First lets reconsider what actually indroduces such things as "directions" as vector space. Vectors can be anyting, numbers, directions, chairs, colours, tables, you name it. As long as you can define an vector space of linear independent base vectors, it is a vector space.
So we arbitrarily introduce some base vectors, call them
"out" (you may also use arrows, or little whatever), also say that "right" and "up" correspond to columns and rows of out later screen and "out" being the depth buffer value. This gives us a screen space vector space. We now introduce a number of transformations, which transform from something we call "local space" into "eye space" and from "eye space" into "clip space". We also say those transformations are to be isomorphisms. Thus all those spaces are structurally equivalent.
You remember the base vectors? We now define that something like
(a, b, c) is in fact a shortcut for writing
a "right" + b "up" + c "out". Now keep in mind that something is then part of a vector space if it can be expressed by a linear combination of its base vectors. If you multiply those base vectors with 0 they vanish. So a null vector is not part of any particular vector space whatsoever, but can be expressed in terms of any vector space. It's also said to be singular. Or in other words, if you test a vector if it can not be expressed as part of a particular vector space, a null vector will fit in any vector space.
In the case of the vector space of directions we introduced this means, that for a null vector no direction in particular is defined, but if added to another direction it will not alter it.
You may ask "how the %$@§ does a zero position vector work then?". Well, remember that we can still use null vectors as offsets. We define an arbitrary element as our origin, and add to it.
Also we must differ between 0 (i.e. the multiplicative vanishing) and the digit "0", which may match in a evaluation to 0, but if part of the bitvector representing a number is not vanishing!