Invariant Subspace

A subspace $U\subseteq V$ is called $\hat{T}$ -invariant if operator $\hat{T}$ keeps everything in U inside U. If it is T-invariant, then this must always be true:

\begin{gather*} \hat{T}(U)=\{\hat{T}\left\lvert \psi \right\rangle|\left\lvert \psi \right\rangle\in U\}\subseteq U \end{gather*}

Simplest T invariant subspace is (with dimensions $d$ )

\begin{gather*} U=span\{\left\lvert u \right\rangle\}\\ \hat{T}\left\lvert y \right\rangle=\lambda \left\lvert u \right\rangle \end{gather*}

When $\lambda$ is Eigenvalue and $\left\lvert u \right\rangle$ is eigenvector and $\left\lvert u \right\rangle\neq 0$ and you can define these Vector by checking

\begin{gather*} (\hat{T}-\lambda I)\left\lvert u \right\rangle=0\\ 0=det(\hat{T}-\lambda I)\\ =(\lambda_1-\lambda)(\lambda_2-\lambda)..(\lambda_d-\lambda) \end{gather*}

In general, this determinant has degree $\lambda_i$ are zeroes of character polynomial $\lambda_i\in C$ can be repeated