Synthesis and Airthmetic of Single Qutrit Circuits

In this paper we study single qutrit quantum circuits consisting of words over the Clifford+ $\mathcal{D}$ gate set, where $\mathcal{D}$ consists of cyclotomic gates of the form $\text{diag}(\pm\xi^{a},\pm\xi^{b},\pm\xi^{c}),$ where $\xi$ is a primitive $9$-th root of unity and integers $a,b,c$. We characterize classes of qutrit unit vectors $z$ with entries in $\mathbb{Z}[\xi, \frac{1}{\chi}]$ based on the possibility of reducing their smallest denominator exponent (sde) with respect to $\chi := 1 - \xi,$ by acting an appropriate gate in Clifford+$\mathcal{D}$. We do this by studying the notion of `derivatives mod $3$' of an arbitrary element of $\mathbb{Z}[\xi]$ and using it to study the smallest denominator exponent of $HDz$ where $H$ is the qutrit Hadamard gate and $D \in \mathcal{D}.$ In addition, we reduce the problem of finding all unit vectors of a given sde to that of finding integral solutions of a positive definite quadratic form along with some additional constraints. As a consequence we prove that the Clifford + $\mathcal{D}$ gates naturally arise as gates with sde $0$ and $3$ in the group $U(3,\mathbb{Z}[\xi, \frac{1}{\chi}])$ of $3 \times 3$ unitaries with entries in $\mathbb{Z}[\xi, \frac{1}{\chi}]$