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Categories of Operator Modules (Morita Equivalence and Projective Modules)
 
David P. Blecher University of Houston, Houston, TX
Paul S. Muhly University of Iowa, Iowa City, IA
Vern I. Paulsen University of Houston, Houston, TX
Categories of Operator Modules (Morita Equivalence and Projective Modules)
eBook ISBN:  978-1-4704-0272-3
Product Code:  MEMO/143/681.E
List Price: $51.00
MAA Member Price: $45.90
AMS Member Price: $30.60
Categories of Operator Modules (Morita Equivalence and Projective Modules)
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Categories of Operator Modules (Morita Equivalence and Projective Modules)
David P. Blecher University of Houston, Houston, TX
Paul S. Muhly University of Iowa, Iowa City, IA
Vern I. Paulsen University of Houston, Houston, TX
eBook ISBN:  978-1-4704-0272-3
Product Code:  MEMO/143/681.E
List Price: $51.00
MAA Member Price: $45.90
AMS Member Price: $30.60
  • Book Details
     
     
    Memoirs of the American Mathematical Society
    Volume: 1432000; 94 pp
    MSC: Primary 47; 46; Secondary 16

    Abstract. We employ recent advances in the theory of operator spaces, also known as quantized functional analysis, to provide a context in which one can compare categories of modules over operator algebras that are not necessarily self-adjoint. We focus our attention on the category of Hilbert modules over an operator algebra and on the category of operator modules over an operator algebra. The module operations are assumed to be completely bounded - usually, completely contractive. We develop the notion of a Morita context between two operator algebras \(A\) and \(B\). This is a system \((A,B,{}_{A}X_{B},{}_{B} Y_{A},(\cdot,\cdot),[\cdot,\cdot])\) consisting of the algebras, two bimodules \({}_{A}X_{B}\) and \(_{B}Y_{A}\) and pairings \((\cdot,\cdot)\) and \([\cdot,\cdot]\) that induce (complete) isomorphisms between the (balanced) Haagerup tensor products, \(X \otimes_{hB} {} Y\) and \(Y \otimes_{hA} {} X\), and the algebras, \(A\) and \(B\), respectively. Thus, formally, a Morita context is the same as that which appears in pure ring theory. The subtleties of the theory lie in the interplay between the pure algebra and the operator space geometry. Our analysis leads to viable notions of projective operator modules and dual operator modules. We show that two C\(^*\)-algebras are Morita equivalent in our sense if and only if they are \(C^{\ast}\)-algebraically strong Morita equivalent, and moreover the equivalence bimodules are the same. The distinctive features of the non-self-adjoint theory are illuminated through a number of examples drawn from complex analysis and the theory of incidence algebras over topological partial orders. Finally, an appendix provides links to the literature that developed since this Memoir was accepted for publication.

    Readership

    Graduate students and research mathematicians interested in operator theory.

  • Table of Contents
     
     
    • Chapters
    • 1. Introduction
    • 2. Preliminaries
    • 3. Morita contexts
    • 4. Duals and projective modules
    • 5. Representations of the linking algebra
    • 6. $C$*-algebras and Morita contexts
    • 7. Stable isomorphisms
    • 8. Examples
    • 9. Appendix — More recent developments
  • Requests
     
     
    Review Copy – for publishers of book reviews
    Permission – for use of book, eBook, or Journal content
    Accessibility – to request an alternate format of an AMS title
Volume: 1432000; 94 pp
MSC: Primary 47; 46; Secondary 16

Abstract. We employ recent advances in the theory of operator spaces, also known as quantized functional analysis, to provide a context in which one can compare categories of modules over operator algebras that are not necessarily self-adjoint. We focus our attention on the category of Hilbert modules over an operator algebra and on the category of operator modules over an operator algebra. The module operations are assumed to be completely bounded - usually, completely contractive. We develop the notion of a Morita context between two operator algebras \(A\) and \(B\). This is a system \((A,B,{}_{A}X_{B},{}_{B} Y_{A},(\cdot,\cdot),[\cdot,\cdot])\) consisting of the algebras, two bimodules \({}_{A}X_{B}\) and \(_{B}Y_{A}\) and pairings \((\cdot,\cdot)\) and \([\cdot,\cdot]\) that induce (complete) isomorphisms between the (balanced) Haagerup tensor products, \(X \otimes_{hB} {} Y\) and \(Y \otimes_{hA} {} X\), and the algebras, \(A\) and \(B\), respectively. Thus, formally, a Morita context is the same as that which appears in pure ring theory. The subtleties of the theory lie in the interplay between the pure algebra and the operator space geometry. Our analysis leads to viable notions of projective operator modules and dual operator modules. We show that two C\(^*\)-algebras are Morita equivalent in our sense if and only if they are \(C^{\ast}\)-algebraically strong Morita equivalent, and moreover the equivalence bimodules are the same. The distinctive features of the non-self-adjoint theory are illuminated through a number of examples drawn from complex analysis and the theory of incidence algebras over topological partial orders. Finally, an appendix provides links to the literature that developed since this Memoir was accepted for publication.

Readership

Graduate students and research mathematicians interested in operator theory.

  • Chapters
  • 1. Introduction
  • 2. Preliminaries
  • 3. Morita contexts
  • 4. Duals and projective modules
  • 5. Representations of the linking algebra
  • 6. $C$*-algebras and Morita contexts
  • 7. Stable isomorphisms
  • 8. Examples
  • 9. Appendix — More recent developments
Review Copy – for publishers of book reviews
Permission – for use of book, eBook, or Journal content
Accessibility – to request an alternate format of an AMS title
Please select which format for which you are requesting permissions.