Back when C was being written, the PDP-11's MACRO-11 assembly language had:
MOV #'A, R0 // 8-bit character encoding for 'A' into 16 bit register
This kind of thing's quite common in assembly language - the low 8 bits will hold the character code, other bits cleared to 0. PDP-11 even had:
MOV #"AB, R0 // 16-bit character encoding for 'A' (low byte) and 'B'
This provided a convenient way to load two characters into the low and high bytes of the 16 bit register. You might then write those elsewhere, updating some textual data or screen memory.
So, the idea of characters being promoted to register size is quite normal and desirable. But, let's say you need to get 'A' into a register not as part of the hard-coded opcode, but from somewhere in main memory containing:
If you want to read just an 'A' from this main memory into a register, which one would you read?
Some CPUs may only directly support reading a 16 bit value into a 16 bit register, which would mean a read at 20 or 22 would then require the bits from 'X' be cleared out, and depending on the endianness of the CPU one or other would need shifting into the low order byte.
Some CPUs may require a memory-aligned read, which means that the lowest address involved must be a multiple of the data size: you might be able to read from addresses 24 and 25, but not 27 and 28.
So, a compiler generating code to get an 'A' into the register may prefer to waste a little extra memory and encode the value as 0 'A' or 'A' 0 - depending on endianness, and also ensuring it is aligned properly (i.e. not at an odd memory address).
My guess is that C's simply carried this level of CPU-centric behaviour over, thinking of character constants occupying register sizes of memory, bearing out the common assessment of C as a "high level assembler".
(See 6.3.3 on page 6-25 of http://www.dmv.net/dec/pdf/macro.pdf)