Since you gave no details I'm assuming you are interested in behavior of Unix-like systems.
open() system call only creates a file descriptor which then may be used by either
Both memory mapped I/O and standard I/O internally access files on disk through page cache, a buffer in which files are cached in order to reduce number of I/O operations.
Standard I/O approach (using
read()) involves performing a system call which then copies data from (or to if you are writing) page cache to a buffer chosen by application. In addition to that non-sequential access requires another system call
lseek(). System calls are expensive and so is copying data.
When a file is memory mapped usually a memory region in process address space is mapped directly to page cache, so that all reads and writes of already loaded data can be performed without any additional delay (no system calls, no data copying). Only when an application attempts to access file region that is not already loaded a page fault occurs and the kernel loads required data (whole page) from disk.
I see that I also have to explain memory paging. On most modern architectures there is physical memory which is a real piece of hardware and virtual memory which creates address spaces for processes. Kernel decides how addresses in virtual memory are mapped to addresses in physical memory. The smallest unit is a memory page (usually, but not always 4K). It does not have to be 1:1 mapping, for example all virtual memory pages may be mapped to the same physical address.
In memory mapped I/O part of application address space and kernel's page cache are mapped to the same physical memory region, hence program is able to directly access page cache.