In order to maintain momentum conservation in collisions which undergo Lorentz transformation Einstein had to modify the Newtonian definition of momentum to relativistic domains. This resulted in his famous mass-energy equivalence relation E=mc2 . We suggest here that Lorentz invariance offers a more general form of relativistic momentum which would give a more general expression for kinetic and total energy. We further suggest methods to test the validity of this generalized relativistic mechanics.
The equivalence of mass and energy given by the relation:
E = m c 2 (1)
is the most famous contribution of Einstein [
In order to determine a more general version of the mass-energy relation, we study the factors that led to the development of this relation. In the subsequent section we will develop a generalization of the mass-energy relation, consistent with Lorentz invariance, whose first approximation will result in the familiar mass-energy equivalence. Finally we conclude by suggesting how experiments can test whether the expressions for the generalized kinetic energy and relativistic momentum are correct.
Einstein noticed that the Lorentz transformation for velocity, being nonlinear, will not respect the linearly additive conservation of momentum in a collision between particles if the momentum p is defined as in Newtonian mechanics as:
p = m o v , (2)
where m o is mass (inertia) of a particle moving with a velocity v. He noticed that conservation of momentum will be at stake under Lorentz transformation if we stick to the Newtonian definition for momentum. The stroke of his genius was to define the relativistic momentum p r as:
p r = γ m o v , (3)
where γ is the Lorentz factor given by:
γ = 1 1 − v 2 c 2 = 1 1 − β 2 , β = v c . (4)
This directly results in the expression for the kinetic energy T as:
T = ∫ 0 v v ⋅ d p = ∫ 0 v v d p = ( γ − 1 ) m o c 2 . (5)
The velocity independent term in Equation (5), i.e., the constant of integration prompted Einstein [
E = T + m o c 2 = γ m o c 2 , (6)
where E is the total energy and the second term m o c 2 is termed the rest energy. Equation (6) is what Einstein termed as energy-mass equivalence.
The success of this expression for kinetic energy as given in Equation (5) lies in the observation that it leads to in the approximation at low velocities:
T = ( γ − 1 ) m o c 2 = m o c 2 ( 1 + β 2 / 2 + ⋯ − 1 ) = 1 2 m o v 2 . (7)
familiar in non-relativistic Newtonian mechanics. Einstein considered this as the main validation for the expression in Equation (5). Equation (3) and Equation (6) lead us to the important relation: for the energy:
E 2 = c 2 p ⋅ p + m o 2 c 4 . (8)
This relation guarantees Lorentz invariance and is a direct consequence of the simple identity:
γ 2 − γ 2 β 2 = 1. (9)
This identity is akin to the properties of hyperbolic trigonometric cosh and sinh functions. This is the key used to generalize the definition of relativistic momentum in the next section. As has been mentioned by many authors [
We attempt here to see if there is a more general expression for the relativistic momentum for which Equation (3) is just an approximation and analyze its consequences. Specifically we define the momentum as:
p = u v m o c sinh − 1 ( β γ ) p = u v m o c cosh − 1 γ p = u v m o c tanh − 1 β p = u v m o c log ( γ ( 1 + β ) ) (10)
where u v denotes the unit vector in the direction of v and v denotes ‖ v ‖ 2 or alternatively
sinh ( p m o c ) = β γ cosh ( p m o c ) = γ tanh ( p m o c ) = β = v c m o c 2 cosh ( p m o c ) m o c 2 sinh ( p m o c ) = c v (11)
With this definition, the expression for the kinetic energy becomes:
K = ∫ 0 v v ⋅ d p = ∫ 0 v v d p = m o c 2 ∫ 0 β β d β 1 − β 2 = m o c 2 log γ . (12)
Naively as a first approximation we get:
K ≈ m o c 2 ( γ − 1 ) = T , (13)
which is the usual expression given in Equation (5). More precisely, since γ ≥ 1 :
K = − m o c 2 log 1 − β 2 , (14)
which for smaller values of β yields:
K ≈ m o c 2 ( 1 − 1 − β 2 ) . (15)
This in particular appears as the kinetic energy of a relativistic particle in the classical Lagrangian. From Equation (10), we obtain:
[ m o c 2 cosh ( p m o c ) ] 2 − [ m o c 2 sinh ( p m o c ) ] 2 = m o 2 c 4 (16)
This further implies that:
( γ m o c 2 ) 2 − ( γ β m o c 2 ) 2 = ( γ m o c 2 ) 2 − ( γ m o v c ) 2 = m o 2 c 4 . (17)
Thus:
γ m o c 2 = m o c 2 e log γ = m o c 2 e K m o c 2 ≈ m o c 2 ( 1 + K m o c 2 ) = K + m o c 2 = E
γ m o v c = m o c 2 sinh ( p m o c ) (18)
For low values of p this becomes:
γ m o v c ≈ m o c 2 p m o c = c p . (19)
Then we get the expression for low values of p:
E 2 − c 2 p ⋅ p = m o 2 c 4 ,
which is Equation (6) as a first approximation. The close connection of the Lorentz transform to hyperbolic functions has been known from the early days of special relativity. We emphasize that in the generalization in Equation (17), the first term is E2 and the second term is c 2 p ⋅ p for Einstein. This is only an approximation to the more general expression, where the first term in the identity:
( m o c 2 cosh ( p m o c ) ) 2 = ( m o c 2 e T m o c 2 ) 2 (20)
and the second term is given by ( m o c 2 sinh ( p m o c ) ) 2 .
A new definition for relativistic momentum that is consistent with Lorentz invariance is suggested. As is known, the relativistic formulas for momentum and energy are not amenable to direct tests of high precision [
I would like to thank Prof. Balu Santhanam, Department of E.C.E., University of New Mexico, Albuquerque, USA, for editing the manuscript.
Santhanam, T.S. (2018) On a Generalization of Einstein’s E = mc2. Journal of Applied Mathematics and Physics, 6, 1012-1016. https://doi.org/10.4236/jamp.2018.65088