Inverse Mobius Spacetime in 1+1D Quantum Gravity: Functional Analytic Structures, Dirac Spectrum, and Pin Geometry

Abstract

In this manuscript, we formulate a (1+1)-dimensional Jackiw-Teitelboim gravity toy model whose Euclidean spacetime manifold is the M\"obius band M. Since M is non-orientable, the relevant spin-statistics structure is Pin rather than Spin. To emphasize the role of orientation reversal, we refer to the universal orientable cover M as the inverse M\"obius band, which resolves the M\"obius twist into an infinite ribbon equipped with a Z deck action. We compute the Stiefel-Whitney classes w1, w2, classify all Pin structures, construct the associated pinor bundles, and analyze the Dirac operator under the twisted equivariance condition \[ (x+1, w) = γw (x, -w). \] Half-integer momentum quantization, spectral symmetry, vanishing mod-2 index, and ηD(0) = 0 follow. In JT gravity, the two inequivalent Pin lifts in each parity double the non-perturbative saddle-point sum, yet leave the leading Bekenstein-Hawking entropy unchanged. Full proofs and heat-kernel calculations are provided for completeness.