Mini-workshop: Nonlinear spectral and eigenvalue theory with applications to the \(p\)-Laplace operator (Q1779195)

These are brief contributions on a mini/workshop which will not be reviewed individually. Editors' abstract: What is the state-of-the-art of abstract spectral and eigenvalue theory for nonlinear operators, and how may this theory be applied to nonlinear equations involving the \(p\)-Laplace operator? These two questions have provided the main focus of the Mini-Workshop. Accordingly, the main topics covered by the talks on this Mini-Workshop have been -- spectra for nonlinear operators, -- nonlinear eigenvalue problems, and -- equations involving the \(p\)-Laplace operator. Of course, these three topics are not mutually independent, but there are various interconnections between them which are of particular interest. For example, sets of eigenvalues (point spectra) may be regarded, as in the linear case, as an important part of the spectrum; conversely, nonlinear eigenvalue theory is one of the historical roots of nonlinear spectral theory. Moreover, the \(p\)-Laplace operator is one of the most interesting homogeneous (though nonlinear) operators which may not only serve as a ``model operator'' in nonlinear eigenvalue problems, but also occurs quite frequently in various applications to physics, mechanics, and elasticity. The aim and scope of the Mini-Workshop was to bring together experts on nonlinear spectral analysis and operator theory, on the one hand, and more application-oriented specialists in eigenvalue problems for nonlinear partial differential equations (like the \(p\)-Laplace equation), on the other. As a result, 15 leading experts in the field from 10 different countries discussed recent progress and open problems in the theory, methods, and applications of spectra and eigenvalues of nonlinear operators. Contributions: -- M. Cuesta (Calais) (joint with M. Arias (Granada), J.-P. Gossez (Bruxelles)), Asymmetric Eigenvalue Problems with Weights for the \(p\)-Laplacian with Neumann Boundary Conditions, p.411 -- J.-P. Gossez (Bruxelles), Antimaximum principle and Fučik spectrum, p.413 -- P. Drábek (Rostock), P. Girg (Plzeň), P. Takáč (Rostock), The Fredholm alternative for the \(p\)-Laplacian: bifurcation from infinity, existence and multiplicity p.414 -- Raffaele Chiappinelli (Siena, Italy), Perturbation of the simple eigenvalue by 1-homogeneous operators p.422 -- Vesa Mustonen (Oulu), Remarks on some inhomogeneus eigenvalue problems. p.424 -- C. A. Stuart (Lausanne), Applications of the degree for Fredholm maps to elliptic problems. p.425 -- Massimo Furi (Florence, Italy), On the sign-jump of one-parameter families of Fredholm operators and bifurcation. p.425 -- Wenying Feng (Peterborough, Canada), Applications of nonlinear and semilinear spectral theory to boundary value problems. p.427 -- Martin Väth, Epi and Coepi Maps, and Further? p.428 -- Elena Giorgieri (Rome), Spectral theory for homogeneous operators. I. p.429 -- Jürgen Appell (Würzburg), Spectral theory for homogeneous operators. II. Applications. p.431 -- Jürgen Appell (Würzburg), Numerical Ranges for Nonlinear Operators: A Survey p.434.