Proof. If $\{T_i:1\leq i\leq N\}$ is disjoint transitive then it is disjoint hypercyclic by [Reference Bès and Peris9, Proposition 2.3].

Suppose that $\{T_i:1\leq i\leq N\}$ is disjoint hypercyclic and let $x\in X$ be a disjoint hypercyclic vector for $\{T_i:1\leq i\leq N\}$ . We will prove that, for every $n\in \mathbb N$ , $T_1^n(x)$ is a disjoint hypercyclic vector for $\{T_i:1\leq i\leq N\}$ . Let $n\in \mathbb N$ .

As the operators commute, it follows that

$$ \begin{align*}\mathrm{Orb}_{T_1\oplus \cdots \oplus T_N}\bigg(\bigoplus_{i=1}^N T_1^n(x)\bigg)= \bigoplus_{i=1}^N T_1^n \bigg( \mathrm{Orb}_{T_1\oplus \cdots \oplus T_N}\bigg(\bigoplus_{i=1}^N x\bigg)\bigg).\end{align*} $$

The operator $T_1$ is hypercyclic and hence $T_1^n$ is also hypercyclic [Reference Grosse-Erdmann and Peris Manguillot21, Theorem 6.2]. This implies that $Im(\bigoplus _{i=1}^N T_1^n)$ is dense in $\bigoplus _{i=1}^N X$ . On the other hand, $\bigoplus _{i=1}^N \mathrm {Orb}_{T_1\oplus \cdots \oplus T_N}(\bigoplus _{i=1}^N x)$ is also dense in $\bigoplus _{i=1}^N X$ . We conclude that $T_1^n(x)$ is a disjoint hypercyclic vector.

Now consider non-empty open sets U and $V_1,\ldots V_N$ . Since x is a hypercyclic vector for $T_1$ , there is $n_1$ such that $y=T_1^{n_1}(x)\in U$ . We have just proved that y is a d-hypercyclic vector for $\{T_i:1\leq i\leq N\}$ . Thus, there is n such that $T_i^n(y)\in V_i$ for every $1\leq i\leq N$ . It follows that $y\in U\cap \bigcap _{i=1}^N T_i^{-n}V_i.$

Proof of Theorem 3.3

Suppose that there are $j_1,j_2,j_3,j_4\in J\cup \{0\},\ 0\leq j_1\leq j_2 \leq j_3\leq ~j_4$ such that $j_1+j_4=j_2+j_3$ .

Let $U,V$ be non-empty open sets. We will prove that $N_T(U,U)\cap N_T(U,V)\neq \emptyset .$ By Proposition 2.1 this implies that T is weakly mixing.

We will divide the proof into three cases.

First case. Suppose that $j_1\neq 0$ and that $j_2<j_3$ . Let $x\in X$ be a disjoint hypercyclic vector for $\{T^{j_i}:1\leq i\leq 4\}$ . Hence, there is $n\in \mathbb N$ such that $T^{j_in}(x)\in U$ for $i\leq 3$ and $T^{j_4n}(x)\in V$ . Therefore, $j_4n-j_2n\in N_T(x,V)-N_T(x,U)=N_T(U,V)$ and, on the other hand, $j_4n-j_2n=j_3n-j_1n\in N_T(x,U)-N_T(x,U)=N_T(U,U)$ .

If $j_1\neq 0$ and $j_2=j_3$ the proof is the same by considering $x\in X$ a disjoint hypercyclic vector for $\{T^{j_1},T^{j_2},T^{j_4}\}$ and $n\in \mathbb N$ such that $T^{j_in}(x)\in U$ for $i\leq 3$ and $T^{j_4n}(x)\in V$ .

Second case. Suppose that $j_1=0$ and that $j_2\neq j_3$ . By Proposition 2.4, the set of disjoint hypercyclic vectors is dense and hence there is a disjoint hypercyclic vector $x\in U$ for $\{T^{j_2},T^{j_3}, T^{j_4}\}$ .

Let $n\in \mathbb N$ such that $T^{j_2n}(x)\in U$ , $T^{j_3n}(x)\in U$ and $T^{j_4n}(x)\in V.$ Therefore, $j_4n-j_3n\in N_T(x,V)-N_T(x,U)= N_T(U,V)$ . On the other hand, $j_4n-j_3n=j_2n\in N_T(U,U)$ , because $x\in U$ and $T^{j2n}(x)\in U.$

Final case. Suppose that $j_1=0$ , $j_2=j_3=j$ and $j_4=2j$ . By Proposition 2.4 there is a disjoint hypercyclic vector $x\in U$ for $\{T^j,T^{2j}\}$ . Let $n\in \mathbb N$ such that $T^{jn}(x)\in U$ and such that $T^{2jn}(x)\in V$ . It follows that $2jn-jn=jn\in N_T(x,V)-N_T(x,U)=N_T(U,V)$ . On the other hand, $jn\in N_T(U,U)$ , because $x\in U$ and $T^{jn}(x)\in U$ .

This implies that $N_T(U,U)\cap N_T(U,V)\ne \emptyset $ and thus T is weakly mixing.

Proof of Theorem 3.4

Let $(F_n)_n$ be a collection of finite sets, with $|F_n|=n$ , such that $F_n\cup \{0\}$ is a Sidon set and such that any finite set $F\subset \mathbb N$ such that $F\cup \{0\}$ is Sidon, F is contained in $F_n\cup \{0\}$ for some n. We consider $(j_{n,k})_{0\leq k\le n,n\in \mathbb N}$ such that for every n, $(j_{n,k})_{0\le k\le n}$ forms an increasing enumeration of $F_n\cup \{0\}$ . Thus, it suffices to show the existence of a Bayart–Matheron operator such that for each n, the set of operators $\{T^{j_{n,1}},\dots ,T^{j_{n,n}}\}$ is disjoint hypercyclic.

For a sequence $m_{l,n}$ such that $l\geq n$ (to be defined), we will consider $b_{l,n,k}$ , $1\hspace{-2pt}\leq\hspace{-2pt} k\hspace{-2pt}\leq\hspace{-2pt} n\hspace{-2pt}\leq\hspace{-2pt} l$ , such that $b_{l,n,k}=m_{l,n} j_{n,k}$ . Note that $b_{l,n,k}$ is not defined if $k=0$ .

The order considered for the tuples $(l,n)$ is lexicographic, that is, $(l,n)\leq (l',n')$ if $l<l'$ or if $l=l'$ and $n\le n'$ . The tuples $(l,n,k)$ will also be ordered lexicographically.

We will construct $m_{l,n}$ by induction in $(l,n)$ so that the sets

$$ \begin{align*} J_{l,n,k}:=&\bigg[b_{l,n,k},b_{l,n,k}+\frac{m_{l,n}}{2}\bigg]\\ & \cup \bigg(\bigcup_{(l',n',k')\leq (l,n,k)}\bigg[b_{l,n,k}+ b_{l',n',k'} ,b_{l,n,k}+ b_{l',n',k'}+\frac{m_{l,n}}{2}\bigg]\bigg) \end{align*} $$

with $1\le k\le n\le l$ are pairwise disjoint. If so, it will follow by definition that $(b_{l,n,k})$ is a $\Delta _{l,n,k}$ -Sidon sequence for $\Delta _{l,n,k}=({m_{l,n}})/{2}$ . At each inductive step $(L,N)$ we will construct sets $J_{L,N,k}$ , $1\leq k\leq N$ so that:

1. (i) for $1\leq k\leq N$ , the $J_{L,N,k}$ are pairwise disjoint; and

2. (ii) for every $1\leq k\leq N$ , $1\leq k'\leq N'$ and $(L',N')<(L,N)$ , $J_{L,N,k}$ is disjoint from $J_{L',N',k'}$ .

The first step is straightforward because there is a single set. We put $m_{1,1}=1$ .

Suppose now that we have constructed $m_{1,1},\ldots m_{L,N}$ such all the sets $J_{l,n,k}$ with $(l,n,k)\leq (L,N,N)$ are pairwise disjoint. If $(\tilde L,\tilde N)$ denotes the immediate successor of $(L,N)$ we have to choose $m_{\tilde L, \tilde N}$ such that the $J_{l,n,k}$ are pairwise disjoint for every $(l,n,k)\leq (\tilde L,\tilde N ,\tilde N)$ . To do that, we will choose $m_{\tilde L,\tilde N}$ big enough so that for $k\leq \tilde N$ the minimum of $J_{\tilde L,\tilde N,k}$ is greater than the maximum of $\bigcup _{(l,n,k)\leq (L,N,N)} J_{l,n,k}$ . Then we will use that $(j_{n,k})_k$ is Sidon to show that, for $k\leq \tilde N$ , the $J_{\tilde L,\tilde N,k}$ are pairwise disjoint.

Let $m_{\tilde L,\tilde N}$ such that for every $(l',n')\leq (L,N),$

(1) $$ \begin{align} m_{\tilde L,\tilde N}>2m_{l',n'}j_{n',n'}+\frac{m_{l',n'}}{2}. \end{align} $$

We claim that for every $k\leq \tilde N$ , the set $J_{\tilde L,\tilde N,k}$ is disjoint from $J_{l',n',k'}$ for every $(l',n',k')\leq (L,N,N)$ . Indeed,

$$ \begin{align*} \min J_{\tilde L,\tilde N,k}&= b_{\tilde L,\tilde N,k}= m_{\tilde L,\tilde N}j_{\tilde N,k}\geq m_{\tilde L,\tilde N}j_{\tilde N,1}\\ &> 2m_{l',n'}j_{n',k'}+\frac{m_{l',n'}}{2}= \max J_{l',n',k'}. \end{align*} $$

So, it only remains to prove that $J_{\tilde L,\tilde N,k}$ , with $1\leq k\leq \tilde N$ , are pairwise disjoint.

Suppose otherwise and let $t\in J_{\tilde L,\tilde N,k_1}\cap J_{\tilde L,\tilde N,k_2}$ . Hence, there are $ (L_i',N_i',k_i')\leq (\tilde L,\tilde N,k_i)$ such that for $i=1$ and $i=2$ we have that

$$ \begin{align*} m_{\tilde L,\tilde N}j_{\tilde N,k_i}+m_{L_i',N_i'}j_{N_i',k_i'}\leq t\leq m_{\tilde L,\tilde N}j_{\tilde N,k_i}+m_{L_i',N_i'}j_{N'_i,k_i'} +\frac{m_{\tilde L,\tilde N}}{2}. \end{align*} $$

Note that $k_i'$ may be equal to 0 here. This is the case if $t\in [b_{\tilde L,\tilde N,k_i},b_{\tilde L,\tilde N,k_i}+({m_{\tilde L,\tilde N}})/{2}]$ .

Therefore $j_{\tilde N, k_i}\hspace{-2.3pt}+\hspace{-1.2pt}({m_{L_i',N_i'}})/({m_{\tilde L,\tilde N}})j_{\tilde N,k_i'}\hspace{-1.5pt}\leq\hspace{-1pt} {t}/({m_{\tilde L,\tilde N}})\hspace{-1.2pt}\leq\hspace{-1.3pt} j_{\tilde N,k_i}\hspace{-2.5pt}+\hspace{-1pt}({m_{L_i',N_i'}})/({m_{\tilde L,\tilde N}}) j_{\tilde N,} {}_{k_i'}\hspace{-1.2pt} +\hspace{-1.4pt} \tfrac {1}{2}$ , $i=1,2$ . Applying (1), we obtain that if $(L_i',N_i')<(\tilde L,\tilde N)$ ,

$$ \begin{align*} j_{\tilde N, k_i}\leq \frac{t}{m_{\tilde L,\tilde N}}< j_{\tilde N,k_i} +1. \end{align*} $$

Otherwise, if $(L_i',N_i')=(\tilde L,\tilde N)$ , we obtain

$$ \begin{align*} j_{\tilde N, k_i}+j_{\tilde N,k_i'}\leq \frac{t}{m_{\tilde L,\tilde N}}\leq j_{\tilde N,k_i}+j_{\tilde N,k_i'} +\frac{1}{2}. \end{align*} $$

Thus, for example, if $(L_1',N_1')<(\tilde L,\tilde N)$ and $(L_2',N_2')=(\tilde L,\tilde N)$ , the above inequalities show that $j_{\tilde N, k_1}=\lfloor {t}/({m_{\tilde L,\tilde N}})\rfloor =j_{\tilde N, k_2}+j_{\tilde N, k_2'}$ . This is a contradiction because $\{0,j_{\tilde N,1},\dots ,j_{\tilde N,\tilde N}\}$ is Sidon, $k_1\neq k_2$ and $k_2'\leq k_2$ .

The other cases,

• • $(L_1',N_1')<(\tilde L,\tilde N)$ and $(L_2',N_2')<(\tilde L,\tilde N)$ ,

• • $(L_1',N_1')=(\tilde L,\tilde N)$ and $(L_2',N_2')<(\tilde L,\tilde N)$ ,

• • $(L_1',N_1')=(L_2',N_2')=(\tilde L,\tilde N)$ ,

are similar.

We have proved that the sets $J_{l,n,k}$ , $1\le k\le n\le l$ , are pairwise disjoint and thus $b_{l,n,k}$ is a $\Delta _{l,n,k}$ -Sidon sequence for some $\Delta _{l,n,k}\to \infty $ . Therefore, by Theorem 3.8, there are parameters $w_{l,n,k},{1}/({a_{l,n,k}})\to 0$ and $u_{l,n,k}\to \infty $ such that if $P_{l,n,k}$ is controlled by $u_{l,n,k}$ then T is continuous and not weakly mixing.

We consider a family of polynomials $P_{l,n,k}=P_{l,k}$ controlled by $u_{l,n,k}$ such that for every $n, ( P_{l,1}\oplus P_{l,2}\oplus \cdots \oplus P_{l,n})_{l\geq n}$ is dense in $\bigoplus _{k\leq n} {\mathbb {C}}([x])$ . To construct this sequence of polynomials just consider $v_{l,k}=\min _{n\in [k,l]} \{u_{l,n,k}\}$ and a dense sequence $(Q_l)_l\subset \bigoplus _{k\in \mathbb N} {\mathbb {C}}[x]$ , where $Q_l=([Q_l]_1,[Q_l]_2,\ldots ),$ with the additional property that each $[Q_l]_k$ is controlled by $ v_{l,k}$ whenever $l\geq k$ .

The polynomials $P_{l,k}=[Q_l]_k$ satisfy the desired property.

It remains to show that for every n and k, $e_1\oplus e_1\oplus \cdots \oplus e_1$ is a hypercyclic vector for $T^{j_{n,1}}\oplus T^{j_{n,2}}\oplus \cdots \oplus T^{j_{n,n}}$ . Indeed,

$$ \begin{align*} &(T^{j_{n,1}}\oplus T^{j_{n,2}}\oplus\cdots \oplus T^{j_{n,n}})^{m_{l,n}}(e_1\oplus\cdots \oplus e_1)\\ &\quad= (T^{b_{l,n,1}}\oplus T^{b_{l,n,2}}\oplus\cdots \oplus T^{b_{l,n,n}})(e_1\oplus\cdots \oplus e_1)\\ &\quad=P_{l,1}(T)(e_1)+ {e_{ b_{l,n,1}}}/{ a_{l,n,1}}\oplus \cdots \oplus P_{l,n}(T)(e_1)+ {e_{ b_{l,n,n}}}/{a_{l,n,n}}. \end{align*} $$

Thus $((T^{j_{n,1}}\oplus T^{j_{n,2}}\oplus \cdots \oplus T^{j_{n,n}})^{m_{l,n}}(e_1\oplus \cdots \oplus e_1))_{l\ge n}$ is dense in $\bigoplus _{1\leq k\leq n} \ell _1$ .

Proof. Let $U_1,V_1,U_2,V_2\ldots U_N,V_N$ be non-empty open sets.

Put $W_1=U_1$ and $n_1=0$ . By an inductive argument we construct non-empty open sets $W_N\subseteq W_{N-1}\ldots \subseteq W_1\subseteq U_1$ and numbers $n_1,\ldots n_N$ such that for every i, $n_i\in N_{T_{i}}(W_{i-1},U_i)$ and $W_i=W_{i-1}\cap T_i^{-n_i}(U_i)$ .

Since each $T_i$ is hypercyclic we have that each $T^{-n_i} (V_i)$ is a non-empty open set. Let $m\in \bigcap _{i=1}^N N_{T_i} (W_N, T^{-n_i} (V_i))$ . We will show that $m\in \bigcap _{i=1}^N N_{T_i}(U_i,V_i)$ . For $i=1$ it is clear because $W_N\subseteq U_1$ and $T^{-n_1}(V_1)=V_1$ . If $i>1$ , there is $x_i\in W_N$ such that $T_i^m(x_i)\in T_i^{-n_i}(V_i)$ . Hence $T_i^{m+n_i}(x_i)\in V_i$ . Using that $W_N\subseteq W_i\subseteq T_i^{-n_i}(U_i)$ , we see that $T_i^{n_i}(x_i)\in U_i$ . Therefore, $m\in N_{T_i}(U_i,V_i)$ .

Proof. Let U be a non-empty open set and $V_l: 1\leq l\leq n$ be non-empty open sets. We will prove that $\bigcap _{l\leq n} N_{T^{j_2^l-j_1^l}}(U,V_l) $ is non-empty.

By Proposition 2.4 there is a disjoint hypercyclic vector $x\in U$ . Let $m\in \mathbb N$ such that for every $1\leq l\leq n$ , $T^{j^l_2 m}(x)\in V_l$ and $T^{j_1^lm}(x)\in U$ . Therefore, $j_2^lm-j_1^lm\in N_T(x,V_l)-N_T(x,U)=N_T(U,V_l)$ . We conclude that $m\in N_{T^{j_2^l-j_1^l}}(U,V_l)$ for every $1\leq l\leq n$ .

Proof. Let T be the operator constructed in Theorem 3.4. Then T is not weakly mixing and $\{T^{j}:j\in J\}$ is disjoint hypercyclic for every finite J such that $J\cup \{0\}$ is Sidon.

Suppose that $J_n=\{k_1,k_1+1,k_2,k_2+2,\dots ,k_n,k_n+n\}$ is a Sidon set. Then Proposition 4.2 implies that $T\oplus T^2\oplus \dots \oplus T^n$ is hypercyclic. Indeed, we may just take $j_2^l=k_l+l$ and $j_1^l=k_l$ for $l=1,\dots , n$ .

If we take $k_1=n+1$ and $k_{j+1}=2(k_j+j)+1$ then it is simple to show that $J_n\cup \{0\}$ is Sidon. Indeed, suppose that $0\leq a_1\leq a_2\leq a_3<a_4$ are elements in $J_n\cup \{0\}$ such that $a_1+a_4=a_2+a_3$ . Notice that, by construction, if $l_1\leq l_2<l_3$ then ${k_{l_1}+l_1+k_{l_2}+l_2<k_{l_3}}$ . This implies that there is $l\leq n$ such that $a_4=k_l+l$ and $a_3=k_l$ . Hence, $l=a_2-a_1$ . It follows that there must be $l'$ such that $a_2=k_{l'}+l'$ and $a_1=k_{l'}$ , because otherwise $a_2-a_1>n+1>l$ . Thus, $l=a_2-a_1=l'$ , which is a contradiction because $a_2<a_4.$

Proof. $(1)\Rightarrow (2)$ . Since T is a syndetically transitive linear operator, it is thickly transitive. It follows by the above lemma that T is thickly syndetically transitive.

Let $U_1,U_2,V_1,V_2$ be non-empty open sets. Then $N_S(U_2,V_2)$ is thick while $N_T(U_1,V_1)$ is thickly syndetic, that is, for every k, there is a syndetic set A such that $A+\{1,\ldots , k\}\subseteq N_T(U_1,V_1)$ . Let $k\in \mathbb N$ . Then $N_S(U_2,V_2)\cap A+\{1,\ldots , k\}$ contains k consecutive integers.

$(2)\Rightarrow (3)$ . Let S be a weakly mixing operator. Then $T\oplus S$ is weakly mixing. In particular, $T\oplus S$ is hypercyclic.

$(3)\Rightarrow (1)$ . We will prove that if T is not syndetically transitive, then there is a weakly mixing operator S such that $T\oplus S$ is not hypercyclic.

Let T be not syndetically transitive. Hence there are non-empty open sets $U,V$ such that $N_T(U,V)$ is not syndetic. Thus, there is a sequence $(n_k)$ for which $n_{k+1}>n_k+k$ and

$$ \begin{align*}\bigcup_k [n_k,n_k+k]\subseteq N_T(U,V)^c.\end{align*} $$

It suffices to show the existence of a weakly mixing operator S and a non-empty open set W for which

$$ \begin{align*}N_S(W,W)\subseteq \bigcup_k [n_k,n_k+k].\end{align*} $$

Let S be the weighted backward shift on $\ell _2$ given by the weights

$$ \begin{align*}w_n=\begin{cases} 2 &\text{ if } n\in [n_k,n_k+k] \text{ for some } k,\\ 2^{-k} &\text{ if } n=n_k+k+1,\\ 1 &\text{ otherwise}. \end{cases} \end{align*} $$

The weights $(w_n)_n$ are bounded and $\prod _{j=1}^{n_k+k} w_j=2^k$ . These facts imply that $B_w$ is well defined and that $B_w$ is weakly mixing (see [Reference Grosse-Erdmann and Peris Manguillot21, Ch. 4]). On the other hand, we notice that if $n\notin \bigcup _k [n_k,n_k+k]$ , then $\prod _{j=1}^n w_j=1$ .

Consider now $W=B(e_1,\varepsilon )$ with $\varepsilon <\tfrac {1}{2}$ and let $n\in N_S(W,W).$ Hence, there is x such that $\|x-e_1\|<\varepsilon $ and $\|S_w^n(x)-e_1\|<\varepsilon .$ Therefore,

$$ \begin{align*}|x_n|<\varepsilon \ \ \text{ and }\ \ \bigg|\prod_{j=1}^n w_j x_n-1\bigg|=|[B_w^n(x)-e_1]_1|<\varepsilon.\end{align*} $$

It follows that $n\in \bigcup _k [n_k,n_k+k].$

Proof. $(1)\Longrightarrow (2)$ . Suppose that T is piecewise syndetically transitive and let S be a syndetically transitive operator. Then S is, by Lemma 5.2, thickly syndetically transitive. By the duality between the piecewise syndetic and the thickly syndetic sets, we obtain that for every tuple of non-empty open sets $U_1,U_2,V_1,V_2$ ,

$$ \begin{align*}N_T(U_1,V_1)\cap N_S(U_2,V_2)\neq \emptyset\end{align*} $$

and hence $T\oplus S$ is hypercyclic.

$(2)\Longrightarrow (1)$ . Suppose that T is not piecewise syndetically transitive. It suffices to show the existence of a syndetically transitive operator S and non-empty open sets $U,V,W$ such that $N_S(W,W)\subseteq N_T(U,V)^c$ .

Since T is not piecewise syndetically transitive there are non-empty open sets $U,V$ such that $N_T(U,V)$ is not piecewise syndetic. By duality, there is a thickly syndetic set A such that $N_T(U,V)\cap A=\emptyset $ . It follows that $N_T(U,V)^c$ is thickly syndetic. Equivalently, we have that for every k, $\{n:[n,n+k]\subseteq N_T(U,V)^c\}$ is syndetic.

Let S be the weighted backward shift on $\ell _2$ given by the weights

$$ \begin{align*}w_n=\begin{cases} 2 &\text{ if } n\in N_T(U,V)^c,\\ 2^{-l} &\text{ if } n\notin N_T(U,V)^c, n-1\in N_T(U,V)^c \text{ and }\\ & l =\max\{j\in\mathbb N:[n-j,n-1] \subseteq N_T(U,V)^c\},\\ 1 &\text{ otherwise}. \end{cases} \end{align*} $$

The weights $w_n$ are bounded and hence S is a well-defined backward shift. Also, for every k, $\{n:[n,n+k+1]\subseteq N_T(U,V)^c\}\subseteq \{n: \prod _{j=1}^n w_j>2^k\}$ . This implies that for every M, $\{n: \prod _{j=1}^n w_j>M\}$ is syndetic and hence S is syndetically transitive [Reference Bès, Menet, Peris and Puig7, Corollary 3.4]. On the other hand, we notice that if $n\notin N_T(U,V)^c$ , then $\prod _{j=1}^n w_j=1$ .

Consider now $W=B(e_1,\varepsilon )$ with $\varepsilon <\tfrac 12$ and let $n\in N_S(W,W)$ . Thus, there is x such that $\|x-e_1\|<\varepsilon $ and $\|S^n(x)-e_1\|<\varepsilon $ . Therefore,

$$ \begin{align*}|x_n|<\varepsilon \quad \text{and}\quad \bigg|\prod_{j=1}^n w_j x_n-1\bigg|=|[B_w^n(x)-e_1]_1|<\varepsilon.\end{align*} $$

It follows that $n\in N_T(U,V)^c.$

Proof. Let $C>0$ such that $n_k\leq Ck^2.$ Notice that $\#\{k\leq K:n_{k+1}-n_{k}\geq 8Ck\}\leq {K}/{2}$ . Indeed, if we suppose otherwise, then we get that

$$ \begin{align*} n_K-n_1=\sum_{l=1}^K n_{l+1}-n_l\geq \sum_{l=1}^{{K}/{2}}8Ck>CK^2, \end{align*} $$

which is a contradiction. Hence, $\#\{k\leq K:n_{k+1}-n_{k}\leq 8Ck\}\geq {K}/{2}$ . This implies that

$$ \begin{align*}\underline d \{n_k-n_j:k\geq j\}\geq \frac{1}{16C}.\end{align*} $$

Proof of Theorem 5.5

Let T be a non-weakly mixing operator and x such that for every non-empty open set U, $N_T(x,U)\in O(n^2)$ . By the above lemma we get that for every non-empty open set U, $N_T(U,U)=N_T(x,U)- N_T(x,U)$ has positive lower density.

Consider now a pair of non-empty open sets $U,V$ . Since T is hypercyclic, there are $U'\subseteq U$ and n such that $T^n(U')\subseteq V$ . Hence $N_T(U',U')+n\subseteq N_T(U,V)$ and therefore $N_T(U,V)$ has positive lower density.

Question. Let T be a piecewise syndetically transitive linear operator. Is T weakly mixing?