The Arf-Brown TQFT of pin⁻ surfaces

Abstract: The Arf-Brown invariant AB(Σ) is an 8th root of unity associated to a surface Σ equipped with a Pin − structure. In this note we investigate a certain fully extended, invertible, topological quantum field theory (TQFT) whose partition function is the Arf-Brown invariant. Our motivation comes from the recent work of Freed-Hopkins on the classification of topological phases, of which the Arf-Brown TQFT provides a nice example of the general theory; physically, it can be thought of as the low energy effective the… Show more

“…That is, we want to find an enhancement of a given TQFT functor Bord Spin n (BG) → Vect Z 2 C to a functor Z : Bord Spin,∂ n (BG) → Vect Z 2 C , where Bord Spin,∂ n is the bordism category whose objects can have boundaries and morphisms can have corners. 32 Further, since the fSPT is trivial when its background is ignored (i.e. maps to BG are trivial), physically we expect that we can obtain the boundary TQFT Z ∂ : Bord Spin n−1 → Vect Z 2 C from the bulk-boundary TQFT Z.…”

“…where C[n] denotes a one-dimensional complex vector space with Z 2 grading n, and Z Arf is the nontrivial (fully extendable) invertible 2d spin-TQFT such that its value on a closed spin-surface Σ is Z Arf (Σ) = (−1) Arf(Σ) . Such TQFT was considered in detail in [32] (see also [33]). The value of SL 4 on morphisms (using the conventions in (5.23)) is Then the functor SL 4 categorifies link invariant SL 3 in the sense that…”

“…C is the functor representing the pin − fSPT defined by the ABK invariant. Such (fully extended) 2d TQFT was considered in detail in [32]. The functor Z evaluated on a morphism (M 3 , g) ∈ Hom Bord Spin,∂ 3 ((M 2 1 , g), (M 2 2 , g)) is similarly constructed as:…”

Fermionic Finite-Group Gauge Theories and Interacting Symmetric/Crystalline Orders via Cobordisms

“…That is, we want to find an enhancement of a given TQFT functor Bord Spin n (BG) → Vect Z 2 C to a functor Z : Bord Spin,∂ n (BG) → Vect Z 2 C , where Bord Spin,∂ n is the bordism category whose objects can have boundaries and morphisms can have corners. 32 Further, since the fSPT is trivial when its background is ignored (i.e. maps to BG are trivial), physically we expect that we can obtain the boundary TQFT Z ∂ : Bord Spin n−1 → Vect Z 2 C from the bulk-boundary TQFT Z.…”

“…where C[n] denotes a one-dimensional complex vector space with Z 2 grading n, and Z Arf is the nontrivial (fully extendable) invertible 2d spin-TQFT such that its value on a closed spin-surface Σ is Z Arf (Σ) = (−1) Arf(Σ) . Such TQFT was considered in detail in [32] (see also [33]). The value of SL 4 on morphisms (using the conventions in (5.23)) is Then the functor SL 4 categorifies link invariant SL 3 in the sense that…”

“…C is the functor representing the pin − fSPT defined by the ABK invariant. Such (fully extended) 2d TQFT was considered in detail in [32]. The functor Z evaluated on a morphism (M 3 , g) ∈ Hom Bord Spin,∂ 3 ((M 2 1 , g), (M 2 2 , g)) is similarly constructed as:…”

Fermionic Finite-Group Gauge Theories and Interacting Symmetric/Crystalline Orders via Cobordisms

“…In this section, we construct the 2d pin − invertible TQFT [23] for the Arf-Brown-Kervaire (ABK) invariant via the Grassmann integral on lattice, whose state sum definition was initially given in [15]. In condensed matter literature, this invertible theory describes (1+1)d topological superconductors in class BDI [16].…”

“…We further show that pin ± Gu-Wen SPT phases always admit a gapped boundary, by explicitly constructing the Grassmann integral for the coupled bulk and boundary system on an unoriented manifold. In addition, we propose a lattice definition of 2d pin − TQFT whose partition function is the Arf-Brown-Kervaire (ABK) invariant [15,22,23], which generates the Z 8 classification of (1+1)d topological superconductors. Finally, we discuss a way to compute the Z 16 -valued (2+1)d pin + anomaly from the data of (2+1)d anomalous theory.…”

Pin TQFT and Grassmann integral

Diagrammatic state sums for 2D pin-minus TQFTs