The Thomas--Wigner rotation (TWR) results from the fact that a combination of boosts leads to a non-trivial rotation of a physical system. Its origin lies in the structure of the Lorentz group. In this article we discuss the idea that the TWR can be understood in the geometric manner, being caused by the non-trivially curved relativistic momentum space, i.e. the mass shell, seen as a Riemannian manifold. We show explicitly how the TWR for a massive spin-$1/2$ particle can be calculated as a holonomy of the mass shell. To reach this conclusion we recall how to construct the spin bundle over the mass shell manifold.Comment: 25 pages, 3 figure
Quantum-mechanical spin is often thought of in terms of classical angular momentum. In fact spin is ...
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We revisit spatially flat, anisotropic cosmologies within the framework of mini-superspace. Putting ...
We develop a theory of massive spinning particles interacting with background fields in four spaceti...
International audienceThis paper aims at explaining that a key to understanding quantum mechanics (Q...
It is possible to associate two angles with two successive non-collinear Lorentz boosts. If one boos...
It is shown that models of elementary particles in classical general relativity (geons) will natural...
The standard expression for the Wigner rotation leads to incorrect result for the wavefront rotation...
We live in a space, where the line element in a $n$-dimensional space-time is given by $(dx_0^2 - \s...
The connection between spin and symmetry was established by Wigner in his 1939 paper on the Poincar\...
In this paper, we review a general technique for converting the standard Lagrangian description of a...
Using a position operator obtained for spin 1/2 particles by the present author and Wigner, we obtai...
We report the simplest possible form to compute rotations around arbitrary axis and boosts in arbitr...
In the traditional formalism of quantum mechanics, a simple direct proof of (a version of) the Spin ...
In this paper, some physical expressions as the specific energy and the specific angular momentum on...
Quantum-mechanical spin is often thought of in terms of classical angular momentum. In fact spin is ...
The Thomas precession is shown to be due to the rotation of Minkowski space-time, a rotation which i...
We revisit spatially flat, anisotropic cosmologies within the framework of mini-superspace. Putting ...
We develop a theory of massive spinning particles interacting with background fields in four spaceti...
International audienceThis paper aims at explaining that a key to understanding quantum mechanics (Q...
It is possible to associate two angles with two successive non-collinear Lorentz boosts. If one boos...
It is shown that models of elementary particles in classical general relativity (geons) will natural...
The standard expression for the Wigner rotation leads to incorrect result for the wavefront rotation...
We live in a space, where the line element in a $n$-dimensional space-time is given by $(dx_0^2 - \s...
The connection between spin and symmetry was established by Wigner in his 1939 paper on the Poincar\...
In this paper, we review a general technique for converting the standard Lagrangian description of a...
Using a position operator obtained for spin 1/2 particles by the present author and Wigner, we obtai...
We report the simplest possible form to compute rotations around arbitrary axis and boosts in arbitr...
In the traditional formalism of quantum mechanics, a simple direct proof of (a version of) the Spin ...
In this paper, some physical expressions as the specific energy and the specific angular momentum on...
Quantum-mechanical spin is often thought of in terms of classical angular momentum. In fact spin is ...
The Thomas precession is shown to be due to the rotation of Minkowski space-time, a rotation which i...
We revisit spatially flat, anisotropic cosmologies within the framework of mini-superspace. Putting ...