Litcius/Paper detail

Scalar curvature and harmonic maps to $S^1$

Daniel Stern

2022Journal of Differential Geometry33 citationsDOI

Abstract

For a harmonic map $u : M^3 \to S^1$ on a closed, oriented $3$-manifold, we establish the identity \[ 2 \pi \int_{\theta \in S^1} \chi (\Sigma _\theta) \geq \frac{1}{2} \int_{\theta \in S^1} \int_{\Sigma_\theta} \left( {\lvert du \rvert}^{-2} {\lvert \mathit{Hess} (u) \rvert}^2 + R_M \right) \] relating the scalar curvature $R_M$ of $M$ to the average Euler characteristic of the level sets $\Sigma_\theta = u^{-1} {\lbrace \theta \rbrace}$. As our primary application, we extend the Kronheimer–Mrowka characterization of the Thurston norm on $H_2 (M; \mathbb{Z})$ in terms of ${\lVert R^{-}_M \rVert}_{L^2}$ and the harmonic norm to any closed $3$-manifold containing no nonseparating spheres. Additional corollaries include the Bray–Brendle–Neves rigidity theorem for the systolic inequality $(\min R_M) \mathit{sys}_2 (M) \leq 8\pi$, and the well-known result of Schoen and Yau that $T^3$ admits no metric of positive scalar curvature.

Topics & Concepts

MathematicsScalar curvatureScalar (mathematics)CurvatureManifold (fluid mechanics)Harmonic mapNorm (philosophy)Mathematical physicsSubsequenceCombinatoricsRicci curvaturePure mathematicsMathematical analysisGeometryBounded functionEngineeringPolitical scienceLawMechanical engineeringGeometric and Algebraic TopologyGeometric Analysis and Curvature FlowsGeometry and complex manifolds