# 7: Eigenvalues and Eigenvectors

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In this chapter we study linear operators \(T : V \to V\) on a finite-dimensional vector space \(V\). We are interested in understanding when there is a basis \(B\) for \(V\) such that the matrix \(M(T)\) of \(T\) with respect to \(B\) has a particularly nice form. In particular, we would like \(M(T)\) to be either upper triangular or diagonal. This quest leads us to the notions of eigenvalues and eigenvectors of a linear operator, which is one of the most important concepts in Linear Algebra and beyond. For example, quantum mechanics is largely based upon the study of eigenvalues and eigenvectors of operators on finite- and infinite-dimensional vector spaces.

### Contributors

- Isaiah Lankham, Mathematics Department at UC Davis
- Bruno Nachtergaele, Mathematics Department at UC Davis
- Anne Schilling, Mathematics Department at UC Davis

Both hardbound and softbound versions of this textbook are available online at WorldScientific.com.