Yes, modern multicore processors are really doing parallel processing, on appropriate tasks and provided the software is properly written to permit it. I have personally tested multithreaded software with a configurable number of threads, and watched the throughput increase proportional to the number of threads until that number was equal to the number of cores: on a four core processor, one thread completed one task in a certain amount of time, and four threads completed four tasks in the same amount of time, a quadrupling of throughput. With additional threads beyond the number of cores, there was no further increase, and in fact a slight decrease: eight tasks on eight threads took more than twice the amount of time to complete than did four tasks on four threads. It was faster just to use four threads and have them each process two tasks in a row.
However, and this may be what your professor is referring to, just having multiple threads does not guarantee that you will be taking advantage of multiple cores. For example, the threads may be limited by contention on a shared resource - say, a piece of memory they all needed to access. They could also be contending for a shared I/O resource, like disk access or network access. In some of these cases, running more than one thread at a time may not improve things, and may actually decrease total throughput.
Finally, the "number of threads" and "number of cores" numbers are different because of Intel's "hyperthreading" architecture, which supposedly allows each core to run two threads at a time. In my experience, hyperthreading is not very useful in the real world: for example, in the test I described above, the cores were hyperthreaded Intel cores, but the peak throughput still occurred when I ran a number of threads equal to the number of physical cores, and dropped when I ran a number of threads equal to Intel's claimed thread capacity. I find it best to pay attention to the number of cores and ignore Intel's "number of threads" claim.