Many modern cryptographic primitives for hashing and (authenticated) encryption make use of constructions that are instantiated with an iterated cryptographic permutation that operates on a fixed-width state consisting of an array of bits. Often, such permutations are the repeated application of a relatively simple round function consisting of a linear layer and a non-linear layer. These constructions do not require that the underlying function is a permutation and they can plausibly be based on a non-invertible transformation. Recently, Grassi proposed the use of non-invertible mappings operating on arrays of digits that are elements of a finite field of odd characteristic for so-called MPC-/FHE-/ZK-friendly symmetric cryptographic primitives. In this work, we consider a mapping that we call $$\gamma $$
γ
that has a simple expression and is based on squaring. We discuss, for the first time, the differential and linear propagation properties of $$\gamma $$
γ
and observe that these follow the same rules up to a relabeling of the digits. This is an intriguing property that, as far as we know, only exists for $$\gamma $$
γ
and the binary mapping $$\chi _{_{3}}$$
χ
3
that is used in the cryptographic permutation Xoodoo. Moreover, we study the implications of its non-invertibility on differentials with zero output difference and on biases at the output of the $$\gamma $$
γ
mapping and show that they are as small as they can possibly be.