1. Introduction
The group ring $RG$ , where $G$ is a finite group and $R$ is a commutative ring, holds significant importance in representation theory. Over the past few decades, there has been considerable interest in decoding information about a group $G$ from its group ring $RG$ . One particularly challenging problem in this context is the isomorphism problem, which investigates whether a group ring uniquely determines its corresponding group. Specifically, if $RG$ and $RH$ are isomorphic as $R$ -rings, does it imply that the groups $G$ and $H$ are isomorphic as well? For the current status of this problem, one can refer to [Reference Coleman2, Reference Karpilovsky13, Reference Margolis15, Reference Margolis and Del Rio16, Reference Sandling27]. The solution to this problem depends mainly upon the ring under consideration. For example, all the finite abelian groups of a given order have isomorphic complex group algebras, whereas the rational group algebras of any two non-isomorphic abelian groups are always non-isomorphic (see [Reference Perlis and Walker25]). In 1971, Dade [Reference Dade3] constructed an example demonstrating the existence of two non-isomorphic metabelian groups that possess isomorphic group algebras over any field. Subsequently, Hertweck [Reference Hertweck9] presented a counterexample of this phenomenon for integral group rings, showcasing two non-isomorphic groups of even order whose integral group rings are isomorphic. However, the problem of determining whether integral group rings of groups with odd order are isomorphic remains an open question. Additionally, investigating this problem in the context of modular group rings, in particular, for the group rings of finite $p$ -groups over a field of characteristic $p$ has been of significant interest (see [Reference Polcino Milies and Sehgal26]).
In recent times, a variant of the classical isomorphism problem known as the twisted group ring isomorphism problem has gained considerable attention. The problem was initially introduced in [Reference Margolis and Schnabel17] and has been further explored by the authors in [Reference Margolis and Schnabel18, Reference Margolis and Schnabel19]. In order to explain this version of the isomorphism problem, we start by introducing some notation.
Let $R$ be a commutative ring with unity and $R^\times$ be the unit group of $R$ . Following [Reference Karpilovsky14], we denote the set of $2$ -cocyles of $G$ by $ Z^{2}(G,R^{\times })$ and the second cohomology group of $G$ over $R^{\times }$ by ${\mathrm{H}}^{2}(G,R^{\times })$ . For a $2$ -cocycle $\alpha,$ let $R^{\alpha }[G]$ be the $\alpha$ -twisted group ring of $G$ over $R$ , that is $R^\alpha [G] = \{\sum _{g \in G} x_g e_g \mid x_g \in R \}$ is an $R$ -algebra with the following operations:
-
(addition) $(\sum _{g \in G} x_g e_g) + (\sum _{g \in G} y_g e_g) = \sum _{g \in G} (x_g + y_g) e_g$ .
-
(multiplication) $e_g.e_h = \alpha (g,h) e_{gh}$ for all $g,h \in G$ , and defined distributively for all other elements of $R^\alpha [G]$ .
For an element $\alpha \in Z^2(G, \mathbb C^\times )$ , the corresponding element of ${\mathrm{H}}^2(G, \mathbb C^\times )$ will be denoted by $[\alpha ]$ . It is well known that $R^\alpha [G] \cong R^\beta [G]$ as $R$ -algebras for $\alpha, \beta \in Z^2(G, R^\times )$ such that $[\alpha ] = [\beta ]$ .
Given groups $G,H$ and a ring $R$ , we write $G\sim _{R}H$ if there exists an isomorphism $\psi \;:\;{\mathrm{H}}^{2}(G,R^{\times }) \rightarrow{\mathrm{H}}^{2}(H,R^{\times })$ such that $R^{\alpha }[G] \cong R^{\psi (\alpha )}[H]$ for every $[\alpha ] \in{\mathrm{H}}^{2}(G,R^{\times })$ . The twisted group ring isomorphism problem is to determine the equivalence classes of groups of order $n,$ under the relation $\sim _{R}$ . We call these equivalence classes the $R$ -twist isomorphism classes.
Throughout this article, our focus lies on the $\mathbb{C}$ -twist isomorphism classes of finite $p$ -groups. The second cohomology group of a finite group $G$ over $\mathbb C^\times$ , that is ${\mathrm{H}}^2(G, \mathbb{C}^\times )$ , is commonly referred to as the Schur multiplier of $G$ . The order of the group, the structure of the Schur multiplier, and the structure of the complex group algebra remain invariant under $\mathbb{C}$ -twist isomorphism.
In [Reference Margolis and Schnabel17, Theorem 4.3], Margolis and Schnabel determined the $\mathbb{C}$ -twist isomorphism classes of groups of order $p^4$ , where $p$ is a prime. In the same article, they proved (see [Reference Margolis and Schnabel17, Lemma 1.2]) that any equivalence class of a finite abelian group with respect to $\sim _{\mathbb{C}}$ is a singleton. Hence, it is sufficient to focus on the classification of the $\mathbb C$ -twist isomorphism classes of non-abelian finite groups. In this article, we continue this line of investigation of the $\mathbb{C}$ -twist isomorphism classes of finite non-abelian $p$ -groups by fixing the order of the second cohomology group over $\mathbb C^\times$ . Green [Reference Green6] proved that the order of the Schur multiplier of a $p$ -group $G$ of order $p^n$ is at most $ p^{\frac{n(n-1)}{2}}.$ Niroomand [Reference Niroomand20] improved this bound for non-abelian $p$ -groups and proved that $|{\mathrm{H}}^2(G, \mathbb C^\times )| \leq p^{\frac{(n-1)(n-2)}{2}+1}$ for any non-abelian group $G$ of order $p^n$ . In view of this result, a finite non-abelian $p$ -group $G$ is said to have generalized corank $s(G)$ if $|{\mathrm{H}}^2(G, \mathbb C^\times )| = p^{\frac{(n-1)(n-2)}{2}+1 - s(G)}.$
We study the $\mathbb{C}$ -twist isomorphism classes of finite non-abelian $p$ -groups by fixing their generalized corank. In particular, we describe the $\mathbb C$ -twist isomorphism classes of all $p$ -groups with $s(G) \leq 3$ . The classification of all non-isomorphic $p$ -groups with $s(G) \leq 3$ is known in the literature by the work of Niroomand [Reference Niroomand24] and Hatui [Reference Hatui7]. We use this classification along with the structure of the corresponding twisted group algebras to obtain our results. We use the following notation:
-
$C_{p^{n}}$ denotes the cyclic group of order $p^n$ .
-
$C_{p^{n}}^{m}$ or $C_{p^{n}}^{(m)}$ denote the direct product of $m$ -copies of the cyclic group of order $p^n$ .
-
$H_{m}^{1}$ and $H_{m}^{2}$ denote the extraspecial $p$ -groups of order $p^{2m+1}$ and of exponent $p$ and $p^2$ , respectively.
-
$H.K$ denotes the central product of the groups $H$ and $K$ .
-
$E(r) = E.C_{p^{r}}$ , where $E$ is an extraspecial $p$ -group.
We now list the main results of this article. Our first result describes the $\mathbb{C}$ -twist isomorphism classes of groups with generalized corank zero or one.
Lemma 1.1. For non-abelian groups $G$ of order $p^{n}$ with $s(G) \in \{ 0, 1\}$ , every $\mathbb{C}$ -twist isomorphism class is a singleton, that is consists of only one group up to isomorphism.
In our next result, we describe all non-singleton $\mathbb{C}$ -twist isomorphism classes of finite $p$ -groups with $s(G)=2$ .
Theorem 1.2. All non-singleton $\mathbb{C}$ -twist isomorphism classes of non-abelian groups of order $p^n$ and generalized corank two are as follows:
-
(1) for any $n \geq 4$ , $\mathbb{Q}_{8} \times C_{2}^{(n-3)} \sim _{\mathbb{C}} E(2) \times C_{2}^{(n-4)}$ ;
-
(2) for an odd prime $p$ , $E(2) \sim _{\mathbb{C}} H_1^2 \times C_p \sim _{\mathbb{C}} \langle a,b\,|\,a^{p^2}=1,b^{p}=1, [a,b,a]=[a,b,b]=1 \rangle$ ;
-
(3) for $n \geq 5$ , $E(2) \times C_p^{(n-4)} \sim _{\mathbb{C}} H_1^2 \times C_p^{(n-3)}$ ;
-
(4) for $n = 2m+1$ and $m \geq 2,$ $H_m^1 \times C_p^{(n-2m-1)} \sim _{\mathbb{C}} H_m^2 \times C_p^{(n-2m-1)}$ ;
-
(5) for $n \geq 6$ and $1 \lt m \leq n/2-1$ , $E(2) \times C_p^{(n-2m-2)} \sim _{\mathbb{C}} H_m^1 \times C_p^{(n-2m-1)} \sim _{\mathbb{C}} H_m^2 \times C_p^{(n-2m-1)}$ .
See Section 3 for the proof of Lemma 1.1 and Theorem 1.2. The next result describes the non-singleton $\mathbb{C}$ -twist isomorphism classes for the groups of order $p^{n}$ with $s(G)=3$ . A complete classification of these groups was given by Hatui [Reference Hatui7, Theorem 1.1]. We refer the reader to Theorem 4.1 for the details and for the notation appearing in our next result.
Theorem 1.3. All non-singleton $\mathbb{C}$ -twist isomorphism classes of non-abelian groups of order $p^n$ and generalized corank three are as follows:
-
1. $\phi _3(211)a \sim _{\mathbb C} \phi _3(211)b_1 \sim _{\mathbb C} \phi _3(211)b_{r_p};$
-
2. $\phi _2(2111)c \sim _{\mathbb C} \phi _2(2111)d.$
A proof of the above result is included in Section 4.
Remark 1.4. By [Reference Ellis4], a group $G$ of order $p^n$ is said to have corank $t(G)$ if its Schur multiplier has order $ p^{\frac{n(n-1)}{2} - t(G)}$ . A classification of all finite $p$ -groups $G$ with corank of $G$ at most $6$ is also known in literature, see [Reference Berkovich1, Reference Ellis4, Reference Niroomand21, Reference Niroomand23, Reference Zhou29]. By definition, $t(G) \leq 6$ for any non-abelian group $G$ of order $p^n$ implies $n \leq 8$ and $s(G) \leq 5$ . Further, $s(G) \in \{4,5\}$ gives $n \leq 4$ . Therefore, our above description of $\mathbb C$ -twist isomorphism classes along with the known results from literature also gives $\sim _{\mathbb C}$ classes of groups with $t(G) \leq 6$ .
To prove Theorem 1.2, we use the following general result. This is a helpful tool to prove the $\mathbb C$ -twist isomorphism between groups $G_1$ and $G_2$ and may be of an independent interest.
Theorem 1.5. Suppose $G_1$ and $G_2$ are two groups with isomorphisms $\delta \;:\; G'_{\!\!1} \rightarrow G'_{\!\!2},$ $\sigma \;:\; G_1/G'_{\!\!1} \rightarrow G_2/G'_{\!\!2}$ and the following short exact sequences for $i \in \{ 1, 2\}:$
where ${\mathrm{tra}}_i$ and $\inf _i$ are the transgression and inflation homomorphisms. If $\tilde{\delta }\;:\; \mathrm{Hom}(G'_{\!\!2}, \mathbb{C}^\times ) \rightarrow \mathrm{Hom}(G'_{\!\!1}, \mathbb C^\times )$ and $\tilde{\sigma }\;:\;{\mathrm{H}}^2(G_1/G'_{\!\!1}, \mathbb C^\times ) \rightarrow{\mathrm{H}}^2(G_2/G'_{\!\!2}, \mathbb C^\times )$ are the induced isomorphisms such that the Figure 1 is commutative, then $G_{1}\sim _{\mathbb{C}}G_{2}$ .
We refer the reader to Section 2 for the definition of transgression and inflation homomorphisms as well as for a proof of the above result.
2. Preliminaries
In this section, we fix notation and include a few preliminary results that we use throughout this article. We refer the reader to Karpilovsky [Reference Karpilovsky14] for most of the results included in this section.
Let $G$ be a finite group. Recall, for a group $G$ , $Z^2(G, \mathbb C^\times )$ consists of all functions $f\;:\; G \times G \rightarrow \mathbb C^\times$ such that $f(x,1) = f(1,x) = 1$ and $f(x,y)f(xy, z) = f(x, yz) f(y, z)$ for all $x,y, z \in G$ . We shall call elements of $Z^2(G, \mathbb C^\times )$ as 2-cocycles (or sometimes just cocycles when it is clear from the context). Then ${\mathrm{H}}^2(G, \mathbb C^\times ) = Z^2(G, \mathbb C^\times )/B^2(G, \mathbb C^\times )$ , where $B^2(G, \mathbb C^\times )$ is the set of $2$ -coboundaries of $G$ , is called the second cohomology group of $G$ or the Schur multiplier of $G$ . The elements of ${\mathrm{H}}^2(G, \mathbb C^\times )$ are called the cohomology classes of $G$ . For an element $\alpha \in Z^2(G, \mathbb C^\times )$ , the corresponding element of ${\mathrm{H}}^2(G, \mathbb C^\times )$ will be denoted by $[\alpha ]$ . For 2-cocycles $\alpha, \beta \in Z^2(G, \mathbb C^\times )$ we say $\alpha$ is cohomologous to $\beta$ , whenever $[\alpha ] = [\beta ]$ .
A central extension,
is called a stem extension, if $A \subseteq Z(G) \cap G'$ . For a given stem extension (2.1), the Hochschild-Serre spectral sequence [Reference Hochschild and Serre10, Theorem 2, p. 129] yields the following exact sequence
where ${\mathrm{tra}}\;:\;\mathrm{Hom}( A,\mathbb C^\times ) \to{\mathrm{H}}^2(G/A, \mathbb C^\times )$ given by $f \mapsto [{\mathrm{tra}}(f)]$ , where
for a section $\mu \;:\; G/A \rightarrow G$ , denotes the transgression homomorphism and the inflation homomorphism, $\inf \;:\;{\mathrm{H}}^2(G/A, \mathbb C^\times ) \to{\mathrm{H}}^2(G, \mathbb C^\times )$ is given by $[\alpha ] \mapsto [\inf (\alpha )]$ , where $\inf (\alpha )(x,y) = \alpha (xA,yA)$ .
Let $G$ be a finite group and $V$ be a finite-dimensional complex vector space. A mapping $\rho \;:\; G \rightarrow \mathrm{GL}(V)$ is called a (finite-dimensional and complex) projective representation of $G$ if thhere xists a mapping $\alpha \;:\; G \times G \rightarrow \mathbb C^\times$ such that
-
$\rho (x) \rho (y) = \alpha (x, y) \rho (xy)$ for all $x,y \in G$ ,
-
$\rho (1) = \mathrm{Id}_V$ .
In this case, we say $\rho$ is an $\alpha$ -representation of $G$ on $V$ . For $\alpha \in Z^2(G, \mathbb C^\times )$ , we use $\mathrm{Irr}^\alpha (G)$ to denote the set of equivalence classes of irreducible $\alpha$ -representations of $G$ . For $\alpha = 1$ , we use $\mathrm{Irr}(G)$ instead of $\mathrm{Irr}^\alpha (G)$ and call this the set of ordinary irreducible representations of $G$ . For $\rho \in \mathrm{Irr}(G)$ , at times, we shall also omit the word “ordinary” and call $\rho$ to be a representation of $G$ . For $\alpha \in{\mathrm{H}}^2(G, \mathbb C^\times )$ , the complex group algebra $\mathbb C^\alpha G$ is semisimple and
where $M_n(\mathbb C)$ denotes the $n \times n$ matrix algebra over $\mathbb C$ . Hence, the information of projective representations of $G$ is also helpful to study the twisted group algebra isomorphism problem. To this end, the representation group (also called a covering group) of a group $G$ will play an important role. We now recall the definition of the representation group.
Definition 2.1. A group $G^*$ is called a representation group of the group $G$ if the following conditions are satisfied:
-
1. There exists a central extension $1 \rightarrow A \rightarrow G^* \rightarrow G \rightarrow 1$ such that $\mathrm{Hom}(A,\mathbb C^\times ) \cong{\mathrm{H}}^2(G, \mathbb C^\times )$ .
-
2. For every projective representation $\rho$ of $G$ , thhere xists an ordinary representation $\tilde{\rho }$ of $G^*$ such that $\rho (g)=\tilde{\rho }(s(g))$ for all $g \in G$ and for some section $s\;:\; G\rightarrow G^*.$
In [Reference Schur28], Schur proved that representation group of a finite group always exists (see also [Reference Karpilovsky14, Chapter 3 (Corollary 3.3)]). From above, it is clear that to determine the projective representations of a group $G$ , it is enough to determine a representation group of $G$ (there may be many non-isomorphic ones) and its ordinary representations. We now recall a result that elaborates the above correpondence between the projective representations of $G$ and the ordinary representations of $G^\star$ .
Let $N$ be a normal subgroup of $G$ and $\chi \in \mathrm{Irr}(N)$ . Let $\mathrm{Irr}(G \mid \chi )$ denote the set of inequivalent ordinary irreducible representations of $G$ lying above $\chi$ , that is $\rho \in \mathrm{Irr}(G \mid \chi )$ if and only if $\mathrm{Hom}_{N}(\rho |_{N}, \chi )$ is non-trivial. The following well-known result relates the projective representations of $G$ and the ordinary ones of $G^\star$ , see [Reference Karpilovsky14, Chapter 3, Lemma 3.1] and [Reference Hatui and Singla8, Theorem 3.2] for its proof.
Theorem 2.2. Let $\alpha$ be a $2$ -cocycle of $G$ . Let $\chi \in \mathrm{Hom}(A,\mathbb C^\times )$ be such that $\mathrm{tra}(\chi ) = [\alpha ]$ . There is a bijective correspondence between
obtained via lifting a projective representation of $G$ to an ordinary representation of $G^\star$ . In particular, we obtain the following:
To understand the ordinary representations of a representation group, we also require a few general results from the theory of the ordinary characters of a finite group. These results are usually known by the name of Clifford’s theory and they provide an important connection between the complex representations of a finite group $G$ and its normal subgroups. Recall that $\mathrm{Irr}(G)$ , for a finite group $G$ , denotes the set of all inequivalent irreducible representations of $G$ . For an abelian group $A$ , we also use $\widehat{A}$ to denote $\mathrm{Irr}(A)$ and call this to be the set of characters (or one-dimensional representations) of $A$ . Let $N$ be a normal subgroup of $G$ and $\rho \in \mathrm{Irr}(N)$ be an irreducible representation of $N$ . The representation obtained by inducing $\rho$ from $N$ to $G$ will be denoted by $\mathrm{Ind}_N^G(\rho )$ . We say $\rho \in \mathrm{Irr}(N)$ has an extension to $G$ if thhere xists $\tilde{\rho } \in \mathrm{Irr}(G)$ such that $\tilde{\rho }|_{N} = \rho .$
The group $G$ acts on $\mathrm{Irr}(N)$ via conjugation action of $G$ on $N$ . For $\rho \in \mathrm{Irr}(N)$ and $g\in G$ , define $\rho ^g \in \mathrm{Irr}(N)$ by $\rho ^g(x) = \rho (gxg^{-1})$ for all $x \in N$ . For $\rho, \rho ' \in \mathrm{Irr}(N)$ , we use $\rho \cong \rho '$ to denote that $\rho$ and $\rho '$ are equivalent representations of $N$ . For $\rho \in \mathrm{Irr}(N)$ , let $I_G(\rho ) = \{ g \in G |\,\, \rho ^{g} \cong \rho \}$ denote the stabilizer (or the inertia) group of $\rho$ in $G$ . We will use the following results of Clifford’s theory:
Theorem 2.3.
-
(i) ([Reference Isaacs11], Theorem 6.11) The map
\begin{equation*} \theta \mapsto \mathrm {Ind}_{I_G(\rho )}^G(\theta ) \end{equation*}is a bijection of $\mathrm{Irr}(I_G(\rho ) \mid \rho )$ onto $\mathrm{Irr}(G \mid \rho )$ . -
(ii) ([Reference Isaacs11], Theorem 6.16) Let $H$ be a subgroup of $G$ containing $N$ , and suppose that $\rho$ is an irreducible representation of $N$ which has an extension $\tilde{\rho }$ to $H$ . Then the representations $\delta \otimes \tilde{\rho }$ for $\delta \in \mathrm{Irr}(H/N)$ are irreducible, distinct for distinct $\delta$ and
\begin{equation*} \mathrm {Ind}^{H}_{N}(\rho ) = \oplus _{\delta \in \mathrm {Irr}(H/N)} \delta ' \otimes \tilde {\rho }, \end{equation*}where $\delta '$ is obtained by composing $\delta$ with the natural projection from $H$ onto $H/N$ . -
(iii) ([Reference Isaacs11], Corollary 11.22) Suppose $G/N$ is cyclic. Let $\rho \in \mathrm{Irr}(N)$ such that $I_G(\rho ) = G$ . Then $\rho$ has an extension to G.
We conclude this section by including a proof of Theorem 1.5.
Proof of Theorem 1.5. Our goal is to define an isomorphism $\gamma \;:\;{\mathrm{H}}^2(G_2, \mathbb C^\times ) \rightarrow{\mathrm{H}}^2(G_1, \mathbb C^\times )$ that gives $\mathbb C$ -twist isomorphism between $G_2$ and $G_1$ . It follows from [Reference Karpilovsky14, Theorem 2.9] and [Reference Hatui and Singla8, Theorem 3.2] that the projective representations of $G_{i}$ are obtained from those of $G_{i}/G'_{\!\!i}$ via inflation and
The map $\tilde{\sigma }$ is an induced isomorphism obtained from $\sigma$ . Hence, $\mathbb{C}^\beta [G_1/G'_{\!\!1}] \cong \mathbb{C}^{\tilde{\sigma }(\beta )}[G_2/G'_{\!\!2}].$ Therefore, it is sufficient to define an isomorphism $\gamma \;:\;{\mathrm{H}}^2(G_2, \mathbb C^\times ) \rightarrow{\mathrm{H}}^2(G_1, \mathbb C^\times )$ such that Figure 1 is commutative. Indeed, such a $\gamma$ is obtained by defining
where $[\alpha _0] \in H^2(G_2/G'_{\!\!2}, \mathbb C^\times )$ is any element such that $\inf _2([\alpha _0]) = [\alpha ]$ .
3. $p$ -groups with $s(G) \leq 2$
In this section, we study the $\mathbb{C}$ -twist isomorphism classes of $p$ -groups with $s(G) \leq 2$ . We first deal with the case of $s(G) \in \{0,1\}$ .
Proof of Lemma 1.1. Niroomand [Reference Niroomand22, Theorem 21, Corollary 23] proved the following classification of finite non-abelian $p$ -groups $G$ with $s(G) \in \{0,1\}$ :
-
(a) $s(G) = 0$ if and only if $G$ is isomorphic to $H_{1}^{1} \times C_{p}^{(n-3)}$ .
-
(b) $s(G) = 1$ if and only if $G$ is isomorphic to $D_{8} \times C_{2}^{(n-2)}$ or $C_{p}^{(4)} \rtimes C_{p}\, (p \neq 2)$ .
We remark that in [Reference Niroomand22], Niroomand uses the corank of a group $G$ (denoted $t(G)$ ) instead of the generalized corank of $G$ . We have used the well-known relation $t(G) = s(G) + (n-2)$ for any non-abelian $p$ -group $G$ to use the results of [Reference Niroomand22]. We observe that among the groups mentioned in (a) and (b), thhere xists at most one group for any given order and fixed $s(G)$ . Since both order and $s(G)$ are invariant of $\mathbb C$ -twist isomorphism, our result follows.
The rest of this section is devoted to the $s(G) = 2$ case.
Proposition 3.1.
-
(i) (a) $E(2) \times C_p^{(n-4)} \sim _{\mathbb C} H_1^{2} \times C_p^{(n-3)},$ for $p \neq 2$
-
(b) $E(2) \times C_2^{(n-4)} \sim _{\mathbb C} Q_8 \times C_2^{(n-3)}$
-
(ii) (a) For $n = 2m+1$ and $m \geq 2$ , $H_m^1 \times C_p^{(n-2m-1)} \sim _{\mathbb C} H_m^2 \times C_p^{(n-2m-1)}$
-
(b) For $n \geq 6$ and $m \geq 2$ , $E(2) \times C_p^{(n-2m-2)} \sim _{\mathbb C} H_m^1 \times C_p^{(n-2m-1)} \sim _{\mathbb C} H_m^2 \times C_p^{(n-2m-1)}.$
Proof. We proceed to prove (i). The proof of (ii) is similar so we only give essential ingredients there and omit the details.
(i)(a) For simplification of notations, we denote $E(2) \times C_p^{(n-4)}$ and $H_1^2 \times C_p^{(n-3)}$ by $G_1$ and $G_2$ , respectively. The groups $G_1$ and $G_2$ have following presentations:
Therefore, $G'_{\!\!i} \cong C_{p}$ and $G_{i}/G'_{\!\!i} \cong C_{p}^{ n-1}$ for $i \in \{1, 2\}$ . Also, in view of Proposition 1.3 of [Reference Karpilovsky14],
This yields the following short exact sequences for $i \in \{1, 2\}$ :
We now define $\delta \;:\; G'_{\!\!1} \rightarrow G'_{\!\!2}$ and $\sigma \;:\; G_1/G'_{\!\!1} \rightarrow G_2/G'_{\!\!2}$ such that the Figure 1 is commutative. Define $\delta$ by $\delta (z_1) = z_2$ and $\sigma$ by
for all $i \in \{1,\ldots, n-4\}$ . We now describe transgression maps for these groups.
Define a section $s_1\;:\;G_1/G'_{\!\!1} \rightarrow G_1$ by
For $u= x_1^i y_1^j \gamma _1^k a_1^{r_1} \cdots a_{n-4}^{r_{n-4}} G'_{\!\!1}$ and $v = x_1^{i^{\prime}} y_1^{j^{\prime}} \gamma _1^{k^{\prime}} a_1^{r^{\prime}_1} \cdots a_{n-4}^{r^{\prime}_{\!n-4}} G'_{\!\!1},$ we have
Hence, a representative of $[\mathrm{tra_1}(\chi )]$ is given by ${\mathrm{tra}}_1(\chi )(u, v)= \chi (z_1^{-ji^{\prime}})$ for $\chi \in \mathrm{Hom}(G'_{\!\!1}, \mathbb C^\times )$ . Define a section $s_2\;:\;G_2/G'_{\!\!2} \rightarrow G_2$ by
For $u= x_2^i y_2^j b_1^{r_1} \cdots b_{n-3}^{r_{n-3}} G'_{\!\!2}$ and $v = x_2^{i^{\prime}} y_2^{j^{\prime}} b_1^{r^{\prime}_1} \cdots b_{n-3}^{r^{\prime}_{\!n-3}} G'_{\!\!2},$ we have
Therefore, a representative of $[\mathrm{tra_2}(\chi )]$ is given by $\mathrm{tra_2}(\chi ) (u,v) = \chi (z_2^{-ji^{\prime}})$ for $\chi \in \mathrm{Hom}(G'_{\!\!2}, \mathbb C^\times )$ . This combined with the given isomorphisms $\delta$ and $\sigma$ gives the commutativity of Figure 1. Now, the result follows as a direct consequence of Theorem 1.5.
For $(i)(b)$ , proof is along the same lines as that of $(i)(a)$ with only difference that $Q_8 \times C_2^{(n-3)}$ has the following presentation:
We leave the rest of the details for the reader.
(ii) We denote the groups $E(2) \times C_p^{(n-2m-2)}$ , $H_m^1 \times C_p^{(n-2m-1)}$ and $H_m^2 \times C_p^{(n-2m-1)}$ by $G^m_{1}$ , $G^m_{2}$ and $G^m_{3}$ , respectively. Note that if $m \neq m'$ , then for any $i,j \in \{ 1, 2,3\},$ the complex group algebras of $G_{i}^m$ and $G_j^{m^{\prime}}$ are not isomorphic. Further, observe that for any $m \geq 2$ , the order of $G_{1}^m$ is $p^n$ such that $n \geq 6.$ Therefore, for some $n \geq 6,$ if $G_{i}^{m}$ is $\mathbb{C}$ -twist isomorphic to $G_j^{m^{\prime}},$ then it implies that $m = m'$ . Similarly, when $n = 5,$ a necessary condition for the $\mathbb{C}$ -twist isomorphism of $G_1^{m}$ and $G_2^{m^{\prime}}$ is that $ m = m'$ . Therefore, from now onwards, we fix $m$ and prove the result.
The commutator subgroup of $G_{i}^m$ is central and is isomorphic to $C_{p};$ and $G_{i}^m/(G_{i}^m)' \cong C_p^{(n-1)}.$ Further, since for any $i \in \{1, 2, 3\},$ ${\mathrm{H}}^2(G_{i}^m, \mathbb C^\times ) \cong C_p^{ \frac{n^2-3n}{2} }$ , we get the following short exact sequences:
As in (i), the proof of $\mathbb C$ -twist isomorphism follows by considering the image of the $\mathrm{tra_i}$ for $i \in \{1, 2, 3\}$ and by proving the commutativity of Figure 1. This is obtained by using the following presentation of groups $G_{i}^m.$
Below we calculate $\mathrm{tra}_1$ explicitly and leave the details for ${\mathrm{tra}}_2$ and ${\mathrm{tra}}_3$ as those are similar. By the given presentation of $G_1^m$ , we have $(G_1^m)' = \lt \gamma ^p\gt$ . Define a section $s\;:\;G_1^m/(G_1^m)' \rightarrow G_1^m$ by
Note that for any two elements
of $G_1^m/(G_1^m)^{\prime},$ we have $ s(u)s(v)s(uv)^{-1} = \gamma ^{-p \sum _{l=1}^mj_l i^{\prime}_l}.$ Therefore, for any $\chi \in \mathrm{Hom}((G_1^m)', \mathbb C^\times )$ , a representative of $[\mathrm{tra_1}(\chi )]$ is given by $\mathrm{tra_1}(\chi )(u,v) = \chi (z^{-\sum _{l=1}^mj_l i^{\prime}_l}).$ By a similar computation of ${\mathrm{tra}}_2$ and ${\mathrm{tra}}_3$ , we obtain that for all $i \in \{1, 2, 3\},$ the groups $G_{i}^m$ pairwise satisfy the hypothesis of Theorem 1.5 and hence are $\mathbb C$ -twist isomorphic.
We now complete the details regarding the $\mathbb{C}$ -twist isomorphism classes for $p$ -groups with $s(G)=2$ .
Proof of Theorem 1.2. It follows from [Reference Niroomand24, Theorem 11] that for any fixed $p$ , thhere xists only one $p$ -group of order $p^3$ with $s(G) = 2$ and so it forms a singleton $\mathbb C$ -twist class. We now consider cases when $n \geq 4.$
$n=4$ : Any group of order $p^4$ with $s(G) = 2$ is isomorphic to one of the following:
-
$E(2)$
-
$H_1^{2} \times C_p, p \neq 2$
-
$Q_8 \times C_2$
-
$\langle a,b\,|\,a^4=1,b^4=1,[a,b,a]=[a,b,b]=1, [a,b]=a^2b^2 \rangle$
-
$ \langle a,b,c\,|\,a^2=b^2=c^2=1, abc=bca=cab \rangle$
-
$\langle a,b\,|\,a^{p^2}=1,b^{p}=1, [a,b,a]=[a,b,b]=1 \rangle$
-
$\langle a,b\,|\, a^9=b^3=1, [a,b,a] =1, [a,b,b]=a^6, [a,b,b,b]=1 \rangle$
-
$\langle a,b\,|\, a^p=1, b^p=1, [a,b,a]=[a,b,b,a]=[a,b,b,b]=1 \rangle$ $(p \neq 3).$
Here, the group $\langle a,b,c\,|\,a^{2}=b^{2}=c^{2} = 1,abc=bca=cab \rangle$ is isomorphic to $E(2).$ As mentioned in Theorem $4.3$ in [Reference Margolis and Schnabel17], any non-singleton $\mathbb{C}$ -twist isomorphism class of groups of order $p^4$ consists of two groups, when $p=2;$ and of three groups, when $p$ is an odd prime. Thus, comparing with the groups given in Tables 3 and 4 in [Reference Margolis and Schnabel17], we obtain the following non-singleton $\mathbb C$ -twist isomorphism classes of groups of order $p^4$ with generalized corank $2$ :
-
$\mathbb{Q}_{8} \times C_{2} \sim _{\mathbb{C}} E(2),$ when $p=2$
-
$E(2) \sim _{\mathbb{C}} H_1^1 \times C_p \sim _{\mathbb{C}} \langle a,b\,|\,a^{p^2}=1,b^{p}=1, [a,b,a]=[a,b,b]=1 \rangle$ , when $p$ is odd.
Thus, each of the remaining groups of order $p^4$ in the above list constitutes a $\mathbb C$ -twist isomorphism class of size $1.$
$n \geq 5:$ Any group of order $p^n$ with $n \geq 5$ and $s(G) = 2$ is isomorphic to one of the following:
-
$E(2) \times C_p^{(n-2m-2)}$
-
$H_1^{2} \times C_p^{(n-3)}, p \neq 2$
-
$Q_8 \times C_2^{(n-3)}$
-
$H_m^1 \times C_p^{(n-2m-1)}$
-
$H_m^2 \times C_p^{(n-2m-1)}$
-
$C_{p} \times (C_{p}^4 \rtimes _{\theta } C_{p}),\, p \neq 2.$
The derived subgroup of $C_{p} \times (C_{p}^4 \rtimes _{\theta } C_{p}),\,p \neq 2$ is of order $p^2$ ; whereas the derived subgroup of the rest of the groups in the above list is of order $p$ . Therefore, by comparing the complex group algebras, we obtain that for a fixed odd prime $p,$ the group $C_{p} \times (C_{p}^4 \rtimes _{\theta } C_{p})$ forms a singleton $\mathbb C$ -twist isomorphism class. Finally, Proposition 3.1 completes the classification of the rest of the groups into $\mathbb C$ -twist isomorphism classes.
4. $p$ -groups with $s(G)=3$
In this section, we proceed with the determination of the $\mathbb{C}$ -twist isomorphism classes of the $p$ -groups with $s(G) = 3.$ The following result, using the notations of [Reference James12], gives a complete list of $p$ -groups with $s(G) = 3$ .
Theorem 4.1. ([Reference Hatui7], Theorem 1.1) Let $G$ be a non-abelian $p$ -group of order $p^{n}$ with $s(G)=3$ . Let $r_p$ be the smallest positive integer which is a non-quadratic residue mod $(p)$ .
-
(a) For an odd prime $p$ , $G$ is isomorphic to one of the following groups:
-
(i) $\phi _{2}(22)= \langle \alpha,\,\alpha _{1},\,\alpha _{2}\,|\,[\alpha _{1},\alpha ]=\alpha ^{p}=\alpha _{2},\,\alpha _{1}^{p^{2}}=\alpha _{2}^{p}=1 \rangle$
-
(ii) $\phi _{3}(211)a= \langle \alpha, \,\alpha _{1},\alpha _{2},\,\alpha _{3}\,|\,[\alpha _{1},\alpha ]=\alpha _{2},\,[\alpha _{2},\alpha ] =\alpha ^{p}=\alpha _{3}, \alpha _{1}^{(p)}=\alpha _{2}^{p}=\alpha _{3}^{p}=1\rangle$
-
(iii) $\phi _{3}(211)b_{r} = \langle \alpha, \,\alpha _{1},\alpha _{2},\alpha _{3}\,|\,[\alpha _{1},\alpha ]=\alpha _{2},\,[\alpha _{2},\alpha ]^r =\alpha _{1}^{(p)}=\alpha _{3}^r,\,\alpha ^{p}=\alpha _{2}^{p}=\alpha _{3}^{p}=1 \rangle,$ where $r$ is either $1$ or $r_p.$
-
(iv) $\phi _{2}(2111)c= \phi _{2}(211)c \times C_{p}$ , where $\phi _{2}(211)c = \langle \alpha,\alpha _{1},\alpha _{2}\,|\,[\alpha _{1},\alpha ]=\alpha _{2},\,\alpha ^{p^{2}}=\alpha _{1}^{p}=\alpha _{2}^{p}=1 \rangle$
-
(v) $\phi _{2}(2111)d= ES_{p}(p^{3}) \times C_{p^{2}}$
-
(vi) $\phi _{3}(1^{5}) = \phi _{3}(1^{4}) \times C_{p}$ , where $\phi _{3}(1^{4})= \langle \alpha, \alpha _{1},\alpha _{2},\alpha _{3}\,|\,[\alpha _{i},\alpha ]=\alpha _{i+1},\,\alpha ^{p}=\alpha _{i}^{(p)}=\alpha _{3}^{p}=1\,(i=1,2) \rangle$
-
(vii) $\phi _{7}(1^{5})= \langle \,\alpha, \,\alpha _{1},\alpha _{2},\alpha _{3}, \beta \,|\, \,[\alpha _{i},\alpha ]=\alpha _{i+1}, [\alpha _{1},\beta ] =\alpha _{3},\,\alpha ^{p}=\alpha _{1}^{(p)}=\alpha _{i+1}^{p}=\beta ^{p}=1\,(i=1,2) \rangle$
-
(viii) $\phi _{11}(1^{6}) = \langle \,\alpha _{1}, \,\beta _{1},\alpha _{2},\beta _{2}, \alpha _{3}, \beta _{3}\,|\,\,[\alpha _{1},\alpha _{2}]=\beta _{3},\,[\alpha _{2},\alpha _{3}] =\beta _{1},\,[\alpha _{3},\alpha _{1}] =\beta _{2},\alpha _{i}^{(p)}=\beta _{i}^{p}\,(i=1,2,3) \rangle$
-
(ix) $\phi _{12}(1^{6})=ES_{p}(p^{3}) \times ES_{p}(p^{3})$
-
(x) $\phi _{13}(1^{6}) = \langle \alpha _{1},\alpha _{2},\alpha _{3}, \alpha _{4}, \beta _{1},\beta _{2} \,|\,[\alpha _{1},\alpha _{i+1}]=\beta _{i},\,[\alpha _{2},\alpha _{4}]= \beta _{2},\,\alpha _{i}^{p}=\alpha _{3}^{p}=\alpha _{4}^{p}=\beta _{i}^{p}=1 (i=1,2) \rangle$
-
(xi) $\phi _{15}(1^{6})= \langle \alpha _{1},\alpha _{2},\alpha _{3}, \alpha _{4}, \beta _{1},\beta _{2} \,|\,[\alpha _{1},\alpha _{i+1}]=\beta _{i},\,[\alpha _{3},\alpha _{4}]= \beta _{1},\,[\alpha _{2},\alpha _{4}]= \beta _{2}^{g},\,\alpha _{i}^{p}=\alpha _{3}^{p}=\alpha _{4}^{p}=\beta _{i}^{p}=1 (i=1,2) \rangle$ , where $g$ is the smallest positive integer, which is a primitive root modulo $p$
-
(xii) $(C_{p}^{(4)} \rtimes C_{p}) \times C_{p}^{2}$ .
-
-
(b) For $p=2$ , $G$ is isomorphic to one of the following groups:
-
(xiii) $C_{2}^{4} \rtimes C_{2}$
-
(xiv) $C_{2} \times ((C_{4}\times C_{2}) \rtimes C_{2})$
-
(xv) $C_{4} \rtimes C_{4}$
-
(xvi) $D_{16}$ , the dihedral group of order 16.
-
As mentioned earlier, the $\mathbb{C}$ -twist isomorphism classes of the groups of order $p^4$ were described by Margolis-Schnabel [Reference Margolis and Schnabel17]. We now consider the groups of order $p^5$ with $s(G) = 3$ . Let $H_1$ and $H_2$ denote the groups $\phi _2(2111)d$ and $\phi _2(2111)c,$ respectively. We proceed to prove that $H_1$ and $H_2$ are $\mathbb{C}$ -twist isomorphic. We use the following general result to prove this.
Lemma 4.2. Let $G_1$ and $G_2$ be two finite groups with $\widetilde{G_1}$ and $\widetilde{G_2}$ as their representation groups, respectively. For $i \in \{1, 2\}$ , let $A_i$ be a central subgroup of $\widetilde{G_{i}}$ such that $\widetilde{G_{i}}/A_i \cong G_{i}$ and the transgression maps $\mathrm{tra_i}\;:\; \mathrm{Hom}(A_i, \mathbb C^\times ) \rightarrow{\mathrm{H}}^2(G_{i}, \mathbb C^\times )$ are isomorphisms. Let $\sigma \;:\; \mathrm{Hom}(A_1, \mathbb C^\times ) \rightarrow \mathrm{Hom}(A_2, \mathbb C^\times )$ be an isomorphism such that the following sets are in a dimension preserving bijection for every $\chi \in \mathrm{Hom}(A_1, \mathbb C^\times )$ :
Then $G_1$ and $G_2$ are $\mathbb C$ -twist isomorphic.
Proof. Consider the following diagram:
Define $\tilde{\sigma }\;:\;{\mathrm{H}}^2(G_1, \mathbb C^\times ) \rightarrow{\mathrm{H}}^2(G_2, \mathbb C^\times )$ by $ \tilde{\sigma }({\mathrm{tra}}_1(\chi )) = \mathrm{tra}_2(\sigma (\chi ))$ for $\chi \in \mathrm{Hom}(A_1, \mathbb C^\times )$ . It is easy to see that $\tilde{\sigma }$ is a group isomorphism. By Theorem 2.2, the dimension preserving bijection
for any $\chi \in \mathrm{Hom}(A_1, \mathbb C^\times )$ gives
where $[\alpha _1] = \mathrm{tra}_1(\chi )$ and $[\alpha _2] = \mathrm{tra}_2(\sigma (\chi ))$ . Therefore, $\tilde{\sigma }$ gives the required $\mathbb C$ -twist isomorphism between $G_1$ and $G_2$ .
Note that $H_1 = E_1 \times C_{p^{2}}$ and $H_2 = \langle \alpha, \alpha _1, \alpha _2 \mid [\alpha _1, \alpha ] = \alpha _2, \alpha ^{p^2} = \alpha _1^p = \alpha _2^p = 1 \rangle \times \langle \alpha _3 \rangle$ . Define the following groups:
and
Lemma 4.3. The groups $\widetilde{H_1}$ and $\widetilde{H_2}$ are representation groups of $H_1$ and $H_2$ , respectively.
Proof. Here, we give a proof for $H_1$ . The proof for $H_2$ is along the same lines so we omit that part. The group $H_1$ has the following presentation:
Consider the projection map from $\widetilde{H_1}$ onto $H_1$ obtained by mapping $x,y,z,\alpha$ to $x,y,z,\alpha$ , respectively, and all $\alpha _i$ to $1$ . Let $K_1$ be the kernel of this projection map. Then $|K_1| = |{\mathrm{H}}^2(H_1, \mathbb C^\times )| = p^4$ and $K_1 \subseteq Z(\widetilde{H_1}) \cap [\widetilde{H_1}, \widetilde{H_1}]$ . Therefore, by [Reference Karpilovsky14, Theorem 3.7 (Chapter 3)], $\widetilde{H_1}$ is a representation group of $H_1$ .
Proposition 4.4. The groups $\widetilde{H_1}$ and $\widetilde{H_2}$ satisfy the following:
Furthermore, for the subgroups $A = \langle \alpha _1, \alpha _2, \alpha _3, \alpha _4 \rangle$ and $B = \langle x,y,z,w \rangle$ of $\widetilde{H_1}$ and $\widetilde{H_2}$ respectively, thehere ists an isomorphism $\sigma \;:\; \widehat{A} \rightarrow \widehat{B}$ such that the following sets are in a dimension preserving bijection for every $\chi \in \hat{A}$ :
Proof. Representations of $\widetilde{H_1}$ : We first justify the representations of $\widetilde{H_1}$ . By the definition of $\widetilde{H_1}$ , the derived subgroup of $\widetilde{H_{1}}$ (denoted $\widetilde{H}^{'}_{1}$ ) is $\langle \alpha _{1},\alpha _{2},\alpha _{3},\alpha _{4}, z\rangle$ and the center of $\widetilde{H_{1}}$ is $\langle \alpha _{1},\alpha _{2},\alpha _{3},\alpha _{4}, \alpha ^p \rangle$ . By considering the quotient group $\widetilde{H_{1}}$ / $\widetilde{H}^{'}_{1}$ , we obtain that $\widetilde{H_1}$ has exactly $p^{4}$ one-dimensional representations.
We next consider the abelian normal subgroup $N = \langle \alpha _{1},\alpha _{2},\alpha _{3},\alpha _{4},\alpha,z \rangle$ of $\widetilde{H_{1}}$ . The group $N$ has order $p^7$ . By Frobenius reciprocity and Theorem 2.3, every irreducible representation of $\widetilde{H_1}$ has dimension either $1$ , $p$ or $p^2$ . We have already justified all one-dimensional representations of $\widetilde{H_{1}}$ . Our next goal is to determine all $p$ and $p^2$ dimensional representations of $\widetilde{H_1}$ .
Let $\chi \in \operatorname{Irr}(N)$ such that $\chi (\alpha _{1})= \xi ^{i_{1}}$ , $\chi (\alpha _{2})= \xi ^{i_{2}}$ , $\chi (\alpha _{3})= \xi ^{i_{3}}$ and $\chi (\alpha _{4})= \xi ^{i_{4}}$ , where $\xi$ is a primitive $p^{th}$ root of unity and $0 \leq i_{1},i_{2},i_{3},i_{4} \leq (p-1)$ . We determine the stabilizer (or inertia group) of $\chi$ in $\widetilde{H_1}$ , denoted by $I_{\widetilde{H_{1}}}(\chi )$ . Recall from Section 2, $I_{\widetilde{H_{1}}}(\chi ) = \{g \in \widetilde{H_{1}} \mid \chi ^g = \chi \}.$ By definition of $I_{\widetilde{H_{1}}}(\chi )$ , $N \leq I_{\widetilde{H_{1}}}(\chi )$ . We will obtain the following information from $|I_{\widetilde{H_{1}}}(\chi )|$ and by the virtue of Theorem 2.3.
-
1. $\Big{|}{\frac{I_{\widetilde{H_{1}}}(\chi )}{N}}\Big{|} = 1$ implies every $\rho \in \mathrm{Irr}(\widetilde{H_{1}} \mid \chi )$ satisfies $\dim (\rho ) = p^2$ .
-
2. $\Big{|}{\frac{I_{\widetilde{H_{1}}}(\chi )}{N}}\Big{|} = p$ implies every $\rho \in \mathrm{Irr}(\widetilde{H_{1}} \mid \chi )$ satisfies $\dim (\rho ) = p$ .
-
3. $\Big{|}{\frac{I_{\widetilde{H_{1}}}(\chi )}{N}}\Big{|} = p^2$ implies every $\rho \in \mathrm{Irr}(\widetilde{H_{1}} \mid \chi )$ satisfies $\dim (\rho ) \in \{1, p\}$ .
As we already have information regarding dimension one representations, we will easily obtain the rest of the information regarding $\mathbb C[\widetilde{H_{1}}]$ from the description of $I_{\widetilde{H_{1}}}(\chi )$ . Consider $g = x^{i}y^{j}n$ , with $n \in N$ and $i,j \in \{0, 1, \ldots, p-1\}$ . Recall that every $m \in N$ satisfies $m = \alpha ^{e}z^{f}h$ for some $h \in Z(\widetilde{H_1}).$ Therefore, we have
if and only if $\chi (x^{i}y^{j}\alpha ^{e}z^{f} y^{-j}x^{-i}) = \chi (\alpha ^{e}z^{f}).$ Since
we obtain that $x^i y^j n \in I_{\widetilde{H_{1}}}(\chi )$ if and only if $\chi (\alpha _1^{if} \alpha _2^{jf} \alpha _3^{ie}\alpha _4^{je}) = 1$ . This is equivalent to saying that $\xi ^{i_1if+i_2jf+i_3ie+i_4je} = 1.$
We now consider various cases of irreducible representations of $N$ . Note that in each of the cases discussed below, all the computations for $i$ and $j$ are done modulo $p$ .
-
Case I: Consider $\chi \in \mathrm{Irr}(N)$ such that $i_1 = i_2 = i_3 = i_4 = 0$ . These are exactly $p^3$ in number. Among these there are $p^2$ characters which act trivially on $z$ and hence on $\widetilde{H}^{'}_{1}$ . These give $p^4$ one-dimensional characters of $\widetilde{H_{1}}$ . The other $(p^3-p^2)$ characters of $N$ , by Theorem 2.3, of this case give irreducible characters of $\widetilde{H_{1}}$ of dimension $p$ and therefore we obtain $p^4-p^3$ many characters of $\widetilde{H_{1}}$ of dimension $p$ .
-
Case II: When any three of $i_1, i_2, i_3, i_4$ are $0$ and the fourth one is non-zero, then $g = x^i y^j n \in I_{\widetilde{H_{1}}}(\chi )$ if and only if either $i$ or $j$ is $0$ . Thus, $|I_{\widetilde{H_{1}}}(\chi )| = p^8.$
-
Case III: When any two of $i_1, i_2, i_3, i_4$ are $0$ and the other two are non-zero, then $i$ is a non-zero multiple of $j$ or one of them is zero and other can take any value. Hence, $|I_{\widetilde{H_{1}}}(\chi )| = p^8.$
-
Case IV: When any three of $i_1, i_2, i_3, i_4$ are non-zero and the fourth one is $0$ , then $i = j = 0$ and hence $I_{\widetilde{H_{1}}}(\chi ) = N.$
-
Case V: Assume that each $i_t,$ where $t \in \{1, 2, 3, 4\},$ is non-zero. When $f = 0$ and $e = 1, i = \frac{-i_4j}{i_3};$ and when $e = 0$ and $f = 1, i = \frac{-i_2j}{i_1}.$ Therefore, $\frac{-i_4j}{i_3} = \frac{-i_2j}{i_1},$ which holds if and only if $(i_4i_1-i_2i_3)j = 0.$ Now if $i_4i_1 \neq i_2i_3,$ then $i = j =0$ and hence $I_{\widetilde{H_{1}}}(\chi ) = N.$
Here, note that $(p-1)^3$ many characters of $N$ satisfy $i_4i_1 = i_2i_3$ and their inertia group is of order $p^8.$ Thus, the remaining $((p-1)^4-(p-1)^3)$ characters have inertia group $N.$
Considering the case of $(p^7-p^3)$ many characters of $N,$ discussed in Cases II-V, the inertia group of $ p^3(p-1)^3(p+2)$ characters is $N,$ and for the other $ p^3(p-1)(p^2+4p-1)$ characters, it is of order $p^8.$ Hence, we obtain the following description of the group algebra of $\widetilde{H_{1}}$ .
Representations of $\widetilde{H_{2}}$ : We have $\widetilde{H}^{'}_{2} = \langle x, y, z, w, \alpha _{2} \rangle$ and $Z(\widetilde{H_{2}}) = \langle \alpha ^p, x, y, z, w \rangle$ . Clearly, there are exactly $p^{4}$ number of linear characters of $\widetilde{H_{2}}$ . Consider the subgroup
of $\widetilde{H_{2}}$ . This is an abelian normal group of order $p^7$ . Let $\chi \in \mathrm{Irr}(M)$ such that $\chi (x)= \xi ^{i_{1}}$ , $\chi (y)= \xi ^{i_{2}}$ , $\chi (z)= \xi ^{i_{3}}$ , and $\chi (w)= \xi ^{i_{4}},$ where $\xi$ is a primitive $p^{th}$ root of unity and $0 \leq i_{1},i_{2},i_{3},i_{4} \leq (p-1)$ . Let $g = \alpha ^{i} \alpha _1^{j}m$ , where $m \in M,$ be an element of $I_{G}(\chi ).$ Therefore, for any $m^{\prime} = \alpha _2^{k}\alpha _3^{l}h \in M,$ where $h \in Z(\widetilde{H_1}),$ we have $\chi ^{\alpha ^{i} \alpha _1^{j}}(\alpha _2^{k}\alpha _3^{l}h) = \chi (\alpha _2^{k}\alpha _3^{l}h).$ Computations, similar to $\widetilde{H_{1}}$ , yield that $g \in I_{\widetilde{H_{2}}}(\chi )$ if and only if $\xi ^{i_1jk+i_2ik+i_3(-jl)+i_4(-il)} = 1$ and hence the following cases arise:
-
Case I: When any three of $i_1, i_2, i_3, i_4$ are $0$ and the fourth one is non-zero, then either $i$ or $j$ is $0.$ Thus, $|I_{\widetilde{H_{2}}}(\chi )| = p^8.$
-
Case II: When any two of $i_1, i_2, i_3, i_4$ are $0$ and the other two are non-zero, then $i$ is a non-zero multiple of $j$ or one of them is zero and other can take any value. Hence, $|I_{\widetilde{H_{2}}}(\chi )| = p^8.$
-
Case III: When any three of $i_1, i_2, i_3, i_4$ are non-zero and the fourth one is $0$ , then $i = j = 0$ and hence $I_{\widetilde{H_{2}}}(\chi ) = M.$
-
Case IV: Assume that each $i_t,$ where $t \in \{1, 2, 3, 4\},$ is non-zero. When $l = 0$ and $k = 1, i = \frac{-i_1j}{i_2};$ and when $k = 0$ and $l = 1, i = \frac{-i_3j}{i_4}.$ Therefore, $\frac{-i_3j}{i_4} = \frac{-i_1j}{i_2},$ which holds if and only if $(i_4i_1-i_2i_3)j = 0.$ Now if $i_4i_1 \neq i_2i_3,$ then $i = j =0$ and hence $I_G(\chi ) = M.$ On the other hand, if $i_4 = \frac{i_2i_3}{i_1},$ then $|I_G(\chi )| = p^8.$
Therefore, in this case the inertia group of $(p-1)^3$ many characters is of order $p^8$ and for the remaining $((p-1)^4-(p-1)^3)$ characters it is $M.$
Similar to the proof of $\widetilde{H_{1}}$ , all the above cases along with Theorem 2.3 give
We now proceed to define required isomorphism $\sigma \;:\;\widehat{A} \rightarrow \widehat{B}$ . For this, define an isomorphism $\sigma '\;:\; A \rightarrow B$ by $\sigma '(\alpha _1) = x, \sigma '(\alpha _2) = y, \sigma '(\alpha _3) = z, \sigma '(\alpha _4) = w.$ This defines an isomorphism, denoted by $\sigma$ , between $\widehat{A}$ and $\widehat{B}$ . From above discussion, by considering various cases of $i_j$ for $j \in \{1, \ldots, 4\}$ , we obtain a dimension preserving bijection between the following sets for every $\chi \in \widehat{A}$ :
Proposition 4.5. The groups $H_1$ and $H_2$ are $\mathbb C$ -twist isomorphic.
Proof. This follows from Lemmas 4.2, 4.3 and Proposition 4.4.
Lemma 4.6. $\mathbb C[\phi _{3}(1^{5})] \ncong \mathbb C[\phi _{7}(1^{5})]$ .
Proof. It follows from the presentations of $\phi _{3}(1^{5})$ and $\phi _{7}(1^{5})$ that the nilpotency class of both the groups is $3.$ Now, consider the abelian normal subgroup $N_1 = \langle \alpha _1, \alpha _2, \alpha _3, \beta \rangle$ of $\phi _3(1^5).$ Since it is of index $p,$ each irreducible representation of $\phi _3(1^5)$ is of dimension at most $p.$
Now note that the derived subgroup of $\phi _{7}(1^5)$ is $\langle \alpha _2 \rangle \times \langle \alpha _3 \rangle$ and its center is $\langle \alpha _3 \rangle$ . Consider the abelian normal subgroup $N_2 = \langle \alpha _1, \alpha _2, \alpha _3 \rangle$ of $\phi _{7}(1^5)$ . Let $\chi \in \mathrm{Irr}(N_2)$ such that $\chi (\alpha _1) = \zeta ^{i_1}, \chi (\alpha _2) = \zeta ^{i_2}$ and $\chi (\alpha _3) = \zeta ^{i_3}$ , where $\zeta$ is a primitive $p$ -th root of unity and $0 \leq i_1, i_2, i_3 \leq (p-1).$ Assume that for some $0 \leq i, j \leq p-1,$ $\alpha ^i \beta ^j$ stabilizes $\chi .$ Let $\alpha _{1}^{a}\alpha _{2}^{b}\alpha _{3}^{c}\in N_{2}$ .
Since the group $\phi _{7}(1^5)$ is of nilpotency class $3$ ,
Thus, $\alpha ^{i}\beta ^{j}$ stabilizes $\chi$ if, and only if, $\zeta ^{-aii_2-(ib+aj+a\binom{i}{2})i_3} = 1.$ When $i_2 = 0$ and $i_3 \neq 0,$ then for $a=0$ and $b = \frac{-1}{i_3},$ we have $\zeta ^{i}=1;$ which implies that $i=0.$ Further, $a=\frac{-1}{i_3}$ (note that $i_{3}$ is invertible modulo $p$ ) gives $\zeta ^{j} =1$ . Hence, $j=0$ and it follows that the inertia group of $\chi$ in $\phi _{7}(1^{5})$ is $N_2.$ Therefore, by Theorem 2.3, the character of $\phi _7(1^5)$ induced from $\chi$ is irreducible of degree $p^2.$ Since $\phi _3(1^5)$ has no irreducible representations of dimension $p^2,$ the complex group algebras of $\phi _3(1^5)$ and $\phi _7(1^5)$ are not isomorphic.
Proof of Theorem 1.3. From Theorem 4.1, it is clear that every $p$ -group with $s(G) = 3$ has order $p^n$ where $n \in \{4, \ldots, 7\}$ .
In the following, we separately consider the cases of $n$ with $4 \leq n \leq 7$ :
n = 4. For the proof of this case, one can refer to [Reference Margolis and Schnabel17, Theorem 4.3].
n = 5. When $p$ is an odd prime, it follows from Theorem 4.1 that the only groups of order $p^5$ with $s(G) = 3$ are $\phi _3(1^5)$ , $\phi _7(1^5), H_1$ and $H_2$ . The derived subgroups of $\phi _3(1^5)$ and $\phi _7(1^5)$ are elementary abelian of order $p^2$ and of $H_1$ and $H_2$ are of order $p.$ Thus, the groups $\phi _3(1^5)$ and $\phi _7(1^5)$ have $p^3$ linear characters; whehere $H_1$ and $H_2$ have $p^4$ linear characters. Therefore, no group in the set $\{\phi _3(1^5), \phi _7(1^5)\}$ can be $\mathbb{C}$ -twist isomorphic to any group in $\{H_1, H_2\}.$ Now it follows from Lemma 4.6 and Proposition 4.5 that in this case the only non-singleton $\mathbb{C}$ -twist isomorphism class is constituted by $H_1$ and $H_2.$
When $p = 2$ , $T_1 = C_{2}^{4} \rtimes C_{2}$ and $T_2 = C_{2} \times ((C_{4}\times C_{2}) \rtimes C_{2})$ are the only two $2$ -groups of order $32$ that have generalized corank $3$ . The GAP ID of these groups is [32,27] and [32,22] and it can be checked using GAP [5] that the size of the derived subgroup of $T_1$ is $4$ and that of $T_2$ is $2.$ Thus, the complex group algebras of these groups are not isomorphic and hence each of these groups constitutes a singleton $\mathbb{C}$ -twist isomorphism class.
n = 6. The groups of order $p^6$ with $s(G) = 3$ are $\phi _{11}(1^6), \phi _{12}(1^6), \phi _{13}(1^6)$ and $\phi _{15}(1^6).$ Note that the size of the commutator subgroup of $\phi _{11}(1^6)$ is $p^3$ and of the rest of the groups is $p^2.$
It can be checked that $\phi _{12}(1^6) = ES_p(p^3) \times ES_p(p^3)$ has $2p^2(p-1)$ inequivalent irreducible representations of dimension $p$ and $(p-1)^2$ of dimension $p^2.$ Further, it follows from [Reference James12, Table 4.1] that $\phi _{13}(1^6)$ has $(p^3-p^2)$ representations of dimension $p$ ; whereas $\phi _{15}(1^6)$ has no representation of dimension $p$ . Thus, the complex group algebras of the groups of order $p^6$ with generalized corank $3$ are not isomorphic. It establishes the desired result.
n = 7. There is a unique group of order $p^7$ with $s(G) = 3$ which is isomorphic to $C_{p}^{(4)} \rtimes C_{p} \times C_{p}^{2}$ . Therefore, it constitutes a singleton $\mathbb C$ -twist isomorphism class.
Acknowledgment
The authors are greatly thankful to the referee for their thorough review and insightful comments on this article. Their constructive feedback has been invaluable in improving the overall presentation of this work. GK acknowledges the research support of the National Board for Higher Mathematics, Department of Atomic Energy, Govt. of India (0204/16(7)/2022/R&D-II/11978). PS thanks the research support of SERB-POWER grant (SPG/2022/001099) by the Government of India.
Competing interests
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.