This question cropped up while I was playing with the equation for time dilation. If I set the speed to be $i$ (imaginary unit) the answer from the equation still makes sense, but does that matter if the input data doesn't make sense? Or rather does the input data make sense?
Let $v=i$ and $c=2$ then $T' = T \sqrt{1 -\frac{i^2} {2^2}}$, or $T' = T \sqrt{1 -\frac{-1} {4}}$, or $T' = T \sqrt{\frac{5}{4}}$.
Am I completely out of bounds here or is it something that can be explained?
In what sense does the answer make sense? Does it describe some physical phenomenon?
You've done the algebra right, and gotten a result, but I don't think your inputs (imaginary velocity) mean anything physically. So the answer can't be expected to mean anything physically.
First off Gamma is $\frac{1}{\sqrt{1-v^2/c^2}}$ but that's beside the point.
While by itself it looks okay, if you plug i into a Lorentz transformation everywhere there's a velocity you will also need to either have your time component complex or one of your spatial components as a complex number. This results in that component reversing sign meaning that the proper time or proper separation between events will no longer be equal which was the whole point of a Lorentz transformation in the first place.
Of note is that occasionally time is defined as complex for calculations in general relativity but this is done for both T and T' (I assumed that you were only defining it for one side of the equation); while this does result in what appears to be an imaginary velocity it's just a mathematical trick so the physicist doesn't have to bother keeping the signs straight in the calculations, since at the end it does not change the physics.
