This is the second in a series of papers dedicated to studying w-knots, and
more generally, w-knotted objects (w-braids, w-tangles, etc.). These are
classes of knotted objects that are wider but weaker than their "usual"
counterparts. To get (say) w-knots from usual knots (or u-knots), one has to
allow non-planar "virtual" knot diagrams, hence enlarging the the base set of
knots. But then one imposes a new relation beyond the ordinary collection of
Reidemeister moves, called the "overcrossings commute" relation, making
w-knotted objects a bit weaker once again. Satoh studied several classes of
w-knotted objects (under the name "weakly-virtual") and has shown them to be
closely related to certain classes of knotted surfaces in R4. In this article
we study finite type invariants of w-tangles and w-trivalent graphs (also
referred to as w-tangled foams). Much as the spaces A of chord diagrams for
ordinary knotted objects are related to metrized Lie algebras, the spaces Aw of
"arrow diagrams" for w-knotted objects are related to not-necessarily-metrized
Lie algebras. Many questions concerning w-knotted objects turn out to be
equivalent to questions about Lie algebras. Most notably we find that a
homomorphic universal finite type invariant of w-foams is essentially the same
as a solution of the Kashiwara-Vergne conjecture and much of the
Alekseev-Torossian work on Drinfel'd associators and Kashiwara-Vergne can be
re-interpreted as a study of w-foams.Comment: 57 pages. Improvements to the exposition following a referee repor
