Proof Let the word w equal $w(X_1, \ldots , X_n) = X_{i_m} \dots X_{i_1}$ , where $i_1, \ldots , i_m \in \{ 1, \ldots , n \}$ . Put $a_0= \emptyset $ , $a_k = X_{i_k} \dots X_{i_1}$ , $k=1,\ldots , m$ . Let now $T_j=(t_{rs}^{(j)})_{r,s=0}^{m-1}$ , $j=1,\ldots , n$ , be defined via

$$ \begin{align*}t_{rs}^{(j)} =\left\{ \begin{matrix} 1, & \text{if} & X_j a_s = a_r, \cr 1, & \text{if} & r=0, s=m-1, X_j a_{m-1} = a_m, \cr 0, & \text{otherwise.} & \end{matrix} \right.\end{align*} $$

Notice that $T_j$ only has nonzero entries in the diagonal $\{(i,j): j-i=m-1 (\text {mod}\ m)\}$ , so that the product of k matrices $T_j$ only has nonzero entries in the diagonal $\{(i,j): j-i=m-k (\text {mod}\ m)\}$ . Thus for any word $\tilde {w}$ of length less than m, we have that $\tilde {w}(T_1, \ldots , T_n)$ has zeros on the main diagonal, and thus its trace equals 0. When $\tilde {w}$ has length m it is not hard to see that $\tilde {w}(T_1, \ldots , T_n)$ has 1’s on the diagonal if and only if $\tilde {w}$ is cyclically equivalent to w, and otherwise there will only be zeros on the diagonal. It may be helpful to think of the operators $T_1,\ldots , T_n$ also in the following way.

Let us denote the words that are cyclically equivalent to w as follows: $w_0 = w =a_0 w, w_1=X_{i_1}X_{i_m} \dots X_{i_2}=:a_1 b_1, \ldots , w_{m-1} = X_{i_{m-1}} \dots X_{i_1} X_{i_m} =: a_{m-1}b_{m-1}.$ In this setting, we have that $ t_{rs}^{(j)} =1$ if and only if $r-s=1 (\text {mod}\ m)$ , $X_j$ is the last letter of $w_s$ and $w_r$ is obtained from $w_s$ by moving $X_j$ to the front. In this interpretation, the product $T_jT_k$ has a 1 in position $(r,s)$ if and only if $r-s=2 (\text {mod}\ m)$ , and $w_r$ is obtained from $w_s$ by moving $X_k$ to the front and subsequently $X_j$ to the front. Similarly, any product of $T_j$ ’s can be interpreted.

Proof Let us write $M(X) = \sum _{i=1}^n A_i \otimes X_i$ , where $X \in {\mathcal D}$ . We now have that

$$ \begin{align*}f_A(X)= e^{-\tau(\sum_{m=1}^\infty \frac{M(X)^m}{m})} = 1-\tau(\sum_{m=1}^\infty \frac{M(X)^m}{m}) + \frac{1}{2!}(\tau(\sum_{m=1}^\infty \frac{M(X)^m}{m}))^2 - \dots .\end{align*} $$

Extracting the degree k term, we obtain

$$ \begin{align*}-\tau(\frac{M(X)^k}{k}) + \frac{1}{2!} \sum_{j=1}^k {k\choose j} \tau(\frac{M(X)^j}{j}) \tau(\frac{M(X)^{k-j}}{k-j})- \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \ \end{align*} $$

$$ \begin{align*}\ \ \ \ \ \ \ \ \ \ \ \frac{1}{3!} \sum_{j_1+j_2+j_3=k, j_i\ge 1} \begin{pmatrix} k \cr j_1,j_2,j_3 \end{pmatrix} \tau(\frac{M(X)^{j_1}}{j_1}) \tau(\frac{M(X)^{j_2}}{j_2})\tau(\frac{M(X)^{j_3}}{j_3}) + \dots .\end{align*} $$

Let now $U=(u_{ij})_{i,j=1}^k$ be the $k\times k$ unitary circulant with $u_{ij} =1$ when $j=i+1\mod k$ , and $0$ elsewhere. Then $\mathrm {Tr}\ U^j $ equals 1 when k divides j, and 0 otherwise. If we now let $x_i = U\otimes X_i$ , $i=1,\ldots n$ , we have that $x=(x_1,\ldots , x_n)\in {\mathcal D}$ , and the degree k term in $f_A(x)$ now equals $ -\tau (\frac {M(X)^k}{k})$ . Indeed, whenever $1\le j <k$ , we have that $ \tau (\frac {M(X)^j}{j})=0$ since $\mathrm {Tr}\ U^j =0$ . Next, notice that $M(X)^k= \sum _w w(A_1, \ldots , A_n) \otimes w(X_1,\dots , X_n)$ , where the sum is taken over all words of length k. Since the monomials are linearly independent by Lemma 2.2, the result follows.

Proof Due to the failure of the Connes embedding conjecture [Reference Ji, Natarajan, Vidick, Wright and Yuen8], it follows from [Reference Klep and Schweighofer9, Proposition 3.17] (complex case) and [Reference Burgdorf, Dykema, Klep and Schweighofer2, Proposition 3.2] (real case) that there exists a $\mathrm {II}_1$ factor ${\mathcal F}$ with a faithful tracial state $\tau $ , an $\epsilon>0$ , $n,k\in {\mathbb N}$ , and self-adjoint/symmetric contractions $A_1, \ldots , A_n$ so that for all $s\in {\mathbb N}$ and self-adjoint/symmetric contractions $B_1,\ldots , B_n \in {\mathbb K}^{s\times s}$ there exists a word $w_0$ in n letters of length k so that

$$ \begin{align*}| \tau (w_0(A_1, \ldots , A_n)) - \mathrm{Tr} (w_0(B_1,\ldots , B_n )) | \ge \epsilon.\end{align*} $$

So by Lemma 2.3, we are done.

Proof We will show that $f_A (x_1,\ldots , x_n) = f_B(x_1,\ldots , x_n)$ , for all scalars $x_j$ with $\sum _{i=1}^n |x_j|< 1$ , if and only if $\tau (p(A)) = \tau (p(B))$ for every BMV polynomial p, and thus we would be done. Note that instead of scalars $x_j$ , we may also use simultaneously diagonalizable $x_j$ ’s.

Proceeding in a similar way as in the proof of Lemma 2.3, let $U=(u_{ij})_{i,j=1}^k$ be the $k\times k$ unitary circulant with $u_{ij} =1$ when $j=i+1\ \mod k$ , and $0$ elsewhere. Then $\mathrm {Tr}\ U^j $ equals 1 when k divides j, and 0 otherwise. If we now let $X_i = x_iU$ , $i=1,\ldots n$ , we have that $X=(X_1,\ldots , X_n)\in {\mathcal D}$ whenever $\sum _{i=1}^n |x_j|< 1$ , and the degree k term in $f_A(X)$ now equals $ -\tau (\frac {M(X)^k}{k})$ . Indeed, whenever $1\le j <k$ we have that $ \tau (\frac {M(X)^j}{j})=0$ since $\mathrm {Tr}\ U^j =0$ . Next, notice that $M(X)^k= \sum _w w(A_1, \ldots , A_n) \otimes w(X_1,\dots , X_n)$ , where the sum is taken over all words of length k. On scalar inputs, this reduces to $(t_1A_1+\dots +t_n A_n)^k,$ so we are done by linear independence of monomials. This linear independence can be established in a similar way as in Lemma 2.2, where now we choose $C_k$ the $k\times k$ circular shift, and we take operators T of the form $I\otimes \cdots \otimes I \otimes C_k \otimes I \otimes \cdots \otimes I$ .