重力度规-仿射(爱因斯坦-帕拉蒂尼)作用的新多辛方法

IF 1 4区数学 Q3 MATHEMATICS, APPLIED

Journal of Geometric Mechanics Pub Date : 2018-04-17 DOI:10.3934/jgm.2019019

Jordi Gaset Rifà, N. Rom'an-Roy

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引用次数: 18

摘要

我们提出了广义相对论爱因斯坦-帕拉蒂尼(或度量-仿射)模型(不含能量-物质源)的协变多辛公式。由于它是由一阶仿射拉格朗日(在场的导数中)描述的，所以它是奇异的，因此，这是一个有约束的规范场理论。这些约束是在拉格朗日形式和哈密顿形式的场方程中应用约束算法得到的。为了做到这一点，协变场方程必须用一种合适的几何方式来写，使用由某种类型的多向量场表示的可积分布。我们得到并解释了拉格朗日约束的几何和物理意义，并构造了多动量(协变)哈密顿形式。在两种形式下讨论了该模型的规范对称性，并由此建立了与爱因斯坦-希尔伯特模型的等价性。

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New multisymplectic approach to the Metric-Affine (Einstein-Palatini) action for gravity

We present a covariant multisymplectic formulation for the Einstein-Palatini (or Metric-Affine) model of General Relativity (without energy-matter sources). As it is described by a first-order affine Lagrangian (in the derivatives of the fields), it is singular and, hence, this is a gauge field theory with constraints. These constraints are obtained after applying a constraint algorithm to the field equations, both in the Lagrangian and the Hamiltonian formalisms. In order to do this, the covariant field equations must be written in a suitable geometrical way, using integrable distributions which are represented by multivector fields of a certain type. We obtain and explain the geometrical and physical meaning of the Lagrangian constraints and we construct the multimomentum (covariant) Hamiltonian formalism. The gauge symmetries of the model are discussed in both formalisms and, from them, the equivalence with the Einstein-Hilbert model is established.

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来源期刊

Journal of Geometric Mechanics MATHEMATICS, APPLIED-PHYSICS, MATHEMATICAL

CiteScore

1.70

自引率

12.50%

发文量

审稿时长

>12 weeks

期刊介绍： The Journal of Geometric Mechanics (JGM) aims to publish research articles devoted to geometric methods (in a broad sense) in mechanics and control theory, and intends to facilitate interaction between theory and applications. Advances in the following topics are welcomed by the journal: 1. Lagrangian and Hamiltonian mechanics 2. Symplectic and Poisson geometry and their applications to mechanics 3. Geometric and optimal control theory 4. Geometric and variational integration 5. Geometry of stochastic systems 6. Geometric methods in dynamical systems 7. Continuum mechanics 8. Classical field theory 9. Fluid mechanics 10. Infinite-dimensional dynamical systems 11. Quantum mechanics and quantum information theory 12. Applications in physics, technology, engineering and the biological sciences.