Lindblad-Deformed Spectral Geometry: Heat-Kernel Asymptotics and Effective Spectral Dimension
Abstract
We introduce a Lindblad-deformed spectral geometric framework in which bounded dissipative data deform a standard spectral triple through the Dirac operator Dgamma = D - igammaSigma, where Sigma = (1/2) sumk Lkdagger Lk is constructed from Lindblad jump operators Lk. The associated positive operator Qgamma = Dgamma* Dgamma = D2 + gamma2 Sigma2 - i*gamma [D, Sigma] is identified as the correct spectral-geometric observable. For smooth endomorphism-valued Lindblad data, Qgamma is of Laplace type and admits a standard heat-kernel asymptotic expansion with dissipation-modified even Seeley-DeWitt coefficients. For the scalar deformation L = sqrt(gamma) f with f in Cinfty(M) real-valued, we prove that the first-order Duhamel correction to the heat trace Kgamma(sigma) = Tr(exp(-sigma Qgamma)) vanishes identically, so that the first nontrivial dissipative effect appears at order gamma4. We identify the exact Duhamel-level decomposition of the O(gamma4) correction into a direct W2 insertion and a quadratic W1 x W1 term. In the round S2 model we determine the explicit deformed operator and extract the leading local asymptotic contribution of the W2 sector. We define the effective scale-dependent spectral dimension ds,eff(sigma,gamma) = -2 d/d(log sigma) log Kgamma(sigma) and identify its leading perturbative deformation.
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