This is a very complex question, the quick answer is that applications that can effectively parallelize the computation can and should use multiple cores.
Think about bash. It executes a sequence of operations, tipically each relying on the results of the previous one. In a scenario like this it's very hard to move some computations to other cores and usually doesn't worth it, as starting a new task and the synchronization (waiting for its results) outweights the benefits of running on multiple cores. Also, you have to do deep dependency analysis which, again, is just extra work.
Some simple web-server tasks like sending out files can work well without multiple cores, as good implementations relying on the sendfile syscall hardly do any work and can serve a lot of clients from a single thread.
Then, there are other kind of problems, where there is a lot of cumputation, but the tasks are easily/trivally parallelizable. There is hardly any dependency between the tasks, the server can communicate with each client independently without knownledge of the interaction with the other clients. If you write a chat bot, each thread can utilize a core (or part of a core) and communicate with that one client. If you have a video stream encoder for tv broadcast you can use 1 or more cores for each channel and create a couple encoders until you hit the limits of the whole CPU. Most of the dynamically generated web-sites belong to this category, the web server can run many instances of a PHP/Python/Ruby "module" each serving one client at a time.
There are also problems, and these are the most common ones, with some (but not too much) dependency between the tasks, lots of computation and some disk I/O. Some of the apps utilize the cores, but because it's hard to write good multithreaded code and reason about the behaviour of the code, the apps very often use less parallelism than what is theoretically possible. After all, somebody has to write that code and maintain it, constantly adding new features.