eBook ISBN: | 978-1-4704-0393-5 |
Product Code: | MEMO/167/795.E |
List Price: | $68.00 |
MAA Member Price: | $61.20 |
AMS Member Price: | $40.80 |
eBook ISBN: | 978-1-4704-0393-5 |
Product Code: | MEMO/167/795.E |
List Price: | $68.00 |
MAA Member Price: | $61.20 |
AMS Member Price: | $40.80 |
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Book DetailsMemoirs of the American Mathematical SocietyVolume: 167; 2004; 142 ppMSC: Primary 14; Secondary 18
The use of geometric invariants has recently played an important role in the solution of classification problems in non-commutative ring theory. We construct geometric invariants of non-commutative projectivizataions, a significant class of examples in non-commutative algebraic geometry. More precisely, if \(S\) is an affine, noetherian scheme, \(X\) is a separated, noetherian \(S\)-scheme, \(\mathcal{E}\) is a coherent \({\mathcal{O}}_{X}\)-bimodule and \(\mathcal{I} \subset T(\mathcal{E})\) is a graded ideal then we develop a compatibility theory on adjoint squares in order to construct the functor \(\Gamma_{n}\) of flat families of truncated \(T(\mathcal{E})/\mathcal{I}\)-point modules of length \(n+1\). For \(n \geq 1\) we represent \(\Gamma_{n}\) as a closed subscheme of \({\mathbb{P}}_{X^{2}}({\mathcal{E}}^{\otimes n})\). The representing scheme is defined in terms of both \({\mathcal{I}}_{n}\) and the bimodule Segre embedding, which we construct.
Truncating a truncated family of point modules of length \(i+1\) by taking its first \(i\) components defines a morphism \(\Gamma_{i} \rightarrow \Gamma_{i-1}\) which makes the set \(\{\Gamma_{n}\}\) an inverse system. In order for the point modules of \(T(\mathcal{E})/\mathcal{I}\) to be parameterizable by a scheme, this system must be eventually constant. In [20], we give sufficient conditions for this system to be constant and show that these conditions are satisfied when \({\mathsf{Proj}} T(\mathcal{E})/\mathcal{I}\) is a quantum ruled surface. In this case, we show the point modules over \(T(\mathcal{E})/\mathcal{I}\) are parameterized by the closed points of \({\mathbb{P}}_{X^{2}}(\mathcal{E})\).
ReadershipGraduate students and research mathematicians interested in algebraic geometry.
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Table of Contents
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Chapters
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1. Introduction
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2. Compatibilities on squares
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3. Construction of the functor $\Gamma _n$
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4. Compatibility with descent
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5. The representation of $\Gamma _n$ for low $n$
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6. The bimodule Segre embedding
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7. The representation of $\Gamma _n$ for high $n$
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The use of geometric invariants has recently played an important role in the solution of classification problems in non-commutative ring theory. We construct geometric invariants of non-commutative projectivizataions, a significant class of examples in non-commutative algebraic geometry. More precisely, if \(S\) is an affine, noetherian scheme, \(X\) is a separated, noetherian \(S\)-scheme, \(\mathcal{E}\) is a coherent \({\mathcal{O}}_{X}\)-bimodule and \(\mathcal{I} \subset T(\mathcal{E})\) is a graded ideal then we develop a compatibility theory on adjoint squares in order to construct the functor \(\Gamma_{n}\) of flat families of truncated \(T(\mathcal{E})/\mathcal{I}\)-point modules of length \(n+1\). For \(n \geq 1\) we represent \(\Gamma_{n}\) as a closed subscheme of \({\mathbb{P}}_{X^{2}}({\mathcal{E}}^{\otimes n})\). The representing scheme is defined in terms of both \({\mathcal{I}}_{n}\) and the bimodule Segre embedding, which we construct.
Truncating a truncated family of point modules of length \(i+1\) by taking its first \(i\) components defines a morphism \(\Gamma_{i} \rightarrow \Gamma_{i-1}\) which makes the set \(\{\Gamma_{n}\}\) an inverse system. In order for the point modules of \(T(\mathcal{E})/\mathcal{I}\) to be parameterizable by a scheme, this system must be eventually constant. In [20], we give sufficient conditions for this system to be constant and show that these conditions are satisfied when \({\mathsf{Proj}} T(\mathcal{E})/\mathcal{I}\) is a quantum ruled surface. In this case, we show the point modules over \(T(\mathcal{E})/\mathcal{I}\) are parameterized by the closed points of \({\mathbb{P}}_{X^{2}}(\mathcal{E})\).
Graduate students and research mathematicians interested in algebraic geometry.
-
Chapters
-
1. Introduction
-
2. Compatibilities on squares
-
3. Construction of the functor $\Gamma _n$
-
4. Compatibility with descent
-
5. The representation of $\Gamma _n$ for low $n$
-
6. The bimodule Segre embedding
-
7. The representation of $\Gamma _n$ for high $n$