I'm a master student focused on distributed systems but also interested on theoretical computer science. I was wondering if there is a formal representation of a distributed system on top of a turing machine? That is, is it possible to extend (make a variant) the concept of a turing machine to take advantage of distributed computing?
One idea, is to make a shared tape (something similar to Tuple Space) between TM.
[Is there] a formal representation of a distributed system on top of a turing machine?
Regarding this, the discussion (see link posted by Jukka on comments) is the way to look. The way, I see it, how you would formally represent a distributed system largely depends on how you view them, and that depends on "your favourite system assumptions" (i.e., the assumptions on synchrony (i.e., relative timing of actions in the distributed system), on communication (message passing vs. shared memory), on faults (of processes and/or links, benign or Byzantine, etc). As the community does not agree on this point, there is also no agreement on the basic formalism.
[Is] it possible to extend (make a variant) the concept of a turing machine to take advantage of distributed computing?
I guess it is entirely possible, but no-one (that I know of) has looked into it. What I know of are these:
You might want to look into Pi-Calculus.
http://en.wikipedia.org/wiki/%CE%A0-calculus
Its a processed based calculus designed for reasoning about distributed systems.
I'm surprised that Petri Nets have not yet been mentioned! Extensions of Petri Nets like Coloured Petri Nets or Petri Nets with inhibitor arcs are Turing-complete.
(Warning: somewhat biased views, oversimplifications, and blatant generalisations ahead.)
Often the difference between distributed computing and parallel computing can be summarised as follows:
If you take this perspective, then it often turns out that in order to model distributed systems, it does not really matter that what kind of computational power your nodes (or processors or computers) happen to have.
Typically, you can simply assume that each node is just a state machine (often it is enough to have a reasonably small number of possible states, such as $O(n)$). The machine changes its state based on the messages it receives. Usually you are not that interested in how the machine changes its state. It might be a Turing machine, but this is not really that relevant.
For example, if you take a (reasonable) graph problem $X$ and study the distributed complexity of solving $X$ (e.g., the number of communication rounds required to solve it), the way you model computation at each node does not usually affect the answer. If you analyse it first by using Turing machines, and then by assuming an arbitrarily powerful oracle, the answer is typically the same. You can add non-uniform advice and it does not change anything.
The "bottleneck" is that you cannot gather information quickly. In $T$ communication rounds, no matter what you do, each node can only have information regarding its own radius-$T$ neighbourhood. You could have an arbitrarily powerful processor at each node, but what good does it do if the processors do not have any information to process!
Hence using Turing machines as the starting point in order to model distributed systems sounds a bit unnatural to me: if this is an irrelevant aspect, why build everything on top of it? On the other hand, in parallel computing this would be natural (except that the model is usually something like PRAM instead of Turing machines).
Some argue that depending on your view, you could think of distributed systems as something more powerful than a Turing Machine, because of different interpretations of boundedness of non-determinism and fairness. This link has an interesting discussion on the topic. Herlihy/Shavit in their book "The art of multiprocessor programming" argue that Turing computability inherently refers to the notion of a (sequential) algorithm, and are in some sense not appropriate for reasoning about distributed computing. I should mention that this is arguable and controversial so I hope no one throws me stones because I'm saying this.
