Raising an exception can either be pure OR non-pure, it just depends on the type of exception that is raised. A good rule-of-thumb is if the exception is raised by code, it is pure, but if it is raised by the hardware then it usually must be classed as non-pure.
This can be seen by looking at what occurs when an exception is raised by the hardware: First an interrupt signal is raised, then the interrupt handler starts executing. The issue here is that the interrupt handler was not an argument to your function nor specified in your function, but a global variable. Any time a global variable (aka state) is read or written, you no longer have a pure function.
Compare that to an exception being raised in your code: You construct the Exception value from a set of known, locally scoped arguments or constants, and you "throw" the result. There are no global variables used. The process of throwing an exception is essentially syntactic sugar provided by your language, it does not introduce any non-deterministic or non-pure behaviour. As Don said "It should be semantically equivalent to using a Maybe or Option type", meaning that it should also have all the same properties, including purity.
When I said that raising a hardware exception is "usually" classed as a side effect, it does not always have to be the case. For example, if the computer your code is running on does not call an interrupt when it raises an exception, but instead pushes a special value onto the stack, then it is not classifiable as non-pure. I believe that the IEEE floating point NAN error is thrown using a special value and not an interrupt, so any exceptions raised while doing floating point maths can be classed as side-effect free as the value is not read from any global state, but is a constant encoded into the FPU.
Looking at all the requirements for a piece code to be pure, code based exceptions and throw statement syntactic sugar tick all the boxes, they do not modify any state, they do not have any interaction with their calling functions or anything outside their invocation, and they are referentially transparent, but only once the compiler has had its way with your code.
Like all pure vs non-pure discussions, I have excluded any notion of execution times or memory operations and have operated under the assumption that any function that CAN be implemented purely IS implemented purely regardless of its actual implementation. I also have no evidence of the IEEE Floating point NAN exception claim.