Introductory treatments of relativistic dynamics rely on the invariance of momentum conservation (i.e., on the assumption that momentum is conserved in all inertial frames if it is conserved in one) to establish the relationship for the momentum of a particle in terms of its mass and velocity. By contrast, more advanced treatments rely on the transformation properties of the four-velocity and/or proper time to obtain the same result and then show that momentum conservation is invariant. Here, we will outline a derivation of that relationship that, in the spirit of the more advanced treatments, relies on an elemental feature of the transformation of momentum rather than on its conservation but does not have as a prerequisite the introduction...
Einstein’s relation between mass and energy is perhaps the most famous equation of Physics. Despite ...
We consider conservation of momentum in AQUAL, a field-theoretic extension to Modified Newtonian Dyn...
Newton's law of motion relative to an inertial frame ("the laboratory") for a particle subject to a ...
Introductory treatments of relativistic dynamics rely on the invariance of momentum conservation (i....
We show that relativistic dynamics can be approached without using conservation laws (conservation o...
Based on relativistic velocity addition and the conservation of momentum and energy, I present deriv...
Restricted Access.For a classical-mechanical system of any fixed number of particles it is observed ...
Considerations on the complementary time-dependent coordinate transformations emboding Lorentz trans...
A part of relativistic dynamics (or mechanics) is axiomatized by simple and purely geometrical axiom...
A rigorous definition of mass in special relativity, proposed in a recent paper, is recalled and emp...
A rigorous definition of mass in special relativity, proposed in a recent paper, is recalled and emp...
A rigorous definition of mass in special relativity, proposed in a recent paper, is recalled and emp...
We present a new derivation of the expressions for momentum and energy of a relativistic particle. I...
In a number of previous notes, e.g. (1), we argued that the form of special relativity follows from ...
We first define the functions which ensure the transformation of momentum and energy of a tardyon, t...
Einstein’s relation between mass and energy is perhaps the most famous equation of Physics. Despite ...
We consider conservation of momentum in AQUAL, a field-theoretic extension to Modified Newtonian Dyn...
Newton's law of motion relative to an inertial frame ("the laboratory") for a particle subject to a ...
Introductory treatments of relativistic dynamics rely on the invariance of momentum conservation (i....
We show that relativistic dynamics can be approached without using conservation laws (conservation o...
Based on relativistic velocity addition and the conservation of momentum and energy, I present deriv...
Restricted Access.For a classical-mechanical system of any fixed number of particles it is observed ...
Considerations on the complementary time-dependent coordinate transformations emboding Lorentz trans...
A part of relativistic dynamics (or mechanics) is axiomatized by simple and purely geometrical axiom...
A rigorous definition of mass in special relativity, proposed in a recent paper, is recalled and emp...
A rigorous definition of mass in special relativity, proposed in a recent paper, is recalled and emp...
A rigorous definition of mass in special relativity, proposed in a recent paper, is recalled and emp...
We present a new derivation of the expressions for momentum and energy of a relativistic particle. I...
In a number of previous notes, e.g. (1), we argued that the form of special relativity follows from ...
We first define the functions which ensure the transformation of momentum and energy of a tardyon, t...
Einstein’s relation between mass and energy is perhaps the most famous equation of Physics. Despite ...
We consider conservation of momentum in AQUAL, a field-theoretic extension to Modified Newtonian Dyn...
Newton's law of motion relative to an inertial frame ("the laboratory") for a particle subject to a ...
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