<p>For the prescribed scalar curvature equation on <InlineEquation ID="IEq3"> <EquationSource Format="TEX">\(\,S^{\,n}\,\)</EquationSource> <EquationSource Format="MATHML"><math> <mrow> <mspace width="0.166667em" /> <msup> <mi>S</mi> <mrow> <mspace width="0.166667em" /> <mi>n</mi> </mrow> </msup> <mspace width="0.166667em" /> </mrow> </math></EquationSource> </InlineEquation> (<InlineEquation ID="IEq4"> <EquationSource Format="TEX">\(\,n\,\ge \ 6\,\)</EquationSource> <EquationSource Format="MATHML"><math> <mrow> <mspace width="0.166667em" /> <mi>n</mi> <mspace width="0.166667em" /> <mo>≥</mo> <mspace width="4pt" /> <mn>6</mn> <mspace width="0.166667em" /> </mrow> </math></EquationSource> </InlineEquation>)&#xa0;,&#xa0; we consider the situation where the number of bubbles tends to infinity in the Lyapunov&#xa0;-&#xa0;Schmidt (&#xa0;finite dimension&#xa0;) reduction method&#xa0;.&#xa0; In an outstanding paper by Wei and Yan [<CitationRef CitationID="CR35">35</CitationRef>]&#xa0;,&#xa0; the special case where the bubbles are arranged “&#xa0;evenly&#xa0;"&#xa0; (&#xa0;close to a great circle&#xa0;) is considered&#xa0;.&#xa0; Here we are concerned with the generic scenario, where the bubbles are “&#xa0;planted&#xa0;" (&#xa0;arranged&#xa0;) in general position&#xa0;,&#xa0; in adjacent to the critical points of the prescribed function&#xa0;.&#xa0; The main interest of this article is to extract key information in the finite dimensional reduced functional, as well as in its first partial derivatives&#xa0;.&#xa0; Overall&#xa0;,&#xa0; there are two main contributions in the &#xa0;“expansions&#xa0;"&#xa0;,&#xa0; namely, interaction between bubbles and curvature involvement. As each bubble becomes infinitesimally close to other bubbles in the neighborhood, the errors in the expansions are carefully estimated in terms of the geometric parameters. This lays the foundation for our next step on constructing blow&#xa0;-&#xa0;up sequences of solutions with dense blow&#xa0;-&#xa0;up points (clustered blow&#xa0;-&#xa0;up)&#xa0;,&#xa0; where the (&#xa0;non&#xa0;-&#xa0;radial&#xa0;-&#xa0;symmetric&#xa0;) prescribed scalar curvature function has non&#xa0;-&#xa0;isolated critical points.</p>

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Construction of blow - up sequences for the prescribed scalar curvature equation on \(S^n\). IV. clustered blow - ups

  • Man Chun L Leung

摘要

For the prescribed scalar curvature equation on \(\,S^{\,n}\,\) S n ( \(\,n\,\ge \ 6\,\) n 6 ) ,  we consider the situation where the number of bubbles tends to infinity in the Lyapunov - Schmidt ( finite dimension ) reduction method .  In an outstanding paper by Wei and Yan [35] ,  the special case where the bubbles are arranged “ evenly "  ( close to a great circle ) is considered .  Here we are concerned with the generic scenario, where the bubbles are “ planted " ( arranged ) in general position ,  in adjacent to the critical points of the prescribed function .  The main interest of this article is to extract key information in the finite dimensional reduced functional, as well as in its first partial derivatives .  Overall ,  there are two main contributions in the  “expansions " ,  namely, interaction between bubbles and curvature involvement. As each bubble becomes infinitesimally close to other bubbles in the neighborhood, the errors in the expansions are carefully estimated in terms of the geometric parameters. This lays the foundation for our next step on constructing blow - up sequences of solutions with dense blow - up points (clustered blow - up) ,  where the ( non - radial - symmetric ) prescribed scalar curvature function has non - isolated critical points.