathrm{Irr}_p(G/N)|$ and

$$ \begin{align*} \mathrm{acd}_p(\dot{\cup}_{i=1}^t \mathrm{Irr}(\mu_i^G))&= \frac{\Sigma_{i=1}^t \Sigma_{\chi \in \mathrm{Irr}_p(\mu_i^G)} \chi(1) }{|\dot{\cup}_{i=1}^t \mathrm{Irr}_p(\mu_i^G)|}\\ &= \frac{\Sigma_{i=1}^t \Sigma_{\varphi \in \mathrm{Irr}_p(G/N)} (\chi_i \varphi)(1)}{t|\mathrm{Irr}_p(G/N)|}\\\nonumber &= \frac{t \Sigma_{\varphi \in \mathrm{Irr}_p(G/N)} \varphi(1)}{t|\mathrm{Irr}_p(G/N)|}=\mathrm{acd}_p(G/N). \end{align*} $$

If $\mathrm{acd}_p(G/N) \geq f(p)$ , then

(2.4) $$ \begin{align} \mathrm{acd}_p(\dot{\cup}_{i=1}^t \mathrm{Irr}(\mu_i^G)) \geq f(p). \end{align} $$

Note that $\mathrm{Irr}_p(G|N) = (\dot {\cup }_{i=1}^t\mathrm{Irr}_p(\mu _i^G)) \dot {\cup } \mathfrak {A}$ . It follows from (2.3), (2.4) and Lemma 2.1 that $\mathrm{acd}_p(G|N) \geq f(p)$ , which is a contradiction. This implies that $\mathrm{acd}_p(G/N) <f(p)$ . As $\mathrm{acd}_p(G|N) < f(p)$ and $\mathrm{Irr}_p(G) =\mathrm{Irr}_p(G|N) \dot {\cup } \mathrm{Irr}_p(G/N)$ , we deduce from Lemma 2.1 that $\mathrm{acd}_p(G) < f(p)$ . Hence, Lemma 2.2 implies that G is p-solvable and $O^{p'}(G)$ is solvable, as desired.

Now, assume that $\mathrm{Irr}_p(G|N)=\emptyset $ . Working towards a contradiction, suppose that there exists $\theta \in \mathrm{Irr}(N) $ such that $p \mid \theta (1)$ . We have $\theta (1) \mid \chi (1)$ for every $\chi \in \mathrm{Irr}(\theta ^G)$ . Thus, $p \mid \chi (1)$ for every $\chi \in \mathrm{Irr}(\theta ^G)$ . Clearly, $\theta \neq 1_N$ . So, $\chi \in \mathrm{Irr}_p(\theta ^G) \subseteq \mathrm{Irr}_p(G|N) $ . This means that $\mathrm{Irr}_p(G|N) \neq \emptyset $ , which is a contradiction. This implies that $p \nmid \theta (1)$ for every $\theta \in \mathrm{Irr}(N)$ . It follows from the Ito–Michler theorem [Reference Isaacs4, Corollary 12.34] that N has a normal and abelian Sylow p-subgroup. Thus, N is p-solvable. Now, assume that $1_N \neq \theta \in \mathrm{Irr}(N)$ and $\chi \in \mathrm{Irr}(\theta ^G)$ . Hence, $\chi \in \mathrm{Irr}(G|N) $ . As $\mathrm{Irr}_p(G|N) = \emptyset $ , we deduce that $p \nmid \chi (1)$ . Thus, $p \nmid \chi (1)/\theta (1)$ . It follows from Lemma 2.3 that $G/N$ has an abelian Sylow p-subgroup. This completes the proof.