Quantitative blow-up suppression for the Patlak-Keller-Segel(-Navier-Stokes) system via Couette flow on R2
Abstract
It is well known that solutions to the Patlak--Keller--Segel system on R2 blow up in finite time if the initial mass exceeds 8π. In this paper, we investigate the mixing effect induced by a Couette flow (Ay, 0) with a quantitatively determined amplitude A, which suppresses bacterial aggregation. For the Patlak--Keller--Segel system advected by such a flow on R2, we prove that the solutions remain global in time even for large initial mass, provided the amplitude A is sufficiently large. Specifically, global well-posedness holds if A satisfies a lower bound of the form C* (\| Dxm Dx-1ε nin \|L22+1)9/2. A notable feature of our result is the explicit estimate of the sufficient constant, given by C* = 2,058,614. Furthermore, for the coupled Patlak--Keller--Segel--Navier--Stokes system near the Couette flow, we establish an analogous global existence result, provided the amplitude is sufficiently large in form of C*\|(n in, |Dx|1/3 n in,ω in)\|Ym,ε9.
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