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Free rank of symmetry of products of Dold manifolds

Published online by Cambridge University Press:  30 March 2023

Pinka Dey*
Affiliation:
Statistics and Mathematics Unit, Indian Statistical Institute, B. T. Road, Kolkata 700108, India (pinkadey11@gmail.com)
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Abstract

Dold manifolds $P(m,n)$ are certain twisted complex projective space bundles over real projective spaces and serve as generators for the unoriented cobordism algebra of smooth manifolds. The paper investigates the structure of finite groups that act freely on products of Dold manifolds. It is proved that if a finite group G acts freely and $ \mathbb{Z}_2 $ cohomologically trivially on a finite CW-complex homotopy equivalent to ${\prod_{i=1}^{k} P(2m_i,n_i)}$, then $G\cong (\mathbb{Z}_2)^l$ for some $l\leq k$ (see Theorem A for the exact bound). We also determine some bounds in the case when for each i, ni is even and mi is arbitrary. As a consequence, the free rank of symmetry of these manifolds is determined for cohomologically trivial actions.

Type
Research Article
Copyright
© The Author(s), 2023. Published by Cambridge University Press on Behalf of The Edinburgh Mathematical Society.

1. Introduction

The famous topological spherical space form problem posed by Hopf [Reference Hopf18] asks for a classification of manifolds with universal cover homeomorphic to the n-dimensional sphere S n, where n > 1. This is equivalent to determining all finite groups that can act freely on S n. Smith [Reference Smith29] showed that such a group G must have periodic cohomology, that is, G does not contain a subgroup of the form $ \mathbb{Z}_p \oplus \mathbb{Z}_p$ for any prime p.

A natural generalization of the above problem is to classify all finite groups that can act freely on products of finitely many spheres. More generally, one can ask a similar question for arbitrary topological spaces. This led to the concept of free rank of symmetry of a topological space, defined as follows:

Definition 1.1. Let X be a finite CW-complex and p be a prime number. The free p-rank of symmetry of X, denoted by ${\operatorname{frk}}_p(X)$, is the largest r such that $(\mathbb{Z}_p)^r$ acts freely on X. The smallest value of ${\operatorname{frk}}_p(X)$ over all primes p is called the free rank of symmetry. We use the terminology cohomological free 2-rank, $ c-\operatorname{frk}_2(X) $, to refer the largest value of r such that $ (\mathbb{Z}_2)^r $ acts freely on X with a trivial action on $ \mathbb{Z}_2 $ cohomology. They satisfy the obvious relation $ c-\operatorname{frk}_2(X) \le \operatorname{frk}_2(X) $.

By Smith’s result, if n is odd then ${\operatorname{frk}}_p \,(S^ n)= 1 $ for all primes p, and when n is even, then $ {\operatorname{frk}}_p \,(S^ n)= 1$ if p = 2 and 0 if p > 2. For products of finitely many spheres, the following well-known problem can be found in various places, for example, see [Reference Adem and Browder1, Question 7.2] and [Reference Adem, Davis, Daverman and Sher2, p. 28].

Conjecture 1.2.

If $ (\mathbb{Z}_p)^r $ acts freely on $S^{n_1}\times S^{n_2} \times \cdots \times S^{n_k} $, then $ r\leq k$.

Carlsson [Reference Carlsson6] proved the above conjecture for homologically trivial actions on products of equidimensional spheres. Adem and Browder [Reference Adem and Browder1] resolved the homological non-trivial case except in the cases p = 2 and $ n=1, 3, 7 $. Later, Yalçin [Reference Yalçin32] established that ${\operatorname{frk}}_2((S^1)^k)=k $. The most general result which settles a stable form of the above conjecture is due to Hanke [Reference Hanke16, Theorem 1.3], which states that

\begin{equation*}{{\operatorname{frk}}_p}(S^{n_1} \times \cdots \times S ^{n_k})=k_0 \quad \textrm{if} \ p\gt3(n_1+\cdots+n_k),\end{equation*}

where k 0 is the number of odd-dimensional spheres in the product $ S^{n_1} \times \cdots \times S ^{n_k} $. In [Reference Okutan and Yalçin25, Theorem 1.2], Okutan and Yalçin settle the conjecture in the case when the dimensions of the spheres are high compared to all the differences between the dimensions. To our knowledge, the general case remains open.

For products of even-dimensional spheres, Cusick [Reference Cusick10] proved that if a finite group G acts freely and $ \mathbb{Z}_2 $-cohomologically trivially on $S^{2n_1} \times \cdots \times S ^{2n_k}$, then $G\cong (\mathbb{Z}_2)^r$ for some $r\le k$.

For products of real projective spaces, Cusick [Reference Cusick9] conjectured that if $( \mathbb{Z}_2)^r $ acts freely on $ \mathbb{R}P^{n_1}\times\cdots\times\mathbb{R}P^{n_k} $ with a trivial action on $\mathbb{Z}_2$ cohomology, then $ r\leq \eta(n_1)+\cdots+\eta(n_k),$ where the function η on $ \mathbb{N} $ is defined by

\begin{equation*} \eta(n)= \left\{\begin{array}{ll} 0 & \text{if}\ n\ \text{is even},\\ 1 & \text{if}\ n\ \equiv1\!\!\!\!\pmod 4,\\ 2 & \text{if}\ n\ \equiv3\!\!\!\!\pmod 4.\\ \end{array} \right. \end{equation*}

The same paper established the conjecture when $ n_i\not\equiv3\!\pmod4 $ for all i. Later, the case when n i is odd for all i was settled in [Reference Yalçin32, Theorem 8.3]. The general case remains open.

For products of complex projective spaces, Cusick [Reference Cusick11, Theorem 4.13] proved that if a finite group G acts freely on $ (\mathbb{C} P^m)^k $, then G is a 2-group of order at most 2k and the exponent of G cannot exceed 2 k.

Viewing the product of two projective spaces as a trivial bundle, it is interesting to determine the free rank of symmetry of twisted projective space bundles over projective spaces. Milnor and Dold manifolds are fundamental examples of such spaces introduced by Milnor [Reference Milnor22] and Dold [Reference Dold13], respectively. It is well known that Milnor and Dold manifolds give generators for the unoriented cobordism algebra of smooth manifolds. Therefore, determining various invariants of these manifolds is an interesting problem. The free 2-rank of symmetry of products of Milnor manifolds has been investigated in [Reference Singh28], wherein some bounds have been obtained for the same.

In this paper, we investigate the free rank of symmetry of products of Dold manifolds. A Dold manifold $ P(m, n) $ is the quotient of $ S^m \times \mathbb{C}P^n $ by the free involution that acts antipodally on $\mathbb{S}^m$ and by complex conjugation on $\mathbb{C}P^n$ (see Definition 2.1). The free rank of symmetry of ${\prod_{i=1}^{k} P(2m_i,n_i)}$ is computed by determining the structure of finite groups that act freely on these manifolds. To state our results, we define a function $ \mu:\mathbb{N} \to \{0,1\} $ by

(1.3)\begin{equation} \mu(n)= \left\{ \begin{array}{ll} 1 & \text{if}\ n\ \text{is odd},\\ 0 & \text{if}\ n\ \text{is even.}\\ \end{array} \right. \end{equation}

We establish the following result for products of Dold manifolds (see Theorem 4.11).

Theorem A

Let G be a finite group acting freely on $X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)}$ with a trivial action on $ \mathbb{Z}_2 $ cohomology. Then $G\cong (\mathbb{Z}_2)^l$ for some l satisfying

\begin{equation*} l\leq \mu(n_1)+\mu(n_2)+\cdots+\mu(n_k).\end{equation*}

There is a more general conjecture due to Carlsson [Reference Carlsson, Jackowski and Pawałowski7, Conjecture I.3] for finite free G-CW-complexes.

Conjecture 1.4.

If $G=(\mathbb{Z}_p)^k$ and X is a finite free G-complex, then

\begin{equation*}2^k\leq \sum_{i=0}^{\dim X} \dim_{\mathbb{F}_p} H_i(X;\mathbb{Z}_p).\end{equation*}

For $\mathbb{Z}_2$-cohomologically trivial actions, the above conjecture has a positive answer for $ X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)} $ by Theorem A. Also, the upper bound of Theorem A is sharp because of examples in $\S$ 3.

When n i’s are even, that is, for $ X\simeq \prod_{i=1}^k P(m_i,2n_i) $, following the Carlsson’s approach [Reference Carlsson5], we obtain the next result (see Theorem 4.20).

Theorem B

Let $ G=(\mathbb{Z}_2)^l$ act freely on $ X\simeq \prod_{i=1}^k P(m_i,2n_i) $ with a trivial action on $ \mathbb{Z}_2 $ cohomology.

  • (a) Then $ l\leq 2(\mu(m_1)+\mu(m_2)+ \cdots + \mu(m_k)) $.

  • (b) Moreover, if all of the odd m i’s are of the form $4k_i +1 $, then

    \begin{equation*} l\leq \mu(m_1)+\mu(m_2)+ \cdots +\mu(m_k). \end{equation*}

The paper is organized as follows. In $ \S$ 2, we recall basic facts about Dold manifolds. In $ \S $ 3, we construct free involutions on these manifolds. Finally, in $ \S $ 4, we investigate the free rank of symmetry of products of Dold manifolds.

Throughout the paper, the cyclic group of order p is denoted by $\mathbb{Z}_p$. The notation $ X\simeq {\prod_{i=1}^{k} P(m_i,n_i)} $ means that X is a finite CW-complex homotopy equivalent to $ {\prod_{i=1}^{k} P(m_i,n_i)} $. A group G acting $ \mathbb{Z}_2 $-cohomologically trivially on X means the induced action on $ H^*(X;\mathbb{Z}_2)$ is trivial.

2. Definition and cohomology of Dold manifolds

Definition 2.1. Let m and n be non-negative integers such that $m+n\gt0$. The Dold manifold $P(m,n)$ is a closed connected smooth manifold of dimension $m+2n$, obtained as the quotient of $S^m \times \mathbb{C}P^n$ under the free involution

\begin{equation*}((x_0, x_1, \ldots, x_m),[z_0, z_1, \ldots, z_n] ) \mapsto ((-x_0, -x_1, \ldots, -x_m),[\overline{z}_0, \overline{z}_1, \ldots, \overline{z}_n]).\end{equation*}

The projection $S^m \times \mathbb{C}P^n \rightarrow S^m$ induces the map

\begin{equation*}p:P(m,n)\rightarrow \mathbb{R}P^m,\end{equation*}

which is a locally trivial fiber bundle with fiber $\mathbb{C}P^n$. It was shown by Dold [Reference Dold13] that, for suitable values of m and n, the cobordism classes of $P(m,n)$ serve as generators in odd degrees for the unoriented cobordism algebra of smooth manifolds. In that same paper, the cohomology ring structure was also determined,

\begin{equation*}H^*(P(m,n); \mathbb{Z}_2) \cong \mathbb{Z}_2[a,b]/\left\langle a^{m+1}, b^{n+1} \right\rangle,\end{equation*}

where $\deg (a)=1$ and $\deg (b) =2$. The action of the Steenrod square Sq 1 on the generators is given by

\begin{equation*} Sq^1 a= a^2, Sq^1 b=ab.\end{equation*}

Dold manifolds have been well-studied in the past. In [Reference Fujii14], Fujii computed the K U-groups of these manifolds. Ucci [Reference Ucci30] characterized Dold manifolds which admit codimension-one embeddings in the Euclidean space. In [Reference Peltier and Beem27], Peltier and Beem obtained some results concerning possible $ \mathbb{Z}_2 $ cohomologies of components of fixed-point sets of smooth involutions on Dold manifolds. Korbaš [Reference Korbaš20] studied parallelizability of Dold manifolds. In a recent work [Reference Nath and Sankaran24], Nath and Sankaran defined generalized Dold manifolds and investigated their stable parallelizability. Orbit spaces of free involutions on Dold manifolds of type $P(1,n)$ have been investigated recently in [Reference Morita, de Mattos and Pergher23]. Generalizing this, the possible $ \mathbb{Z}_2 $-cohomology algebra of orbit spaces of arbitrary free involutions on a Dold manifold was determined in [Reference Dey12].

3. Free involutions on Dold manifolds

In this section, we give some examples of free involutions on Dold manifolds. If both m and n are even, then by Euler characteristic argument, we see that $ \mathbb{Z}_2 $ cannot act freely on $P(m, n)$.

  1. (i) When n is odd: Define $\tau_1:\mathbb{C}P^n \rightarrow \mathbb{C}P^n $ as the free involution given by

    \begin{equation*} \tau_1 ([z_0,\dots,z_n ]) = [-\overline{z}_1, \overline{z}_0, \dots, -\overline{z}_n, \overline{z}_{n-1}].\end{equation*}

    Then $id \times \tau_1$ gives a free involution on $S^m \times \mathbb{C}P^n$. Since τ 1 commutes with the action defining the Dold manifold, we obtain a free involution on $P(m,n)$.

  2. (ii) When both m and n are odd: Note that the preceding free involution is defined in this case as well. Further, for $m \equiv 1 \pmod 4$, we define the action τ 2 on $S^m \times \mathbb{C}P^n$ by

    \begin{equation*}\tau_2((x_0, \ldots, x_{m}), [z_0, \ldots, z_{n}]) =((-x_1, x_0, \ldots, -x_{m}, x_{m-1}), [-\overline{z}_1, {z}_0, \ldots, -\overline{z}_n, {z}_{n-1}]).\end{equation*}

    This gives a free involution on $P(m,n)$ by passing to the quotient. Note that the composition $ \tau_1\circ \tau_2 $ does not define a free involution on $ P(m,n) $.

  3. (iii) Suppose both $ m, n\equiv 3 \pmod 4 $: We know that the quaternion group Q 8 acts freely on $ S^{4k+3} $. This lets us define the free involutions $\varphi_\mathbf{i}$, $\varphi_\mathbf{j}$ and $ \varphi_\mathbf{k} $ on $ P(m,n) $ as follows:

    \begin{align*} \varphi_\mathbf{j}((x_0, \ldots, x_{m}), [z_0, \ldots, z_{n}]) &=\left((-x_2, x_3, x_0,-x_{1},\ldots, -x_{m-2}),\right.\\ &\quad\left.[\overline{z}_2, {z}_3, z_0, \overline{z}_1,\ldots, \overline{z}_{n-2}]\right)\!,\end{align*}
    \begin{align*} \varphi_\mathbf{k}((x_0, \ldots, x_{m}), [z_0, \ldots, z_{n}]) &=\left((-x_3, -x_2, x_1, x_0, \ldots, x_{m-3}),\right.\\ &\quad\left.[\overline{z}_3, \overline{z}_2, {z}_1, z_0, \ldots, z_{m-3}]\right)\!.\end{align*}

    These two actions commute, and the composition $ \varphi_\mathbf{j}\cdot \varphi_\mathbf{k}$ gives another free involution $\varphi_\mathbf{i}$. Hence, $ \mathbb{Z}_2\oplus \mathbb{Z}_2$ acts freely in this case.

  4. (iv) When m is odd and n is even: By [Reference Conner8, p-79], we know that if a closed smooth manifold does not bound, then it cannot admit free involutions. If m is odd and n is even with $m\lt n+1$, then $P(m,n)$ does not bound (see [Reference Khare19, Proposition 2.4]). Hence, $P(m,n)$ does not admit any free involution in this situation.

4. Free rank of symmetry

In this section, we prove our main results. Our main technique is the Serre spectral sequence associated to the Borel fibration. Let G be a finite group and EG be the universal free G-space. Suppose X is a G-space. The bundle $ X\to EG\times_G X\to BG $ associated to the universal principal G-bundle $ G\to EG\to BG $ is called the Borel fibration (see [Reference Borel, Bredon, Floyd, Montgomery and Palais4, Chapter IV, § 3], [Reference Allday and Puppe3, p. 10]). Moreover, for free G-spaces, $ EG\times_G X $ and $ X/G $ are homotopy equivalent [Reference Allday and Puppe3, p. 20].

Let X be a finite CW-complex homotopy equivalent to $ {\prod_{i=1}^{k} P(m_i,n_i)} $. The cohomology ring of X with $ \mathbb{Z}_2 $-coefficient is given by

(4.1)\begin{equation} H^*({X};\mathbb{Z}_2)\cong \mathbb{Z}_2[a_1,\cdots,a_k, b_1,\cdots,b_k]/( a_1^{m_1+1},\cdots, a_k^{m_k+1},b_1^{n_1+1},\cdots,b_k^{n_k+1}), \end{equation}

where $ \deg(a_i)=1$ and $ \deg(b_i)=2 $ for each $ 1\le i\le k $.

4.1. Free rank in the case $ X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)} $

We start with the following lemma

Lemma 4.2. Let $ X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)} $. If $ \mathbb{Z}_4 $ acts freely on X with a trivial action on $ \mathbb{Z}_2 $ cohomology, then

\begin{equation*} \pi_1(X/\mathbb{Z}_4) \cong (\mathbb{Z}_2)^k\oplus \mathbb{Z}_4.\end{equation*}

Proof. Consider the Serre spectral sequence associated to the fibration $ X\hookrightarrow X/\mathbb{Z}_4\to B\mathbb{Z}_4$ whose E 2 term is

\begin{equation*} E_2^{r,s} =H^r(B\mathbb{Z}_4;H^s(X;\mathbb{Z}_2))\cong H^r(B\mathbb{Z}_4;\mathbb{Z}_2) \otimes H^s(X;\mathbb{Z}_2).\end{equation*}

Recall that,

\begin{equation*} H^*(B\mathbb{Z}_4;\mathbb{Z}_2) \cong \mathbb{Z}_2[u,v]/( u^2 ), \qquad \deg(u)=1\ \text{and}\ \deg(v)=2.\end{equation*}

Using this spectral sequence, we first show that $ H^1(X/\mathbb{Z}_4;\mathbb{Z}_2)\cong (\mathbb{Z}_2) ^{k+1}$. For this, it suffices to prove that the generators $ a_i\in E_2^{0,1} $ are permanent cocycles. Suppose $ d_2(a_i) \ne 0$. Then $ a_i^{2m_i+1} =0$ implies

\begin{equation*} 0= d_2(a_i^{2m_i+1}) =a_i^{2m_i}\otimes d_2(a_i)=a_i^{2m_i}\otimes v\ne 0,\end{equation*}

a contradiction. Hence, all the generators $ a_i\in E_2^{0,1} $ survives to $ E_\infty $ page. So, $ H_1(X/\mathbb{Z}_4;\mathbb{Z}_2) \cong (\mathbb{Z}_2) ^{k+1}$. Note that the $ \mathbb{Z}_4 $ action on X induces a $ \mathbb{Z}_4 $ action on $ \pi_1(X,x_0) $ as $ \pi_1(X,x_0) $ is abelian. Moreover, by assumption, this induced $ \mathbb{Z}_4 $ action on $ \pi_1(X,x_0) $ is trivial. We claim that the following short exact sequence of groups is a central extension

(4.3)\begin{equation} 0\to \pi_1(X,x_0) \xrightarrow{i_*} \pi_1(X/\mathbb{Z}_4,\overline{x}_0)\xrightarrow{\pi_*} \mathbb{Z}_4\to 0, \end{equation}

where $ i:X\to X/\mathbb{Z}_4 $. For this, we observe that the induced $ \mathbb{Z}_4 $ action mentioned above is the same as the action of $ \mathbb{Z}_4 $ on $ \pi_1(X,x_0)$ induced by the conjugation action in $ \pi_1(X/\mathbb{Z}_4,\overline{x}_0) $. To see this, let $ g\in \mathbb{Z}_4 $. The action of g on $\pi_1(X,x_0) $ is given by

\begin{equation*} g[\gamma]=[\theta\times g\gamma \times \theta^{-1}], \end{equation*}

where θ is a path in X from x 0 to gx 0. Then applying $ i_*: \pi_1(X,x_0)\to \pi_1(X/\mathbb{Z}_4,\overline{x}_0) $, we obtain

\begin{equation*} i_*(g[\gamma])=[i(\theta)]\cdot i_*([\gamma])\cdot [i(\theta)]^{-1}, \end{equation*}

where $ [i(\theta)]\in \pi_1(X/\mathbb{Z}_4,\overline{x}_0)$ satisfies the property that $ \pi_*([i(\theta)])=g $. This is because $ i(\theta) $ considered as a path in $ E\mathbb{Z}_4\times_{\mathbb{Z}_4} X $ is a lift of a loop in $ B\mathbb{Z}_4 $ representing g. Hence, Equation (4.3) is a central extension. Moreover, the quotient $ \pi_1(X/\mathbb{Z}_4, \overline{x}_0) /\pi_1(X, x_0)\cong \mathbb{Z}_4$ is a cyclic group, so $ \pi_1(X/\mathbb{Z}_4,\overline{x}_0) $ is abelian. This implies $ \pi_1(X/\mathbb{Z}_4,\overline{x}_0)\cong H_1(X/\mathbb{Z}_4;\mathbb{Z}) \cong (\mathbb{Z}_2)^k\oplus \mathbb{Z}_4$ as all other possibilities can be ruled out by Equation (4.3).

In case of $ G =(\mathbb{Z}_2)^{r}$, we have the following:

Lemma 4.4. Let $ G=(\mathbb{Z}_2)^{r} $ and $ X\simeq {\displaystyle\prod_{i=1}^{k} P(2m_i,n_i)} $. If G acts freely on X with a trivial action on $ \mathbb{Z}_2 $ cohomology, then

\begin{equation*} \pi_1(X/G) \cong (\mathbb{Z}_2)^{k+r}.\end{equation*}

Proof. Since G acts freely on X, we get the following extension of groups

(4.5) \begin{equation} 0\to \pi_1(X) \to \pi_1(X/G)\to G\to 0, \end{equation}

where $ \pi_1(X) \cong (\mathbb{Z}_2)^k$. The E 2 term of the Serre spectral sequence associated to the fibration $ X\hookrightarrow X/G\to BG$ is given by

\begin{equation*} E_2^{r,s} =H^r(BG;H^s(X;\mathbb{Z}_2))\cong H^r(BG;\mathbb{Z}_2) \otimes H^s(X;\mathbb{Z}_2),\end{equation*}

where

\begin{equation*} H^r(BG;\mathbb{Z}_2)\cong \mathbb{Z}_2[t_1,\ldots, t_r], \qquad \deg (t_i) =1.\end{equation*}

Using similar argument to that of Lemma 4.2, we obtain that the generators $ a_i \in E_{2}^{0,1}$ are permanent cocycles. Thus, $ H_1(X/G;\mathbb{Z}_2) \cong (\mathbb{Z}_2) ^{k+r}$. As abelianization reduces the order of a non-abelian group, $ \pi_1(X/ G) $ must be abelian. Hence, isomorphic to $ (\mathbb{Z}_2 )^{k+r} $.

In the case $ G=\mathbb{Z}_p $, we have the following:

Lemma 4.6. Let $ X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)} $. If $ \mathbb{Z}_p $ (p an odd prime) acts freely on X with a trivial action on $ \mathbb{Z}_2 $ cohomology, then

\begin{equation*} \pi_1(X/\mathbb{Z}_p) \cong (\mathbb{Z}_2)^k\oplus \mathbb{Z}_p.\end{equation*}

Proof. As in the case of Lemma 4.2, corresponding to the $ \mathbb{Z}_p $ action, we have the following extension of groups

(4.7) \begin{equation} 0\to \pi_1(X,x_0) \to \pi_1(X/\mathbb{Z}_p,\overline{x}_0)\to \mathbb{Z}_p\to 0. \end{equation}

The extension class of the extension (4.7) gives an element in $ H^2(\mathbb{Z}_p;(\mathbb{Z}_2)^k) $, which is equal to 0 as the order of $ \mathbb{Z}_p $ and $ (\mathbb{Z}_2)^k $ are coprime. Moreover, by assumption, $ \mathbb{Z}_p $ acts trivially on $ \pi_1(X,x_0) $. Hence, we have the claim.

Suppose that G is one of the groups $ \mathbb{Z}_4 $, $ (\mathbb{Z}_2)^k $ or $ \mathbb{Z}_p $. Further, let G act freely on $ X\simeq {\displaystyle\prod_{i=1}^{k} P(2m_i,n_i)} $. From Equations (4.3), (4.5) and (4.7), we see that the extensions

\begin{equation*} 0\to \pi_1(X,x_0) \to \pi_1(X/G,\overline{x}_0)\to G\to 0 \end{equation*}

are split extensions. As a result, we obtain that G also acts freely on the universal cover $ \tilde{X}\simeq{\prod_{i=1}^{k} S^{2m_i}\times\mathbb{C}P^{n_i}} $. Let $ g\in G $. The induced action of g on $H^*(\tilde{X}; \mathbb{Z}_2)$ is denoted by $ \tilde{g}^*_{\mathbb{Z}_2}$ and similarly $ \tilde{g}^*_{\mathbb{Z}}$. Recall that

(4.8) \begin{equation} H^*(\tilde{X};\mathbb{Z}_2)\cong \mathbb{Z}_2[\alpha_1,\ldots,\alpha_k, \beta_1,\ldots,\beta_k]/( \alpha_1^2,\ldots, \alpha_k^2,\beta_1^{n_1+1},\ldots,\beta_k^{n_k+1}), \end{equation}

where $ \deg(\alpha_i)=2m_i$ and $ \deg(\beta_i)=2 $ for each $ 1\le i\le k $. With this notation, we have the following description of the induced action on $H^*(\tilde{X}; \mathbb{Z}_2)$:

Lemma 4.9. Let $ X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)} $. The action of $\tilde{g}^*_{\mathbb{Z}_2}$ on the generators of $H^*(\tilde{X}; \mathbb{Z}_2)$ is given by $\tilde{g}^*_{\mathbb{Z}_2}(\beta_i)=\beta_j$ where $n_i=n_j$ and $\tilde{g}^*_{\mathbb{Z}_2}(\alpha_r)= \alpha_s$ where $\deg \alpha _r=\deg \alpha_s$. Here $ 1\le i, j\le k $ and $ 1\le r, s\le k $.

Proof. Note that for each i, n i is the maximum value of t such that $ \beta_i^{t}\ne 0 $. In order to determine the action of $ \tilde{g}^*_{\mathbb{Z}_2} $ on $ H^*(\tilde{X};\mathbb{Z}_2) $, we first analyse the action of $ \tilde{g}^*_{\mathbb{Z}} $ on $ H^*(\tilde{X};\mathbb{Z}) $. Then by the naturality of the change of coefficient homomorphism induced by $ \mathbb{Z}\to \mathbb{Z}_2 $, we will have the lemma. We claim that $\tilde{g}^*_{\mathbb{Z}}(\beta_i)=\pm\beta_j$, where $n_i=n_j$. For this, we proceed by induction on the values of n i’s. Let β u be a generator for which n u is minimum. The relation $\beta_u^{n_u+1}=0$ yields $(\tilde{g}^*_{\mathbb{Z}}(\beta_u))^{n_u+1}=0$. Suppose

\begin{equation*} \tilde{g}^*_{\mathbb{Z}}(\beta_u)=\sum_v \lambda_v\beta_v, \end{equation*}

where $ \lambda_v\in \mathbb{Z} $. As n u is minimum, any non-zero integer multiples of $\beta_v^{n_u}\cdot\beta_w$ are non-zero if $ v\ne w $ in the right hand side of the above equation. Hence, in order to get $(\tilde{g}^*_{\mathbb{Z}}(\beta_u))^{n_u+1}=0$, we must have all λ v’s are zero except one, say $\lambda_\ell$ and $(\beta_\ell)^{n_u+1}=0$. Moreover, $\lambda_\ell$ must be equal to ±1. Thus, we have the claim when n u is minimum. Now suppose the claim holds for any generator β q with $n_q\lt n_x$. Then we show this holds for β x. Let

(4.10) \begin{equation} \tilde{g}^*_{\mathbb{Z}}(\beta_x)=\sum \lambda_y\beta_y. \end{equation}

Case  (a): Suppose for some β y the value of n y is equal to n x and $\lambda_y \ne 0$. Then, as before, all other $\lambda_{y^\prime}$ should be zero for $y\ne y^\prime$; otherwise, $(\tilde{g}^*_{\mathbb{Z}} (\beta_x))^{n_x+1}\ne 0$, a contradiction.

Case  (b): Suppose for all β y in Equation (4.10) $n_y \lt n_x$. Then by induction hypothesis, we know that $(\tilde{g}^*_{\mathbb{Z}})^{-1}(\beta_y)=\pm \beta_z$ for some z such that $n_y=n_z$. As a result,

\begin{equation*}(\tilde{g}^*_{\mathbb{Z}})^{-1}\left(\sum\lambda_y\beta_y\right)=\sum\pm\lambda_y\beta_z\ne\beta_x.\end{equation*}

Hence, this case is not possible. Thus, the claim holds for the generators β i’s.

To determine the action of $\tilde{g}^*_{\mathbb{Z}}$ on α r’s, choose an α u such that $\deg \alpha_u=2m_u$ is minimum. Using similar argument as in Case (b), we find that $\tilde{g}^*_{\mathbb{Z}}(\alpha_u)$ cannot be a monomial of the form $\beta_{j_1}^{t_1}\cdots\beta_{j_r}^{t_r}$ of $\deg$ $2m_u$. Then arguing as in Case (a), we get $ \tilde{g}^*_{\mathbb{Z}}(\alpha_u)=\pm\alpha_v $, where $ \deg \alpha_u=\deg \alpha_v $. Finally, by induction on degrees of α r’s, we get $ \tilde{g}^*_{\mathbb{Z}}(\alpha_r)=\pm\alpha_s $. Now using the naturality of the change of coefficient homomorphism, $ \mathbb{Z} \to \mathbb{Z}_2 $, we get the result.

We are now in a position to prove our main result for products of Dold manifolds.

Theorem 4.11 Let G be a finite group acting freely and $\mathbb{Z}_2$-cohomologically trivially on a finite CW-complex X homotopy equivalent to ${\prod_{i=1}^{k} P(2m_i,n_i)}$. Then $G\cong (\mathbb{Z}_2)^l$ for some l satisfying

\begin{equation*} l\leq \mu(n_1)+\mu(n_2)+\cdots+\mu(n_k).\end{equation*}

Proof. We prove the case $ m_i\gt0 $. The case when some m i’s are zero is analogous. The proof of the theorem is divided into three steps. In step 1, we observe that G cannot contain an element of order 4. In step 2, we show that G cannot have odd torsion. These two together imply that G must be an elementary abelian 2-group. Then finally in step 3, we derive the bound on l. The following proposition is essential for step 1 and step 3:

Proposition 4.12. Let $G= \mathbb{Z}_4 $ or $ (\mathbb{Z}_2)^l $. If G acts freely on $ X\simeq {\prod_{i=1}^{k} P(2m_i,n_i)} $ with a trivial action on $ \mathbb{Z}_2 $ cohomology, then the induced action of G on the $ \mathbb{Z}_2 $ cohomology of the universal cover $ \tilde{X} \simeq {\displaystyle \prod_{i=1}^{k} S^{2m_i}\times\mathbb{C}P^{n_i}}$ is trivial.

Proof. If G acts freely and $ \mathbb{Z}_2 $-cohomologically trivially on X, then the action of G on $ \pi_1(X) \simeq (\mathbb{Z}_2)^k$ is trivial. In particular, it acts trivially on $ B(\mathbb{Z}_2)^k $. For an element $ g\in G $, this gives the following diagram of fibrations

Consider the Serre spectral sequence associated with the fibration

\begin{equation*} \tilde{X}\hookrightarrow X \to B(\mathbb{Z}_2)^k ,\end{equation*}

whose E 2 term is given by

\begin{equation*} E_{2}^{r,s} = H^{r}(B(\mathbb{Z}_2)^k; H^s(\tilde{X};\mathbb{Z}_2)).\end{equation*}

The action of $ \mathbb{Z}_2 $ on $ S^m\times \mathbb{C} P^n $ that defines the Dold manifold induces trivial action on $ H^*(S^m\times \mathbb{C} P^n;\mathbb{Z}_2) $. So the product action of $ (\mathbb{Z}_2)^k $ on $ \tilde{X}\simeq {\prod_{i=1}^{k} S^{2m_i}\times\mathbb{C}P^{n_i}} $ also induces trivial action on $ H^*(\tilde{X};\mathbb{Z}_2) $. Therefore,

\begin{equation*} E_{2}^{r,s} = H^{r}(B(\mathbb{Z}_2)^k;\mathbb{Z}_2)\otimes H^s(\tilde{X};\mathbb{Z}_2).\end{equation*}

Recall that

\begin{equation*} H^s(\tilde{X};\mathbb{Z}_2)\cong \mathbb{Z}_2[\alpha_1,\ldots,\alpha_k, \beta_1,\ldots,\beta_k]/( \alpha_1^2,\ldots, \alpha_k^2,\beta_1^{n_1+1},\ldots,\beta_k^{n_k+1}),\end{equation*}

where $ \deg(\alpha_i)=2m_i$ and $ \deg(\beta_i)=2 $ for each $ 1\le i\le k $. The cohomology ring structure of X, Equation (4.1) tells us that the generators β i’s in $E_2^{0,2} $ must be permanent cocycles, and all the generators α i’s in $E_2^{0,2m_i}$ must be transgressive with $ d_{2m_i+1}(\alpha_i)\ne0 $. Let x be an element of $ H^*(\tilde{X},\mathbb{Z}_2) $. Then the naturality of the spectral sequence associated with Equation (4.13) implies

(4.14) \begin{equation} \tilde{g}^*_{\mathbb{Z}_2}( d_r(x)) =d_r(\tilde{g}^*_{\mathbb{Z}_2}(x)) . \end{equation}

By Lemma 4.9, $\tilde{g}^*_{\mathbb{Z}_2}(\beta_i)=\beta_j$, where $n_i=n_j$, and $\tilde{g}^*_{\mathbb{Z}_2}(\alpha_r)= \alpha_s$, where $\deg \alpha _r=\deg \alpha_s$.

Claim: We claim that $ \alpha_r=\alpha_s $. Suppose $ \alpha_r \ne \alpha_s $, and let $ d_{2m_r+1}(\alpha_r)=\gamma_r $. Then by Equation (4.14), we obtain

\begin{equation*} \tilde{g}^*_{\mathbb{Z}_2}(\gamma_r)=\tilde{g}^*_{\mathbb{Z}_2}(d_{2m_{r+1}}(\alpha_r))=d_{2m_{r+1}}(\tilde{g}^*_{\mathbb{Z}_2}(\alpha_r))=d_{2m_{r+1}}(\alpha_s)=\gamma_s. \end{equation*}

The fact that g acts trivially on $B({\mathbb{Z}_2})^k $ implies that $\tilde{g}^*_{\mathbb{Z}_2}(\gamma_t)=\gamma_t$. So $ \gamma_r=\gamma_s $. For the cohomology ring structure of X, Equation (4.1) ensures that if $ \alpha_r\ne \alpha_s $, then $ \gamma_r\ne \gamma_s$, hence a contradiction. Therefore, $ \alpha_r=\alpha_s $.

Next observe that $ \tilde{g}^*_{\mathbb{Z}_2}(\beta_i) $ must be equal to β i as the generator β i gives a generator of $ H^2(X;{\mathbb{Z}_2}) $ on which the action is trivial by assumption. This completes the proof of the proposition.

Proof of step 1

On the contrary, suppose G contains an element of order 4, that is, $ {\mathbb{Z}_4} $ acts freely and $ {\mathbb{Z}_2} $-cohomologically trivially on X. Then Proposition 4.12 guarantees that $ {\mathbb{Z}_4} $ acts freely on $ \tilde{X} $ with a trivial action on $ {\mathbb{Z}_2} $ cohomology. However, this is impossible because of [Reference Cusick10, Theorem A].

Proof of step 2

In case of $ G={\mathbb{Z}_p} $, we use transfer long exact sequence to give a more direct proof of the fact that if $ {\mathbb{Z}_p} $ acts freely and $ \mathbb{Z}_2 $-cohomologically trivially on X, then the induced action of $ \mathbb{Z}_p $ on the $ \mathbb{Z}_2 $ cohomology of the universal cover $ \tilde{X}$ is trivial (this also follows from a similar argument to that of Proposition 4.12). Consider a two-sheeted covering $ \tilde{X}_1 $ of X. Let $ \pi:\tilde{X}_1\to X $ be the covering projection. Then we have the following long exact sequence

\begin{equation*}\cdots\to H^n(X;{\mathbb{Z}_2})\xrightarrow{\pi^*} H^n(\tilde{X}_1;{\mathbb{Z}_2})\xrightarrow{\tau^*} H^n(X;{\mathbb{Z}_2})\to \cdots,\end{equation*}

where $ \tau^* $ is the transfer homomorphism [Reference Hatcher17, p. 321]. Let $ g\in {\mathbb{Z}_p} $ and $ y\in H^n(\tilde{X};{\mathbb{Z}_2}) $. Note that the action of G commutes with τ. Hence,

\begin{equation*} \tau^*(g^*(y))=g^*(\tau^*(y))=\tau^*(y), \end{equation*}

where the last equality holds because g acts $ {\mathbb{Z}_2} $-cohomologically trivially on X. Hence, $ g^*(y)+y\in \ker(\tau^*)={\rm Im}(\pi^*) $. Suppose $ \pi^*(z)=g^*(y)+y $, where $ z\in H^n({X};{\mathbb{Z}_2}) $. Then

\begin{equation*} \pi^*(z)=\pi^*(g^*\cdot z)=g^*\cdot \pi^*(z)=(g^{*})^2(y)+g^*(y). \end{equation*}

Hence, $ g^{*^2}(y)=y $. Since $ (g^*)^p=1 $, this implies $ g^* $ acts trivially on $ H^*(\tilde{X}_1;{\mathbb{Z}_2}) $. We can repeat this process with a two-sheeted covering of $ \tilde{X}_1$ until we reach to $ \tilde{X} $.

Following the proof of Lemma 4.9, we obtain $ \tilde{g}^*_{\mathbb{Z}}(\beta_i)=\pm \beta_j$, where $ n_i=n_j $ and $ \tilde{g}^*_{\mathbb{Z}}(\alpha_r)=\pm \alpha_s$, where $ \deg \alpha_r=\deg \alpha_s $. This together with the fact that $ \tilde{g}^*_{\mathbb{Z}_2}$ acts trivially on $ H^*(\tilde{X};{\mathbb{Z}_2}) $ implies $ \tilde{g}^*_{\mathbb{Z}}(\beta_i)=\pm \beta_i $ and $ \tilde{g}^*_{\mathbb{Z}}(\alpha_i)=\pm \alpha_i$. But then $ (\tilde{g}^*_{\mathbb{Z}})^2 $ is identity. This contradicts the fact that if G acts freely, then the Lefschetz number must be zero for all elements of G. Hence, G cannot have odd torsion.

Proof of step 3

Step 1 and step 2 together imply that if G acts freely on X with a trivial action on $ {\mathbb{Z}_2} $ cohomology, then G should be an elementary abelian two-group. So assume $ G\cong({\mathbb{Z}_2})^l $. So G acts freely on $ \tilde{X}=\prod_{i=1}^kS^{2{m_i}} \times \mathbb{C}P^{n_i}$. We may apply similar reasoning as in Proposition 4.12 to show that the induced action of G on $ H^*(\tilde{X};{\mathbb{Z}_2}) $ is trivial. Moreover, the action of $ (\mathbb{Z}_2)^k\cong \pi_1(X) $ on $ \tilde{X} $ that defines X also induces trivial action on $ H^*(\tilde{X};{\mathbb{Z}_2}) $. Hence, by Lemma 4.4, $ \pi_1(X/G) $ acts trivially on $ H^*(\tilde{X};{\mathbb{Z}_2}) $. Let $ g\in \pi_1(X/G) $. Following the proof of Lemma 4.9, we obtain $ \tilde{g}^*_{\mathbb{Z}}(\beta_i)=\pm \beta_j$, where $ n_i=n_j $, and $ \tilde{g}^*_{\mathbb{Z}}(\alpha_r)=\pm \alpha_s$, where $ \deg \alpha_r=\deg \alpha_s $. Then using the fact that $ \tilde{g}^*_{\mathbb{Z}_2}$ acts trivially on $ H^*(\tilde{X};{\mathbb{Z}_2}) $, we get $ \tilde{g}^*_{\mathbb{Z}}(\beta_i)=\pm \beta_i $ and $ \tilde{g}^*_{\mathbb{Z}}(\alpha_i)=\pm \alpha_i$. Since $ \pi_1(X/G)\cong (\mathbb{Z}_2)^{k+l} $ acts freely, for each $ g\ne 1 $, the Lefschetz number of $ \tilde{g}^*_{\mathbb{Z}} $, $ \tau(\tilde{g}^*_{\mathbb{Z}}) $ must be zero. Suppose $ \tilde{g}^*_{\mathbb{Z}}(\beta_i) =\lambda_i\beta_i$ and $ \tilde{g}^*_{\mathbb{Z}}(\alpha_i) =\zeta_i\alpha_i$, for $ \lambda_i,\zeta_i \in \{\pm1\} $. Then

\begin{equation*} \tau(\tilde{g}^*_{\mathbb{Z}}) = \prod_{i=1}^k (1 + \zeta_i) (1 + \lambda_i + \cdots + \lambda_i^{n_i}), \end{equation*}

which is zero if either $ \zeta_i=-1 $ or in the case when n i is odd and $ \lambda_i=-1 $. This implies

\begin{equation*} l+k\le k+\mu(n_1)+\mu(n_2)+ \cdots+\mu(n_k).\end{equation*}

Therefore, we obtain the required bound. This completes the proof of the theorem.

Remark 4.15. Examples from $\S$ 3 show that the bound given in Theorem 4.11 is sharp. As a consequence, we obtain the following bound of the cohomological free 2-rank of products of Dold manifolds:

\begin{equation*} {c-\operatorname{frk}}_2\,\left({\displaystyle \prod_{i=1}^{k} P(2m_i, n_i)} \right)= \mu(n_1)+\mu(n_2)+\cdots+\mu(n_k). \end{equation*}

4.2. Free rank in the case $ X\simeq {\displaystyle\prod_{i=1}^{k} P(m_i,2n_i)} $

In this subsection, we prove Theorem B. For this, we closely follow the Carlsson’s approach [Reference Carlsson5]. Also, see [Reference Cusick9] and [Reference Singh28]. First, we recall the following results:

Proposition 4.16. see [Reference Greenberg15, p. 18]

Suppose $ f_1,\ldots, f_s $ are homogenous polynomials of $ \deg m $ in l variables. Then they have a non-trivial common zero in $ (\mathbb{Z}_2)^l$ if l > ms.

Proposition 4.17. see [Reference Carlsson5, Corollary 4, Proposition 5]

Suppose $ f_1,\ldots, f_s $ are elements of $ H^m(B(\mathbb{Z}_2)^l;\mathbb{Z}_2) $, regarded as homogenous polynomials of $ \deg m $ in l variables. Then they have a non-trivial common zero in $ (\mathbb{Z}_2)^l$ if and only if there is a subgroup inclusion $ i: \mathbb{Z}_2\hookrightarrow (\mathbb{Z}_2)^l $ such that $ i^*(f_j)=0 $ for each j, where $i^*: H^*(B(\mathbb{Z}_2)^l;\mathbb{Z}_2)\to H^*(B\mathbb{Z}_2;\mathbb{Z}_2) $.

With the help of Steenrod algebra, one obtains the following stronger restriction.

Proposition 4.18. see [Reference Carlsson5, Proposition 4]

Let $ \langle f_1, \ldots, f_s \rangle $ be an ideal generated by the homogenous polynomials f j’s in $ \mathbb{Z}_2[t_1,\ldots, t_l] $. Further, suppose that this ideal is invariant under the action of Steenrod algebra. Then the polynomials f j’s have a non-trivial common zero in $ (\mathbb{Z}_2)^l $ if l > s.

Returning back to our situation, suppose $ X \simeq \displaystyle\prod_{i=1}^k P(m_i,2n_i)$, and let $ G=(\mathbb{Z}_2)^l $ act freely and $ \mathbb{Z}_2 $-cohomologically trivially on X. Consider the Serre spectral sequence associated to the Borel fibration $ X \hookrightarrow X/G \to BG $, whose E 2 term is given by

\begin{equation*} E_2^{r,s} = H^r(BG,H^s(X;\mathbb{Z}_2)) \cong H^r(BG;\mathbb{Z}_2)\otimes H^s(X;\mathbb{Z}_2). \end{equation*}

Let us recall the cohomology ring structure of $ H^*(X;\mathbb{Z}_2) $ from Equation (4.1). For $ b_i\in E_2^{0,2} $, we have

\begin{equation*} 0=d_2(b_i^{2n_i+1})=b_i^{2n_i} \otimes d_2(b_i). \end{equation*}

This implies $ d_2(b_i)=0 $. Similarly if for some i, m i is even, then we get $ d_2(a_i)=0 $, where $ a_i\in E_2^{0,1} $. Moreover, the generators $ b_i\in E_2^{0,2} $ are permanent cocycles. For this it is enough to show $ d_3(b_i)=0 $. Suppose $ d_3(b_i)=u_i \in E_3^{3,0} $. Then

\begin{equation*} 0=d_3(b_i^{2n_i+1}) = b_i^{2n_i}\otimes d_3(b_i)=b_i^{2n_i} \otimes u_i. \end{equation*}

This implies the element $ b_i^{2n_i} \otimes u_i \in E_2^{3,4{n_i}} $ is in the image of d 2. Suppose $ b_i^{2n_i}\otimes u_i =d_2(w) $ for $ w\in E_2^{1,{4n_i+1}} $. Since the d 2-differential is completely determined by its value on the generators a i’s in $ E_2^{0,1}$, we get $ b_i^{2n_i} \otimes u_i =b_i^{2n_i}\otimes d_2(z)$ for some element $ z\in E_2^{1,1} $. As a result, $ u_i=d_2(z) $. Hence, $ d_3(b_i)=0 $. Let $ d_2(a_i)=x_i $, and let $ \mathcal{I} $ be the ideal $ \langle x_1, \ldots , x_k \rangle $ in $ H^*(BG;\mathbb{Z}_2) $. With this notation, we have the following

Proposition 4.19. Let $ G=(\mathbb{Z}_2)^l $ act freely on $ X \simeq \prod_{i=1}^k P(m_i,2n_i)$ with a trivial action on $ \mathbb{Z}_2$ cohomology. Further, suppose all of the odd m i’s are of the form $ m_i\equiv 1 \pmod 4$ for $1\le i\le k $. Then the ideal $\mathcal{I}$ is invariant under the action of Steenrod algebra.

Proof. Note from [Reference McCleary21, Theorem 6.14] that the action of the Steenrod algebra commutes with transgressive differentials of the Serre spectral sequence. Therefore, we get

\begin{equation*} Sq^1(x_i)=Sq^1( d_2(a_i))=d_3 (Sq^1(a_i))=d_3({a_i}^2). \end{equation*}

Since odd m i’s are of the form $ 4k_i+1 $, the following shows that the elements $ a_i^2 \in E_2^{0,2} $ are permanent cocycles:

\begin{equation*} 0=d_3(a_i^{4k_i+2})=a_i^{4k_i}\otimes d_3(a_i^2). \end{equation*}

This implies $ a_i^{4k_i}\otimes Sq^1(x_i)$ is in the image of d 2. Since the d 2-differential is completely determined by its value on the generators a i’s in $ E_2^{0,1}$, we get

\begin{equation*} a_i^{4k_i}\otimes Sq^1(x_i)=a_i^{4k_i}\otimes d_2(\xi) \end{equation*}

for some element $ \xi \in E_2^{1,1} $. Hence, $ d_2(\xi) =Sq^1(x_i)$. Let

\begin{equation*} \xi =\sum c_{ij}t_i\otimes a_j,\end{equation*}

where $ c_{ij} \in \mathbb{Z}_2 $, and for $ 1\le i\le l $, t i denotes a generator of $ H^1(BG;\mathbb{Z}_2) $. Hence, $ Sq^1(x_i)=\sum c_{ij} t_ix_j \in \mathcal{I} $.

Theorem 4.20 Let $ G=(\mathbb{Z}_2)^l$ act freely on $ X\simeq \prod_{i=1}^k P(m_i,2n_i) $ with a trivial action on $ \mathbb{Z}_2 $ cohomology.

  • (a) Then $ l\leq 2(\mu(m_1)+\mu(m_2)+ \cdots + \mu(m_k)) $.

  • (b) Moreover, if all of the odd m i’s are of the form $4k_i +1 $, then

    \begin{equation*} l\leq \mu(m_1)+\mu(m_2)+ \cdots +\mu(m_k). \end{equation*}

Proof. We first claim that the degree 2 polynomials x i cannot have a non-trivial common zero. Suppose they have a non-trivial common zero. Then, as given in Proposition 4.17, there exists a subgroup inclusion $ i:\mathbb{Z}_2\hookrightarrow (\mathbb{Z}_2)^l $ such that $ i^*(x_i)=0 $ for each i. Let $ (E^{r,s}_n,d_n) $ and $ (\tilde{E}^{r,s}_n,\tilde{d}_n) $ be the Serre spectral sequences associated with the Borel fibrations $ X\hookrightarrow X/G\to BG $ and $X\to X/\mathbb{Z}_2\to B\mathbb{Z}_2 $, respectively. Note that the system of local coefficients is trivial in both the cases. The map $ f^*=i^*\otimes id: E_2^{r,s}\to \tilde{E}_2^{r,s} $ commutes with the differentials. As discussed above, the only possible non-zero differentials are given by $ d_2(a_i) $ and $ \tilde{d}_2(a_i) $. For the latter, observe that

\begin{equation*} \tilde{d}_2(a_i)=\tilde{d}_2(f^*(a_i))= f^*(d_2(a_i))=0. \end{equation*}

Therefore, the spectral sequence $ \tilde{E}^{r,s}_n $ collapses at the E 2 page. This contradicts the fact that $ H^*(X/\mathbb{Z}_2;\mathbb{Z}_2) $ is finite dimensional. Hence, the degree 2 polynomials x i cannot have a non-trivial common zero. Then part (a) of the theorem follows from Proposition 4.16.

For part (b), we observe that if all of the odd m i’s are of the form $ 4k_i+1 $, then the ideal $ \mathcal{I} $ is invariant under the action of Steenrod algebra by Proposition 4.19. Since the polynomials x i cannot have a non-trivial common zero, applying Proposition 4.18, we obtain the result.

4.3. Concluding remarks

We would like to conclude with the following natural questions.

When both $ m, n\equiv 3\pmod 4 $, $ \mathbb{Z}_2\oplus \mathbb{Z}_2 $ acts freely on $ P(m, n) $ (see $\S$ 3). However, in contrast with $ \mathbb{R}P^m\times \mathbb{C}P^n $, there seems to be no obvious way to construct a free action of $ (\mathbb{Z}_2)^3 $ on $ P(m,n) $. Similarly, for $ m,n\equiv 1\pmod 4 $, there seems to be no obvious free action of $ (\mathbb{Z}_2)^2 $ on $ P(m,n) $, whereas there is an immediate free action of $ (\mathbb{Z}_2)^2 $ on $ \mathbb{R}P^m\times \mathbb{C}P^n $. Of course, there may exist some free involutions that are exotic in nature. Hence, further investigations on the free rank of products of Dold manifolds might be interesting.

A first step towards determining the free rank of $ \prod^k_{i=1}P(m_i,n_i) $ may be the following:

Question 1: Determine the maximum value of r such that $ G=({\mathbb{Z}_2})^r $ acts freely on products of equidimensional Dold manifolds, $ X=(P(m,n))^k $ with a trivial action on $ {\mathbb{Z}_2} $ cohomology.

Associated with this action of G, we have the following extension

\begin{equation*} 0\to\pi_1(X) \to\pi_1(X/G)\to G \to 0. \end{equation*}

Investigating along the line of arguments used in [Reference Yalçin33], for example, Propositions 2.3 and 3.4, might shed some light. For this, a crucial step will be to understand the rank of $ \pi_1(X/G) $.

Wall manifolds $ Q(m,n) $ [Reference Wall31] exhibit a close connection to that of Dold and Milnor manifolds in the sense that for certain values of m and n, they serve as generators for the unoriented cobordism algebra. So we may ask the following natural question.

Question-2: Determine the free rank of symmetry of products of Wall manifolds.

The cohomology ring structure of $ Q(m, n) $ with $ \mathbb{Z}_2 $ coefficient was determined in [Reference Wall31, Lemma 4]. In a recent work [Reference Paiva and dos Santos26], the authors have investigated group actions on Wall manifolds, where the authors determined the $ \mathbb{Z}_2 $-cohomology algebra of orbit spaces of free involutions on some Wall manifolds.

Acknowledgements

This article is a part of author’s PhD thesis. The author would like to thank her supervisor Prof. Mahender Singh for some valuable discussions and for his continuous support. The author is indebted to Prof. Samik Basu for pointing out some crucial observations and for his help with some of the arguments. The author wishes to thank the anonymous referees most warmly for pointing out a gap in the previous version of the paper and for many valuable suggestions.

Competing Interests

The author declares none.

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