The problem with all of the binary methods above is that they are limited to integers only. If by "exponentiation" you mean compute the e^x function, the best I have seen is power series that converge quickly, and polynomial, rational, or Pade approximations that are valid over a limited range.
One thing for sure: if you find a lightning fast algorithm for e^x to 96 decimal places, you will also have found a faster way to compute logs (by Newton-Raphson). In fact, Newton-Raphson converges quadratically, so you double the number of digits of precision in your log with each iteration. This was a favorite of Nate Grossman of UCLA back in the Forth days.
Back in the days of four-banger calculators, I used to use e^x = (1+x/1024)^10. Of course that breaks down for x very large or very small, but you can see why it works. If you have a square root button, you can reverse this idea to get logarithms. But you don't need square root for the exponential function.
I wonder if there is some inversion of the AGM algorithm that could do the exponential function... Hmmm....