Parabolic fractal dimension of forward-singularities for Navier-Stokes and liquid crystals inequalities

Abstract

In 1985, V. Scheffer discussed partial regularity results for what he called solutions to the "Navier-Stokes inequality". These maps essentially satisfy the incompressibility condition as well as the local and global energy inequalities and the pressure equation which may be derived formally from the Navier-Stokes system of equations, but they are not required to satisfy the Navier-Stokes system itself. One may extend this notion to a system considered by F.-H. Lin and C. Liu in the mid 1990s related to models of the flow of nematic liquid crystals, which include the Navier-Stokes system when the 'director field' d is taken to be zero. In addition to an extended Navier-Stokes system, the Lin-Liu model includes a further parabolic system which implies an a priori maximum principle for d, which is lost when one considers the analogous 'inequality'. In 2018, Q. Liu proved a partial regularity result for certain solutions to the Lin-Liu model in terms of the parabolic fractal dimension dimpf, relying on the boundedness of d coming from the maximum principle. Specifically, Q. Liu proves dimpf(- K) ≤ 9563 for any compact K, where - is the set of 'forward-singular' space-time points, near which the solution blows up forwards in time. For solutions to the corresponding 'inequality', we prove here that, without any compensation for the lack of maximum principle, one has dimpf(- K) ≤ 5513. We also provide a range of criteria, including as just one example the boundedness of d, any one of which would furthermore imply that dimpf(- K) ≤ 9563 for solutions to the inequality, just as Q. Liu proved for solutions to the Lin-Liu system.