Deriving formula for Relativistic Kinetic Energy

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SUMMARY

The discussion centers on the derivation of the relativistic kinetic energy formula, K_{ineticEnergy}=mc^2-m_{0}c^2, as presented in a textbook. Participants clarify the mathematical steps involved in changing the limits of integration and the implications of using relativistic mass. Specifically, the transition from the integral K=\int^{s}_{0} Fds to K=\int^{u}_{0}ud(\frac{m_{0}u}{\sqrt{1-\frac{u^2}{c^2}}}) is examined, with emphasis on the validity of variable substitution in integrals. The conversation concludes that no steps are omitted, and the reasoning aligns with standard practices in physics.

PREREQUISITES
  • Understanding of Newton's 2nd law and its application in physics.
  • Familiarity with integrals and variable substitution in calculus.
  • Knowledge of relativistic mass and its relationship to rest mass.
  • Basic concepts of kinetic energy and its derivation in classical and relativistic contexts.
NEXT STEPS
  • Study the derivation of relativistic kinetic energy from first principles in physics textbooks.
  • Learn about variable substitution techniques in calculus, particularly in the context of physics.
  • Examine the differences between classical and relativistic mechanics, focusing on mass concepts.
  • Review integral calculus applications in physics, specifically in energy and momentum calculations.
USEFUL FOR

Students of physics, particularly those studying classical mechanics and relativity, as well as educators seeking to clarify the derivation of kinetic energy formulas.

karkas
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Homework Statement


Hey all,
I am encountering a problem with a derivation of the formula K_{ineticEnergy}=mc^2-m_{0}c^2 as it is described by my textbook. I need someone to explain to me how the author changes the integral and the upper limit of it in the final part. I'll now give you the equations.

Homework Equations


The author states that the formula can be derived straight from the definition of kinetic energy
K=\int^{s}_{0} Fds and using Newton's 2nd law F= \frac{d(mu)}{dt} we get
K=\int^{s}_{0}\frac{d(mu)}{dt}ds=\int^{mu}_{0}ud(mu)=\int^{u}_{0}ud(\frac{m_{0}u}{\sqrt{1-\frac{u^2}{c^2}}})
and goes on in a way I can now follow.

The Attempt at a Solution


If someone could tell me the steps the author ommits that would be terrific. I've found that wikipedia's derivation of the formula doesn't have such confusing parts.
 
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karkas said:

Homework Statement


Hey all,
I am encountering a problem with a derivation of the formula K_{ineticEnergy}=mc^2-m_{0}c^2 as it is described by my textbook. I need someone to explain to me how the author changes the integral and the upper limit of it in the final part. I'll now give you the equations.



Homework Equations


The author states that the formula can be derived straight from the definition of kinetic energy
K=\int^{s}_{0} Fds and using Newton's 2nd law F= \frac{d(mu)}{dt} we get
K=\int^{s}_{0}\frac{d(mu)}{dt}ds=\int^{mu}_{0}ud(mu)=\int^{u}_{0}ud(\frac{m_{0}u}{\sqrt{1-\frac{u^2}{c^2}}})
and goes on in a way I can now follow.



The Attempt at a Solution


If someone could tell me the steps the author ommits that would be terrific. I've found that wikipedia's derivation of the formula doesn't have such confusing parts.

No steps are omitted. One step relates to the quantity \frac{ds}{dt} in the first integral, and the second step is simply writing the relativistic mass in terms of the rest mass.
 
Ok but there are some things I'm not sure about:

1) why does the upper limit change from s to mu, simply because we swap ds/dt for u and use d(mu) for the variable of integration, it just doesn't sound too strict mathematically to me.

2) why does m vanish in the final upper limit just because we use relativistic mass?
 
karkas said:
Ok but there are some things I'm not sure about:

1) why does the upper limit change from s to mu, simply because we swap ds/dt for u and use d(mu) for the variable of integration, it just doesn't sound too strict mathematically to me.

Integrating d(mu) from one position to another position doesn't make sense, so the integral is written in terms of going from one momentum to another. There's nothing mathematically flawed about changing the variable of integration, and therefore changing the limits of the integration. Of course, this is one of those instances where just writing u = ds/dt can get you in trouble, if you don't think about what else must change to accompany that if you're doing that operation inside an integral.

2) why does m vanish in the final upper limit just because we use relativistic mass?

For the same reason. The integration variable is no longer mu; the integral depends only on u at this point.
 
I see, I think I get it , thanks!
 
If you're at all ever confused about this sort of thing, never hesitate to do a formal variable substitution like you would for a traditional integral. The author is being lax, like physicists typically are, and assuming that the integral of ds from the initial position to the final position is equivalent to the integral of d(mu) from the initial momentum to the final momentum, since it is the same motion that is being integrated over in either case. This is of course obvious to the physicist, but it rightfully does make the mathematician shudder :)
 
Seeing as I'm studying Physics, this may be a bad sign
 
I didn't mean it like that all! It's only obvious to the physicist after you've had some practice with it (which you're now starting to get). One of the great things about being an undergrad is that you do it the hard way now, so that you can justify doing it the easy way for the rest of your career :)
 
This is Introductory physics? :O
 

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