Cosymplectic Geometry, Reductions, and Energy-Momentum Methods with Applications

IF 1.4 4区 物理与天体物理 Q2 MATHEMATICS, APPLIED
J. de Lucas, A. Maskalaniec, B. M. Zawora
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引用次数: 0

Abstract

Classical energy-momentum methods study the existence and stability properties of solutions of t-dependent Hamilton equations on symplectic manifolds whose evolution is given by their Hamiltonian Lie symmetries. The points of such solutions are called relative equilibrium points. This work devises a new cosymplectic energy-momentum method providing a new and more general framework to study t-dependent Hamilton equations. In fact, cosymplectic geometry allows for using more types of distinguished Lie symmetries (given by Hamiltonian, gradient, or evolution vector fields), relative equilibrium points, and reduction methods, than symplectic techniques. To make our work more self-contained and to fill some gaps in the literature, a review of the cosymplectic formalism and the cosymplectic Marsden–Weinstein reduction is included. Known and new types of relative equilibrium points are characterised and studied. Our methods remove technical conditions used in previous energy-momentum methods, like the \(\textrm{Ad}^*\)-equivariance of momentum maps. Eigenfunctions of t-dependent Schrödinger equations are interpreted in terms of relative equilibrium points in cosymplectic manifolds. A new cosymplectic-to-symplectic reduction is developed and a new associated type of relative equilibrium points, the so-called gradient relative equilibrium points, are introduced and applied to study the Lagrange points and Hill spheres of a restricted circular three-body system by means of a not Hamiltonian Lie symmetry of the system.

Abstract Image

折射几何、还原和能动方法及其应用
经典的能量动量法研究交点流形上依赖于 t 的汉密尔顿方程的解的存在性和稳定性。这些解的点被称为相对平衡点。这项工作设计了一种新的折射能量动量法,为研究依赖 t 的汉密尔顿方程提供了一个新的、更通用的框架。事实上,与交映技术相比,余弦几何允许使用更多类型的区分列对称性(由哈密顿、梯度或演化向量场给出)、相对平衡点和还原方法。为了使我们的工作更加自成一体,并填补文献中的一些空白,我们对共折射形式主义和共折射马斯登-韦恩斯坦还原法进行了回顾。对已知的和新型的相对平衡点进行了描述和研究。我们的方法消除了以往能量-动量方法中使用的技术条件,如动量映射的(\textrm{Ad}^*\)-不等式。依赖于 t 的薛定谔方程的特征函数是用余弦流形中的相对平衡点来解释的。通过系统的非哈密顿李对称性,发展了一种新的共折射到共折射还原,引入了一种新的相关相对平衡点类型,即所谓梯度相对平衡点,并将其应用于研究受限圆三体系统的拉格朗日点和希尔球。
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来源期刊
Journal of Nonlinear Mathematical Physics
Journal of Nonlinear Mathematical Physics PHYSICS, MATHEMATICAL-PHYSICS, MATHEMATICAL
CiteScore
1.60
自引率
0.00%
发文量
67
审稿时长
3 months
期刊介绍: Journal of Nonlinear Mathematical Physics (JNMP) publishes research papers on fundamental mathematical and computational methods in mathematical physics in the form of Letters, Articles, and Review Articles. Journal of Nonlinear Mathematical Physics is a mathematical journal devoted to the publication of research papers concerned with the description, solution, and applications of nonlinear problems in physics and mathematics. The main subjects are: -Nonlinear Equations of Mathematical Physics- Quantum Algebras and Integrability- Discrete Integrable Systems and Discrete Geometry- Applications of Lie Group Theory and Lie Algebras- Non-Commutative Geometry- Super Geometry and Super Integrable System- Integrability and Nonintegrability, Painleve Analysis- Inverse Scattering Method- Geometry of Soliton Equations and Applications of Twistor Theory- Classical and Quantum Many Body Problems- Deformation and Geometric Quantization- Instanton, Monopoles and Gauge Theory- Differential Geometry and Mathematical Physics
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