21 research outputs found
Wheeler-DeWitt equation and Lie symmetries in Bianchi scalar-field cosmology
Lie symmetries are discussed for the Wheeler-De Witt equation in Bianchi
Class A cosmologies. In particular, we consider General Relativity, minimally
coupled scalar field gravity and Hybrid Gravity as paradigmatic examples of the
approach. Several invariant solutions are determined and classified according
to the form of the scalar field potential. The approach gives rise to a
suitable method to select classical solutions and it is based on the first
principle of the existence of symmetries.Comment: 17 page
Autonomous three dimensional Newtonian systems which admit Lie and Noether point symmetries
We determine the autonomous three dimensional Newtonian systems which admit
Lie point symmetries and the three dimensional autonomous Newtonian Hamiltonian
systems, which admit Noether point symmetries. We apply the results in order to
determine the two dimensional Hamiltonian dynamical systems which move in a
space of constant non-vanishing curvature and are integrable via Noether point
symmetries. The derivation of the results is geometric and can be extended
naturally to higher dimensions.Comment: Accepted for publication in Journal of Physics A: Math. and Theor.,13
page
Quadratic conservation laws and collineations: A discussion
Every second order system of autonomous differential equations can be described by an autonomous holonomic dynamical system with a Lagrangian part, an effective potential and a set of generalized forces. The kinematic part of the Lagrangian defines the kinetic metric which subsequently defines a Riemannian geometry in the configuration space. We consider the generic function I=Kab(t,qc)q̇aq̇b+Ka(t,qc)q̇a+K(t,qc) and require the quadratic first integral condition dI∕dt=0 without involving any type of symmetry Lie or Noether. Condition dI∕dt=0 leads to a system of equations involving the coefficients Kab(t,qc),Ka(t,qc),K(t,qc) whose solution will produce all possible quadratic first integrals of the original system of autonomous differential equations. We show that the new system of equations relates the quadratic first integrals of the holonomic system with the geometric collineations of the kinetic metric and in particular with the Killing tensors of order two. We consider briefly various results concerning the Killing tensors of second-order and prove a general formula which gives in the case of a flat kinetic metric the generic Killing tensor in terms of the vectors of the special projective algebra of the kinetic metric. This establishes the connection between the geometry defined by the kinetic metric and the quadratic first integrals of the original system of differential equations. © 2018 Elsevier B.V
Lie and Noether point symmetries for a class of nonautonomous dynamical systems
We prove two general theorems that determine the Lie and the Noether point symmetries for the equations of motion of a dynamical system thatmoves in a general Riemannian space under the action of a time dependent potentialW(t, x) =ω(t)V(x).We apply the theorems to the case of a time dependent central potential and the harmonic oscillator and determine all Lie and Noether point symmetries. Finally we prove that these theorems also apply to the case of a dynamical system with linear dumping and study two examples
Wheeler–DeWitt equation and Lie symmetries in Bianchi scalar-field cosmology
Lie symmetries are discussed for the Wheeler-De Witt equation in Bianchi Class A cosmologies. In particular, we consider general relativity, minimally coupled scalar-field gravity and hybrid gravity as paradigmatic examples of the approach. Several invariant solutions are determined and classified according to the form of the scalar-field potential. The approach gives rise to a suitable method to select classical solutions and it is based on the first principle of the existence of symmetries. © 2016, The Author(s)
Cartan symmetries and global dynamical systems analysis in a higher-order modified teleparallel theory
In a higher-order modified teleparallel theory cosmological we present analytical cosmological solutions. In particular we determine forms of the unknown potential which drives the scalar field such that the field equations form a Liouville integrable system. For the determination of the conservation laws we apply the Cartan symmetries. Furthermore, inspired from our solutions, a toy model is studied and it is shown that it can describe the Supernova data, while at the same time introduces dark matter components in the Hubble function. When the extra matter source is a stiff fluid then we show how analytical solutions for Bianchi I universes can be constructed from our analysis. Finally, we perform a global dynamical analysis of the field equations by using variables different from that of the Hubble-normalization. © 2018, Springer Science+Business Media, LLC, part of Springer Nature