Erlang is probably the best mainstream way to do concurrency because of slow (see shootout) virtual machine but with extremely low overhead per thread and good thread isolation (you cannot mutate data that are not local to thread and can kill and restart threads very easily).
But there are TONS of non-mainstream research and experimental languages specifically designed to treat concurrency much better than an uneducated mind can imagine.
Some of those languages have become mature and production-ready (e.g. GHC implementation of Haskell), but they usually require a PhD in mathematics and/or computer science to write big programs and thus not very useful for commercial apps because of their learning curve.
Haskell support for concurrency includes:
- Light-weight native (as opposed to interpreted) threads ("sparks")
- Software transaction memory
- Data Parallel Haskell (DPH) library
- Communicating Haskell Processes (CHP) library
- many more (MVar, futures, laziness, functional purity etc)
If you want to learn current state of the art, I suggest you going to CiteSeerX or similar catalogs of scientific research publications and reading about Pi-Calculus and related calculi for statically safe concurrency and paralellism. There are literally thousands.
One example of such publication is Communicating Sequential Processes by Tony Hoare. CHP is a Haskell implementation of those ideas.
In general, there are different grades of concurrency support:
- Mainstream (e.g. Java, C#)
- Advanced mainstream (Erlang, Node.js, Clojure, Go)
- Mature research languages and libraries (Haskell, Mozart/Oz, ATS)
- Yet unimplemented ideas or ideas with a buggy and unoptimized implementations (scientific literature and experimental proof-of concept compilers, e.g. "Concurrent Objects in a Process Calculus (1995)" by Pierce)
So to give you a better answer it's good to know why you need an advanced language for concurrency. E.g. are you writing a thesis, doing a hobby research or creating a commercial software product?