talonmies and chaohuang provide good information in the comments, and you should look into that (not sure why these aren't answers, but that's their call). In any event, I will provide an abbreviated partial answer to explain something that you might not be considering.
Let's say that you have 8 threads of control, and 8 processors. If all the instructions in all 8 threads are on-chip instructions taking only a single cycle, then all 8 threads will finish in
n cycles (assuming
n total instructions per thread).
Now let's say that each thread of control consists of
n instructions, where a fraction
r of these are off-chip memory instructions, which take, e.g., 100 cycles to complete. These 8 threads will now take
[(1 - r) + 100r]n cycles to complete. If
r=0.1, this is about 11 times more than the previous case.
Now let's say that we have 16 threads. When the first batch of 8 threads is blocked on the slow operations, the other threads can execute; on-chip instructions can execute, and off-chip instructions can start. So instead of needing
2[(1 - r) + 100r]n cycles to complete all threads, you might need only a little more than
[(1 - r) + 100r]n. In essence, because you have some room to overlap waiting threads with other threads, you can add more threads for free.
This is the great strength of the GPU model: massive parallelism to overcome long latency. It takes a long time to do a little bit of work, but not much more time to do a lot more work. Note that occupancy - related to the amount of work (in threads) you have ready to hide latency - isn't all that important for peak performance when the arithmetic intensity (related to
r in the above formulae) is high. You might play around with the CUDA Occupancy Calculator to see the effect I descibe for different scenarios.