I have just read some article talking about the quantum physics. One interesting thing is that in Haskell programmer's view there are some similarity between these two fields.
First of all, measurement in quantum world seems similar to lazy evaluation in Haskell. If you do not measure, you don't know wether the cat is living or dead. If you do not evaluate, you don't know wether the value is defined or
Second, in quantum we have EPR paradox, which can be explained by interactions with speed higher than light, or equivalently, time machine. In Haskell, as we have seen in Assembly: Circular Programming with Recursive do -Monad.Reader issue 6, we can access a value that came from the future by use of recursive do.
Finally, in quantum we have to distinguish the observable world in which entropy never decrease, and the "pure" quantum world which time is equivalent in both directions. In Haskell we have
IO() world that describes what the program actually do, and the pure functional world that never have side effects, and the values are never depends on evaluation order.
So I guess the above fact prompts there are some inter-connection between these two fields. Can this have more interesting consequences? For example, although I have talked about EPR paradox, I don't know how to create a Haskell program to simulate this: a function creates two values, and later evaluation of one of them will affect another (I think those values must have
IO() types but I don't know how to put them together).