Abstract
In this paper, we consider the contracting curvature flows of smooth closed surfaces in 3-dimensional hyperbolic space and in 3-dimensional sphere. In the hyperbolic case, we show that if the initial surface \(M_0\) has positive scalar curvature, then along the flow by a positive power \(\alpha \) of the mean curvature H, the evolving surface \(M_t\) has positive scalar curvature for \(t>0\). By assuming \(\alpha \in [1,4]\), we can further prove that \(M_t\) contracts a point in finite time and become spherical as the final time is approached. We also show the same conclusion for the flows by powers of scalar curvature and by powers of Gauss curvature provided that the power \(\alpha \in [1/2,1]\). In the sphere case, we show that the flow by a positive power \(\alpha \) of mean curvature contracts strictly convex surface in \(\mathbb {S}^3\) to a round point in finite time if \(\alpha \in [1,5]\). The same conclusion also holds for the flow by powers of Gauss curvature provided that the power \(\alpha \in [1/2,1]\).
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Acknowledgements
The authors would like to thank Professor Ben Andrews for suggestions on the curvature pinching in the hyperbolic case. The first author was supported by China Postdoctoral Science Foundation (No. 2018M641317). The second author was supported by NSFC Grant Nos. 11671224, 11831005 and NSFC-FWO Grant No. 1196131001. The third author was supported by Discovery Early Career Researcher Award DE190100147 of the Australian Research Council.
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Communicated by J. Jost.
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