Global Bifurcation In Four-Component Bose-Einstein Condensates In Space

Abstract

We analyze a system of coupled Bose-Einstein condensates in the domain of a unitary ball in R3. The coupling is due to atom-to-atom interactions that occur between different gas components. The multi-component Bose-Einstein condensate is described by a system of Gross-Pitaevskii equations, which has an explicit trivial branch of constant solutions bifurcating from the zero-solution. Our main theorem establishes that this trivial branch undergoes multiple global bifurcations at any critical values with kernels of dimensions at least 3(2k+1), for k ∈ N+. Handling these high dimension kernels poses a challenge from the perspective of bifurcation theory. Our methodology, which relies on the G-equivariant gradient degree, effectively manages these complexities and establishes the existence of at least two global branch in the particular case of k = 0 and at least six branches in the case of k = 1.