Spacetime Duality Beyond Conformality
Abstract
We extend the spacetime duality programme of Burgess et.al. to massive theories in 1+1 dimensions. For the massive scalar, a heat-kernel computation tracking three contributions to the conformal-mode effective action reveals that the naive leading correction m2(eϕ -1) to the Liouville action cancels exactly, with the genuine leading deformation being -m216π(eϕ-1)2. This breaks self-duality and renders the dual theory for the Lagrange multiplier field Λ non-local. For the massive Dirac fermion, two independent derivations establish that the fermion mass dresses under conformal scaling as m m\, eϕ/2, reflecting the Weyl weight 12 of the two-dimensional spinor. Via the Coleman-Mandelstam bosonisation, this transfers to the mass bilinear as μ(β) μeϕ/2(β), producing a coupled Liouville-sine-Gordon system as the natural starting point for the fermionic construction. Both results are interpreted in terms of the determinant line bundle over Met(Σ)/Diff(Σ).
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