Chirality loss during brane merging: a universal power law from the Jackiw-Rebbi index

Abstract

We investigate the rate at which chiral fermion localisation is lost when two domain walls merge in extra-dimensional braneworld scenarios, using the (1+1)-dimensional Jackiw-Rebbi framework as a controlled analytical laboratory. As the inter-brane separation d decreases, left- and right-handed zero modes hybridise and chiral asymmetry is progressively lost. We show that the spatial separation between the chiral zero modes follows a universal power law |Δabs| dγ in the merging limit d 0+, with the critical exponent γ determined solely by the Jackiw-Rebbi topological index NJR, and independent of the fermionic mass gap, the integrability of the scalar sector, and the detailed shape of the domain wall profile. Comparing the integrable sine-Gordon model with four members of the non-integrable double sine-Gordon family, all sharing NJR=1, we find γ∈[0.930,0.985]. For the sine-Gordon model we derive the closed-form overlap integral I(d)=2d/(2d), from which the exact chiral separation follows as a ratio of hyperbolic functions without free parameters. This result identifies γ as the crossover plateau of a local effective exponent γeff(d), explaining the sub-unit value analytically and tracing the universality to the Pöschl-Teller structure of the NJR=1 zero mode. The universality of γ implies that the rate of four-dimensional Yukawa coupling collapse during brane merging is a topological invariant, insensitive to the microscopic scalar dynamics generating the walls.