Weyl's theorem for class \(A\) operators (Q2711486)

Let \({\mathcal B}({\mathcal H})\) be the set of all bounded linear operators on a Hilbert space \({\mathcal H}\) and \({\mathcal K}({\mathcal H})\) be the set of all compact operators in \({\mathcal B}({\mathcal H}).\) According to Coburn Weyl's theorem holds for \(T\in {\mathcal B}({\mathcal H})\) if \(\sigma (T) \setminus w(T)=\pi _{00}(T)\) where \(\sigma (T)\) denotes the spectrum of \(T,\) \(w(T)=\cap _{K\in {\mathcal K}({\mathcal H})}\sigma (T+K),\) \(\pi _{00}(T)\) denotes the set of all isolated eigenvalues of finite multiplicity of \(T.\) By definition an operator \(T(\in {\mathcal B}({\mathcal H}))\) belongs to the class \({\mathcal A}\) if \(\|T^2\|\geq \|T\|^2.\) The aim of the paper is to show that NEWLINENEWLINENEWLINE1) Weyl's theorem holds for class \({\mathcal A}\) operators under a certain condition, NEWLINENEWLINENEWLINE2) a class \({\mathcal A}\) with \(w(T)=\{0\}\) is always compact and normal.