全Kostant-Toda格的Lusztig分解动力学

IF 0.9 3区数学 Q3 MATHEMATICS, APPLIED

Mathematical Physics, Analysis and Geometry Pub Date : 2023-01-17 DOI:10.1007/s11040-022-09444-3

Nicholas M. Ercolani, Jonathan Ramalheira-Tsu

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引用次数: 1

摘要

我们研究了经典Toda格在不同时空尺度上的扩展。这些扩展是从经典的三对角线相空间扩展到满海森伯格矩阵的相空间，称为满Kostant-Toda晶格。我们的公式可以很自然地对Borel-Lie代数的对偶空间作进一步的李论推广。我们的研究引入了由Lusztig引起的规范协调的Loewner-Whitney型因子分解。利用这些坐标，我们给出了在不同时空尺度下动力学适定性的精确条件。在此过程中，我们为完整Kostant-Toda晶格导出了一个新颖的最小盒球系统，它不涉及任何容量或着色，并且根据Robinson-Schensted-Knuth算法具有自然的解释。我们也提供了O 'Connell常微分方程到完全Kostant-Toda格的推广。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Lusztig Factorization Dynamics of the Full Kostant–Toda Lattices

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Lusztig Factorization Dynamics of the Full Kostant–Toda Lattices

We study extensions of the classical Toda lattices at several different space–time scales. These extensions are from the classical tridiagonal phase spaces to the phase space of full Hessenberg matrices, referred to as the Full Kostant–Toda Lattice. Our formulation makes it natural to make further Lie-theoretic generalizations to dual spaces of Borel–Lie algebras. Our study brings into play factorizations of Loewner–Whitney type in terms of canonical coordinatizations due to Lusztig. Using these coordinates we formulate precise conditions for the well-posedness of the dynamics at the different space–time scales. Along the way we derive a novel, minimal box–ball system for the Full Kostant–Toda Lattice that does not involve any capacities or colorings, and which has a natural interpretation in terms of the Robinson–Schensted–Knuth algorithm. We provide as well an extension of O’Connell’s ordinary differential equations to the Full Kostant–Toda Lattice.

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来源期刊

Mathematical Physics, Analysis and Geometry 数学-物理：数学物理

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： MPAG is a peer-reviewed journal organized in sections. Each section is editorially independent and provides a high forum for research articles in the respective areas. The entire editorial board commits itself to combine the requirements of an accurate and fast refereeing process. The section on Probability and Statistical Physics focuses on probabilistic models and spatial stochastic processes arising in statistical physics. Examples include: interacting particle systems, non-equilibrium statistical mechanics, integrable probability, random graphs and percolation, critical phenomena and conformal theories. Applications of probability theory and statistical physics to other areas of mathematics, such as analysis (stochastic pde''s), random geometry, combinatorial aspects are also addressed. The section on Quantum Theory publishes research papers on developments in geometry, probability and analysis that are relevant to quantum theory. Topics that are covered in this section include: classical and algebraic quantum field theories, deformation and geometric quantisation, index theory, Lie algebras and Hopf algebras, non-commutative geometry, spectral theory for quantum systems, disordered quantum systems (Anderson localization, quantum diffusion), many-body quantum physics with applications to condensed matter theory, partial differential equations emerging from quantum theory, quantum lattice systems, topological phases of matter, equilibrium and non-equilibrium quantum statistical mechanics, multiscale analysis, rigorous renormalisation group.