High School Acceleration at Near-Light Speed: Answers

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SUMMARY

The discussion centers on the behavior of acceleration as an object approaches near-light speed, specifically at 0.9999c. It confirms that while an observer in a rocket moving at this speed will experience constant acceleration (1g), an external observer on Earth will perceive a reduced acceleration due to relativistic effects. The fundamental principle that the laws of physics remain consistent across reference frames is emphasized, highlighting that both observers can ignite rockets and feel normal acceleration despite differing measurements. The Lorentz gamma factor is introduced to quantify the relationship between perceived and actual acceleration.

PREREQUISITES
  • Understanding of special relativity principles
  • Familiarity with the Lorentz gamma factor
  • Knowledge of inertial and non-inertial reference frames
  • Basic concepts of acceleration and its measurement
NEXT STEPS
  • Study the implications of the Lorentz transformation in special relativity
  • Explore the effects of relativistic speeds on time dilation and length contraction
  • Investigate the concept of proper acceleration in non-inertial frames
  • Learn about gyroscopic motion and its relativistic behavior
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Physics students, aerospace engineers, and anyone interested in the implications of relativistic physics on motion and acceleration.

derek10
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Hi
I understand that accelerating you get closer and closer to the speed of light wrt anything in an asymptotic way, but would acceleration still act the same way as non relativistic speeds (inertia, gyroscope, etc?) even if the speed won't increase almost at all (for example at 0.9999 c)
Thank you
 
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What do you mean by "act the same way"? If you have a rocket that moves at 0.9999 c relative to Earth, you would not notice anything special in the rocket, and you can use the rocket to accelerate as usual*. That is one of the fundamental principles of physics: the laws of physics are the same in every reference frame. Why should you have to care about your speed relative to Earth? There is nothing special about Earth.

*Observers on Earth will measure a different acceleration than you in your rocket.
 
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Someone moving close to the speed of light relative to you can consider themselves at rest and you as moving close to the speed of light. You can both ignite rockets and feel a 1g acceleration. Both of you will report that you are accelerating at 1g and the other as accelerating much less. Both of you can spin up gyroscopes and find they look normal, but the other guy's will look odd - see the illustration half way down http://asia.iop.org/cws/article/news/50366
 
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Thank you. I mean accelerating constantly from the Earth toward c , so it will still accelerate but the speed increase of this acceleration will slow down with respect to the earth, but not with other objects, right?
 
Yes. If you are accelerating in your direction of motion with respect to some object, if you feel an acceleration ##a## then an observer in an inertial frame will observe an acceleration ##\gamma^3a##, where ##\gamma=(1-v^2/c^2)^{-1/2}## is the Lorentz gamma factor and ##v## is your speed with respect to that object. So as you approach light speed (with respect to me) I will see your acceleration drop while you will feel it remaining constant.
 

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