Years ago, I defined the "congruence speed" (radix-$10$) of the integer tetration $^{b}a$ as $V(a,b)$, which is the number of the new(!) rightmost digits that freeze when we move from $b \in \mathbb{Z}^+$ to $b+1$ (i.e., if exactly $d$ digits are frozen at height $b-1$, then $V(a,b) \in \mathbb{N}_0$ is such that $^{b}a \equiv \hspace{1mm} ^{b+1}a \pmod {10^{V(a,b)+d}} \wedge ^{b}a \not\equiv \hspace{1mm} ^{b+1}a \pmod {10^{V(a,b)+d+1}}$).
Then, I defined the "constant congruence speed" of tetration as $V(a)$, which corresponds to the non-negative integer number of the new rightmost digits that freeze when we move from a hyperexponent $\overline{b}:=a+1$ to $\overline{b}+c$, for every $c \in \mathbb{Z}^+$ (as long as $a$ is not a multiple of $10$, the congruence speed of $a$ does not depend on $b$ anymore since $\overline{b}=a+1$ represents a sufficient condition for the above).
Now, I observe that we can do roughly the same thing by taking into account exponentiation, instead of tetration. I mean, let me indicate as $V(a)$^ this (new) constant congruence speed of $a^b$; then we know that if $a$ is a multiple of $10$, $a=10 \cdot k, k \in \mathbb{Z}^+ : k \not\equiv 0 \pmod {10}$, and thus $V(a)$^$=k$ (trivial).
Question: Can we simply state that $V(a)$^$=0$ otherwise by observing that $\left(a^2 \equiv \hspace{1mm} a^3 \pmod {10^d} \wedge a^2 \not\equiv \hspace{1mm} a^3 \pmod {10^{d+1}}\right) \Rightarrow a^3 \not\equiv \hspace{1mm} a^4 \pmod {10^{d+1}}$ holds for any $a \geq 2$ which is not a multiple of $10$ (since the value of $V(1)$ is also trivial to be defined by its own)?
As an example, let me take $a=5$ and so $V(5)$^$=0$ since $5^2 \equiv 5^3 \pmod{10^2} \Rightarrow d(5,2) \geq 2$ and $5^3 \not\equiv 5^4 \pmod {10^3}$.
