Sokolov V.V. Algebraic quantum Hamiltonians on the plane, talk at The Mini-Workshop on Integrable Equations, 17 February 2015, Independent University of Moscow (abstract): Difference between revisions
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| speaker = Vladimir Sokolov | | speaker = Vladimir Sokolov | ||
| title = Algebraic quantum Hamiltonians on the plane | | title = Algebraic quantum Hamiltonians on the plane | ||
| abstract = In is known that many of quantum Calogero-Moser type Hamiltonians admit a change of variables bringing them to differential operators <math>P</math> of second order with polynomial coefficients. | | abstract = In is known that many of quantum Calogero-Moser type Hamiltonians admit a change of variables bringing them to differential operators <math alt="P">P</math> of second order with polynomial coefficients. | ||
It turns out that in all known examples: | It turns out that in all known examples: | ||
<math>\mathbf{1}</math> : <math>P</math> preserves some finite-dimensional polynomial vector space <math>V</math>. | <math alt="1">\mathbf{1}</math> : <math alt="P">P</math> preserves some finite-dimensional polynomial vector space <math alt="V">V</math>. | ||
The set of all differential operators with polynomial coefficients that preserve a fixed finite-dimensional polynomial vector space <math>V</math> forms an associative algebra <math>A</math>. In the most interesting case the vector space <math>V</math> coincides with the space of all polynomials of degrees <math>\le k</math> for some <math>k</math>. For such <math>V</math> the algebra <math>A</math> is the universal enveloping algebra <math>\operatorname{sl}(n+1)</math>, where <math>n</math> is the number of independent variables. | The set of all differential operators with polynomial coefficients that preserve a fixed finite-dimensional polynomial vector space <math alt="V">V</math> forms an associative algebra <math alt="A">A</math>. In the most interesting case the vector space <math alt="V">V</math> coincides with the space of all polynomials of degrees <math alt="<=">\le k</math> for some <math alt="k">k</math>. For such <math alt="V">V</math> the algebra <math alt="A">A</math> is the universal enveloping algebra <math alt="sl(n+1)">\operatorname{sl}(n+1)</math>, where <math alt="n">n</math> is the number of independent variables. | ||
It is clear that if a differential operator satisfies Property <math>\mathbf{1}</math>, we can find several eigenvalues and corresponding polynomial eigenvectors in an explicit algebraic form. | It is clear that if a differential operator satisfies Property <math alt="">\mathbf{1}</math>, we can find several eigenvalues and corresponding polynomial eigenvectors in an explicit algebraic form. | ||
For the elliptic Calogero type models the flat metric <math>g</math> related to the symbol of <math>P</math> depends on the elliptic parameter. One of the reasons why such a metric could be interesting in itself is that families of contravariant metrics with linear dependence on a parameter are closely related to the Frobenius manifolds. | For the elliptic Calogero type models the flat metric <math alt="">g</math> related to the symbol of <math alt="">P</math> depends on the elliptic parameter. One of the reasons why such a metric could be interesting in itself is that families of contravariant metrics with linear dependence on a parameter are closely related to the Frobenius manifolds. | ||
| slides = | | slides = | ||
| references = | | references = | ||
| 79YY-MM-DD = 7984-97-84 | | 79YY-MM-DD = 7984-97-84 | ||
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Revision as of 17:46, 23 January 2015
Speaker: Vladimir Sokolov
Title: Algebraic quantum Hamiltonians on the plane
Abstract:
In is known that many of quantum Calogero-Moser type Hamiltonians admit a change of variables bringing them to differential operators of second order with polynomial coefficients.
It turns out that in all known examples:
: preserves some finite-dimensional polynomial vector space .
The set of all differential operators with polynomial coefficients that preserve a fixed finite-dimensional polynomial vector space forms an associative algebra . In the most interesting case the vector space coincides with the space of all polynomials of degrees for some . For such the algebra is the universal enveloping algebra , where is the number of independent variables.
It is clear that if a differential operator satisfies Property , we can find several eigenvalues and corresponding polynomial eigenvectors in an explicit algebraic form.
For the elliptic Calogero type models the flat metric related to the symbol of depends on the elliptic parameter. One of the reasons why such a metric could be interesting in itself is that families of contravariant metrics with linear dependence on a parameter are closely related to the Frobenius manifolds.
