There are many good contributed answers which adequately address the questions. However, the coverage of NULL is light.
In a modern virtual memory architecture, NULL points to memory for which any reference (that is, an attempt to read from or write to memory at that address) causes a segfault exception—also called an access violation or memory fault. This is an intentional protective mechanism to detect and deal appropriately with invalid memory accesses:
char *p = 0;
for (int j = 0; j < 50000000; ++j)
*(p += 1000000) = 10;
This code writes a ten at every millionth memory byte. It won't run for many loops—probably not even once. Either it will attempt to access an unmapped address, or it will attempt to modify read-only memory—where constant data or program code reside. The CPU will interrupt the instruction midway and report the exception to the operating system. Since there's no exception handling specified, the default o/s handling is to terminate the program. Linux displays
Segmentation fault (for historical reasons). MS Windows is inconsistent, but tends to say
access violation. The same should happen with any program in protected virtual memory doing this:
char *p = NULL;
if (p  == 'Y')
printf ("A miracle has occurred!\n");
This segfaults. A memory location near the NULL address is being dereferenced.
At the risk of confusion, it is possible that a large offset from zero will be valid memory. Thirty-four certainly won't be okay, but 34,000 might be. Different operating systems and different program processing tools (linkers) reserve a fixed amount of the zero end of memory and arrange for it to be unmapped. It could be as little as 1K, though 8K was a popular choice in the 1990s. Systems with ample virtual address space (not memory, but potential memory) might leave an 8M or 16M memory hole. Some modern operating systems randomize the amount of space reserved, as well as randomly varying the locations for the code and data sections each time a program starts.
The other extreme is non-virtual memory architectures. Typically, these provide valid addresses beginning at address zero up to the limit of installed memory. Such is common in embedded processors, many DSPs, and pre-protected mode CPUs, 8 and 16-bit processors like the 8086, 68000, etc. Reading a NULL address does not cause any special CPU reaction—it simply reads whatever is there, which is usually interrupt vectors. Writes to low memory usually result in hard-to-diagnose dire consequences as interrupt vectors are used asynchronously and infrequently.
Even stranger is the segment model of the oddly named "real-mode" x86 using small or medium memory model conventions. Such data addresses are 16 bits using the
DS register which is set to the program's initialized data area. Dereferencing NULL accesses the first bytes of this space, but MSDOS programs contain ancient runtime structures for compatibility with CP/M, an o/s Fred Flintstone used. No exceptions, and maybe no consequences for modifying the memory near NULL in this environment. These were challenging bugs to find without program source code.
Virtual memory protection was a huge leap forward in creating stable systems and protecting programmers from themselves. Properly used NULLs provide significant safety and rapid debugging of programming flaws.