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By the end of this section, you will be able to:
  • Explain how the work-energy theorem leads to an expression for the relativistic kinetic energy of an object
  • Show how the relativistic energy relates to the classical kinetic energy, and sets a limit on the speed of any object with mass
  • Describe how the total energy of a particle is related to its mass and velocity
  • Explain how relativity relates to energy-mass equivalence, and some of the practical implications of energy-mass equivalence

The tokamak in [link] is a form of experimental fusion reactor, which can change mass to energy. Nuclear reactors are proof of the relationship between energy and matter.

Conservation of energy is one of the most important laws in physics. Not only does energy have many important forms, but each form can be converted to any other. We know that classically, the total amount of energy in a system remains constant. Relativistically, energy is still conserved, but energy-mass equivalence must now be taken into account, for example, in the reactions that occur within a nuclear reactor. Relativistic energy is intentionally defined so that it is conserved in all inertial frames, just as is the case for relativistic momentum. As a consequence, several fundamental quantities are related in ways not known in classical physics. All of these relationships have been verified by experimental results and have fundamental consequences. The altered definition of energy contains some of the most fundamental and spectacular new insights into nature in recent history.

A photo of the NSTX tokamak.
The National Spherical Torus Experiment (NSTX) is a fusion reactor in which hydrogen isotopes undergo fusion to produce helium. In this process, a relatively small mass of fuel is converted into a large amount of energy. (credit: Princeton Plasma Physics Laboratory)

Kinetic energy and the ultimate speed limit

The first postulate of relativity states that the laws of physics are the same in all inertial frames. Einstein showed that the law of conservation of energy of a particle is valid relativistically, but for energy expressed in terms of velocity and mass in a way consistent with relativity.

Consider first the relativistic expression for the kinetic energy. We again use u for velocity to distinguish it from relative velocity v between observers. Classically, kinetic energy is related to mass and speed by the familiar expression K = 1 2 m u 2 . The corresponding relativistic expression for kinetic energy can be obtained from the work-energy theorem. This theorem states that the net work on a system goes into kinetic energy. Specifically, if a force, expressed as F = d p d t = m d ( γ u ) d t , accelerates a particle from rest to its final velocity, the work done on the particle should be equal to its final kinetic energy. In mathematical form, for one-dimensional motion:

K = F d x = m d d t ( γ u ) d x = m d ( γ u ) d t d x d t d t = m u d d t ( u 1 ( u / c ) 2 ) d t .

Integrate this by parts to obtain

K = m u 2 1 ( u / c ) 2 | 0 u m u 1 ( u / c ) 2 d u d t d t = m u 2 1 ( u / c ) 2 m u 1 ( u / c ) 2 d u = m u 2 1 ( u / c ) 2 m c 2 ( 1 ( u / c ) 2 ) | 0 u = m u 2 1 ( u / c ) 2 + m c 2 1 ( u / c ) 2 m c 2 = m c 2 [ ( u 2 / c 2 ) + 1 ( u 2 / c 2 ) 1 ( u / c ) 2 ] m c 2 K = m c 2 1 ( u / c ) 2 m c 2 .
Practice Key Terms 4

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Source:  OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4
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