I don't know whether it's UB
It is undefined, as specified in C++11 5/4:
If during the evaluation of an expression, the result is not mathematically defined or not in the range of representable values for its type, the behavior is undefined.
(As you say, it is defined for unsigned types, since they are defined by 3.9.1/4 to obey modular arithmetic)
on a modern architecture, will I actually see arithmetic overflow of bits in memory?
On all the modern architectures I know of (x86, ARM, 68000, and various DSPs), arithmetic is modular, with fixed-width 2s-complement results; on those architectures that can write the result to memory rather than registers, it will never overwrite more memory than the result size. For addition and subtraction, there is no difference to the CPU between signed and unsigned arithmetic. Overflow (signed or unsigned) can be detected from the state of CPU flags after the operation.
I could imagine a compiler for, say, a 32-bit DSP that tried to implement arithmetic on 8 or 16-bit values packed into a larger word, where overflow would affect the rest of the word; however, all compilers I've seen for such architectures just defined
int to be 32-bit types.
Or is that really more of a historical thing?
It would have happened on Babbage's Difference Engine, since "memory" is a single number; if you partition it into smaller numbers, and don't insert guard digits, then overflow from one will alter the value of the next. However, you couldn't run any non-trivial C++ program on this architecture.
Historically, I believe some processors would produce an exception on overflow - that would be why the behaviour is undefined.