Bergman spaces on disconnected domains
(1996) In Canadian Journal of Mathematics 48(2). p.225-243- Abstract
- For a bounded open set $U$ in the complex plane, we consider the Bergman space $L^p_a(U)$ of $p$th-power area-integrable analytic functions on $U$, with $p$ assumed to be in the range $1\le p<+\infty$, where the lower bound assures that $L^p_a(U)$ is a Banach space. Fix a bounded domain $G$ and a compact subset $K$ of $G$ with zero area measure. Let $M$ be a closed subspace of $L^p_a(G\sbs K)$. We say that $M$ is invariant provided that $zf\in M$ whenever $f\in M$. Aleman, Richter, and Ross study those invariant subspaces $M$ of $L^p_a(G\sbs K)$ that contain $L^p_a(G)$. They also add the requirement that $M$ have index one, which is taken to mean that $(z-\lambda)M$ has codimension $1$ in $M$, for all $\lambda\in G\sbs K$. Natural... (More)
- For a bounded open set $U$ in the complex plane, we consider the Bergman space $L^p_a(U)$ of $p$th-power area-integrable analytic functions on $U$, with $p$ assumed to be in the range $1\le p<+\infty$, where the lower bound assures that $L^p_a(U)$ is a Banach space. Fix a bounded domain $G$ and a compact subset $K$ of $G$ with zero area measure. Let $M$ be a closed subspace of $L^p_a(G\sbs K)$. We say that $M$ is invariant provided that $zf\in M$ whenever $f\in M$. Aleman, Richter, and Ross study those invariant subspaces $M$ of $L^p_a(G\sbs K)$ that contain $L^p_a(G)$. They also add the requirement that $M$ have index one, which is taken to mean that $(z-\lambda)M$ has codimension $1$ in $M$, for all $\lambda\in G\sbs K$. Natural examples of such invariant subspaces are those of the form $M=L^p_a(G\sbs E)$, where $E$ is a closed subset of $K$. The authors show that for $p<2$, these are indeed all such invariant subspaces which can be found. For $p\ge2$, this is not so, but nevertheless a complete classification can be found in terms of quasi-closed subsets $E$ of $K$.
If the condition that the index of $M$ is one is dropped, then the structure of such invariant subspaces can be extremely complicated. If, however, $G\sbs K$ is connected, the authors show that $M$ automatically has index one (due to the assumption that $M$ should contain $L_a^p(G)$). (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/1467233
- author
- Aleman, Alexandru LU ; Richter, Stefan and Ross, William T
- publishing date
- 1996
- type
- Contribution to journal
- publication status
- published
- subject
- in
- Canadian Journal of Mathematics
- volume
- 48
- issue
- 2
- pages
- 225 - 243
- publisher
- Canadian Mathematical Society
- external identifiers
-
- scopus:0030504629
- ISSN
- 0008-414X
- language
- English
- LU publication?
- no
- id
- 8b2528f1-46da-4cb3-b0d9-9eae2db94884 (old id 1467233)
- date added to LUP
- 2016-04-01 16:27:56
- date last changed
- 2022-01-28 19:55:53
@article{8b2528f1-46da-4cb3-b0d9-9eae2db94884, abstract = {{For a bounded open set $U$ in the complex plane, we consider the Bergman space $L^p_a(U)$ of $p$th-power area-integrable analytic functions on $U$, with $p$ assumed to be in the range $1\le p<+\infty$, where the lower bound assures that $L^p_a(U)$ is a Banach space. Fix a bounded domain $G$ and a compact subset $K$ of $G$ with zero area measure. Let $M$ be a closed subspace of $L^p_a(G\sbs K)$. We say that $M$ is invariant provided that $zf\in M$ whenever $f\in M$. Aleman, Richter, and Ross study those invariant subspaces $M$ of $L^p_a(G\sbs K)$ that contain $L^p_a(G)$. They also add the requirement that $M$ have index one, which is taken to mean that $(z-\lambda)M$ has codimension $1$ in $M$, for all $\lambda\in G\sbs K$. Natural examples of such invariant subspaces are those of the form $M=L^p_a(G\sbs E)$, where $E$ is a closed subset of $K$. The authors show that for $p<2$, these are indeed all such invariant subspaces which can be found. For $p\ge2$, this is not so, but nevertheless a complete classification can be found in terms of quasi-closed subsets $E$ of $K$. <br/><br> <br/><br> If the condition that the index of $M$ is one is dropped, then the structure of such invariant subspaces can be extremely complicated. If, however, $G\sbs K$ is connected, the authors show that $M$ automatically has index one (due to the assumption that $M$ should contain $L_a^p(G)$).}}, author = {{Aleman, Alexandru and Richter, Stefan and Ross, William T}}, issn = {{0008-414X}}, language = {{eng}}, number = {{2}}, pages = {{225--243}}, publisher = {{Canadian Mathematical Society}}, series = {{Canadian Journal of Mathematics}}, title = {{Bergman spaces on disconnected domains}}, volume = {{48}}, year = {{1996}}, }