A covariant signature change from Euclidean to Lorentzian geometry on a curvature-regular hypersurface generates inflation via an effective geometric stress tensor, with duration set by the interpolator slope relative to extrinsic and spatial curvatures.
Euclidean Action and the Einstein tensor
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abstract
I give a local description of the Euclidean regime $(M, g_{ab}, u^a)$ of Lorentzian spacetimes $(M, g_{ab})$ based on timelike geodesics $u^a$ passing through an arbitrary event $p_0 \in M$. I show that, to leading order, the Euclidean Einstein-Hilbert action $I_E$ is proportional to the Einstein tensor $G_{ab}u^a u^b$ of $g_{ab}$. The positivity of $I_E$ follows if $G_{ab}u^a u^b>0$ holds. I suggest an interpretation of this result in terms of the amplitude $\mathcal{A}[\Sigma_0]=\exp[{-I_E}]$ for a single space-like hypersurface $\Sigma_0 \in I^{+}(p_0)$ to emerge at a constant geodesic distance $\lambda_0$ from $p_0$. Implications for classical and quantum gravity are discussed.
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gr-qc 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Inflation from Covariant Signature Change: A Geometric Mechanism
A covariant signature change from Euclidean to Lorentzian geometry on a curvature-regular hypersurface generates inflation via an effective geometric stress tensor, with duration set by the interpolator slope relative to extrinsic and spatial curvatures.