If an application makes use of, for example, the Intel maths libraries and has been compiled with the right switches, routines like FFTs will at runtime be split out into separate threads matching the number of cores in the machine. Your source code remains 'single threaded', but the library is creating and destroying threads behind your back.
Similarly some compilers (e.h. Intel's icc, Sun's C compiler) may turn some loops into separate threads, each tackling a share of the iterations. Again the source code looks single threaded, but the compiler generates threaded code on your behalf. It's a bit like automatically applying some OpenMP to your source code.
OSes cannot second guess what an application is going to do, so they cannot intervene like this. Libraries and compilers know what is about to happen, so they can.
Libraries and compiler tricks like this have been developed so as to make it easy for programmers to extract higher performance from 'single' threaded code. Intel started adding features like that to their maths library around about the same time they started heading towards multi-core CPUs. The idea was to create (from the programmer's point of view) the impression of better 'single' thread performance, whilst the speed was actually being delivered by multiple cores. Similarly with Sun when they started doing multi-processor computers.
And with everyone more or less giving up on making significant improvements to the performance of a single core, this is the only way ahead.
2) Yes. How else would it do it?