Abstract
AbstractThis chapter is entirely devoted to the studies of the lowest non-trivial eigenvalue of operators on graphs. For standard Laplacians on connected graphs the lowest eigenvalue is $$ \lambda _1 = 0 $$
λ
1
=
0
and we shall be interested in $$ \lambda _2$$
λ
2
, which coincides with the spectral gap $$ \lambda _2 - \lambda _1$$
λ
2
−
λ
1
. For Laplacians with Dirichlet vertices it is already non-trivial to calculate the ground state $$ \lambda _1 > 0 $$
λ
1
>
0
. To study these quantities similar methods can be used: Eulerian path and symmetrisation techniques, Cheeger’s approach, surgery principles. Most of these methods work for Schrödinger operators but in order to illuminate connections between spectrum and topology/geometry we shall focus on standard and Dirichlet Laplacians. The methods developed will be extended to higher eigenvalues in the following chapter.
Publisher
Springer Berlin Heidelberg
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