Which language is best for serial programming?
Seriously, concurrency covers a lot of ground (at the same time!), and some algorithms that are expressed very naturally in one model of concurrency are incredibly awkward to implement in another.
And if we haven't really figured out what's best for a serial programming language yet, is it any surpise that parallelism- and concurrency-aware languages are way behind even that?
Right now there's a bunch of niche concurrent programming languages, most fairly new, some that some people use, some that no one really will ever much use. There's Erlang -- which has a large niche, to be sure, and significant real world applications, which is more than most of the others can say. But lots of problems are much more easily expressed when there is some shared state, and the message passing in the language itself is (intentionally) very limited compared to other message passing systems -- multicast messages to other Erlang processes aren't "built in" to the language, neither are collective operations. The Erlang language itself is very well suited to lots of internet-type stuff -- anything that looks a lot like a telecom system, basically (little state, and small messages to expendible clients). But as you go further from that sort of programming, Erlang is harder to use. Which is fine; it'd be weird if one tool were good at everything.
People will suggest Go, and Occam, and Scala, and Clojure, and F#, and others. All fine and wonderful languages, have nothing against them, and they obviously have their problems they do very well with. But some fraction of them are going to meet the same end as Ada (1975), Lucid (1976), MultiLisp (1985), etc; languages that were all wrestling (if perhaps with less urgency) with the same issues then as today.
There's a lot of people pushing functional languages for concurrent programming today; that makes sense, as it's about time for it again (it happens every 25 years or so). Functional languages are great, I've recently had a tonne of fun with Haskell, and I'd be lost without Mathematica. The argument, (which again, every 25 years or so is apparently very compelling) is that the explicit flow of data should make automatic parallelization by the compiler and runtime very straightforward. SISAL (1983) actually had some good luck with that, as you probably would have learned in your SISAL programming course in high-school, had it ever taken off. It's worth pointing out that what's unquestionably the most successfull parallel functional language, Erlang, didn't even try to take this approach and just baked message passing into the language instead. It's parallelism is unrelated to its functional nature.
There's a series of programming languages for parallel scientific computing that are coming around now; UPC, X10, Chapel, Titanium, Fortress -- all look to be very useful for their particular problem sets, but again, some of them will fall by the waysides; but that's the only way to find out what works and what doesn't. The venerable FORTRAN (which survives because it is very good at what it does) is adding co-arrays, which are going to be huge for number crunching applications, but would be a disaster as a basis for writing chatrooms or telecom switches.
An interesting book for some perspective on this is Introduction to Concurrency in Programming Languages which goes through the history in some detail; you won't have a lot more answers after reading the book, but at least you'll be able to survey the current, fragmented, state of affairs and have something like an answer to the question: ``How the $%^ did we get here?''