Geometric torsions and invariants of manifolds with a triangulated boundary

Abstract: Geometric torsions are torsions of acyclic complexes of vector spaces consisting of differentials of geometric quantities assigned to the elements of a manifold triangulation. We use geometric torsions to construct invariants for a three-dimensional manifold with a triangulated boundary. These invariants can be naturally combined into a vector, and a change of the boundary triangulation corresponds to a linear transformation of this vector. Moreover, when two manifolds are glued at their common boundary, these… Show more

“…In doing so, we are guided by the idea of constructing eventually a topological quantum field theory (TQFT) according to some version of Atiyah's axioms [1] where, as is known, the boundary plays a fundamental role. Some fragments of this theory have been already developed in our works; in particular, it was shown in papers [11] and [12] that, indeed, a TQFT is obtained this way. This TQFT is fermionic: the necessary modification of Atiyah's axioms is that the usual composition of tensor quantities, corresponding to the gluing of manifolds, is replaced with Berezin (fermionic) integral in anticommuting variables.…”

A Euclidean Geometric Invariant of Framed (Un)Knots in Manifolds

“…In doing so, we are guided by the idea of constructing eventually a topological quantum field theory (TQFT) according to some version of Atiyah's axioms [1] where, as is known, the boundary plays a fundamental role. Some fragments of this theory have been already developed in our works; in particular, it was shown in papers [11] and [12] that, indeed, a TQFT is obtained this way. This TQFT is fermionic: the necessary modification of Atiyah's axioms is that the usual composition of tensor quantities, corresponding to the gluing of manifolds, is replaced with Berezin (fermionic) integral in anticommuting variables.…”

A Euclidean Geometric Invariant of Framed (Un)Knots in Manifolds

“…Here, we finish constructing a version of invariants of three-dimensional manifolds with triangulated boundaries begun in [1]. Namely, we present a construction of these invariants for a compact connected three-dimensional manifold with an arbitrary number of boundary components, while we restricted ourself to not more than one component in [1].…”

“…Namely, we present a construction of these invariants for a compact connected three-dimensional manifold with an arbitrary number of boundary components, while we restricted ourself to not more than one component in [1].…”

“…In [1], we demonstrated how to construct not one but many algebraic complexes for a manifold with a one-component boundary with a fixed triangulation given on the boundary. Such a complex depends on two arbitrary sets of boundary edges C and D of equal cardinality; we gave examples showing that such a complex is acyclic in sufficiently many cases (and if it is not acyclic, then its torsion is assumed to be zero).…”

Geometric torsions and an Atiyah-style topological field theory

“…We also note that it is a long way from formula (5) in[5], on which our research on pentagon equations is based, to the TQFT in[6],[7].…”

A matrix solution of the pentagon equation with anticommuting variables