Is Mass a Relative Concept in Physics?

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Discussion Overview

The discussion revolves around the concept of mass in physics, particularly whether it is a relative concept. Participants explore the implications of mass in different reference frames, the relationship between mass and energy, and the distinctions between invariant mass and relativistic mass. The conversation touches on theoretical aspects, definitions, and interpretations within the context of relativity.

Discussion Character

  • Debate/contested
  • Technical explanation
  • Conceptual clarification

Main Points Raised

  • Some participants propose that as an object loses potential energy, it also loses mass, suggesting a relationship between energy loss and mass loss.
  • Others argue that mass is not a fixed quantity and can vary depending on the observer's frame of reference, particularly in relativistic contexts.
  • There is a discussion about the distinction between invariant mass and relativistic mass, with some asserting that invariant mass is the more relevant concept in modern physics.
  • One participant questions whether there is a mass that remains invariant across all reference frames, leading to a clarification that invariant mass does indeed have the same value in all inertial frames.
  • Some express confusion over the terminology used in different physics texts, noting that the use of relativistic mass varies among authors and can lead to inconsistent interpretations.
  • Participants highlight the importance of specifying the type of mass being discussed to avoid misunderstandings in discussions about mass conservation and invariance.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the definitions and implications of mass. There are multiple competing views regarding the relevance of relativistic mass versus invariant mass, and the discussion remains unresolved on several points.

Contextual Notes

There are limitations in the discussion regarding the definitions of mass, the assumptions underlying the relationship between mass and energy, and the varying interpretations of mass in different contexts. Some mathematical steps and definitions remain unresolved.

derek.basler
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Ok this may or may not sound like a very stupid idea. But having read the Black Hole War by Leonard Susskind, he makes a claim that as the Earth gets closer and closer to the center, squeezed by gravity, it loses potential energy. The lost potential energy is then radiated as heat, and therefore the Earth loses energy. And since energy and mass are inter-related, the Earth thereby loses mass. However, if my understanding is correct, potential energy is a relative measure [ P.E = mgh]. So would that also make mass a relative aspect as well, since energy is really mass? My understanding of the General Theory of Relativity is somewhat weak, so if anyone could just clear this up I would greatly appreciate it.
 
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Of course it is. That's true in the special theory as well: if the mass of an object is m0 in a coordinate system in which it is at rest, its mass as measured in a coordinate system moving at speed v with respect to it is
[tex]\frac{m_0}{\sqrt{1- \frac{v^2}{c^2}}}[/tex]
 
So mass is not a set number at all then. If you were traveling next to an object at the same velocity, and you measured its mass, and then some how measured it while you were at rest and the object was still moving, their masses would differ?
 
Sounds weird. I was always told I'd _lose_ weight by jogging. :)
 
You got it!
Mass, length, time, kinetic energy are all relative.
Electric charge and potential energy seem fixed. And I still wonder about potential energy.
 
I wonder what physics mean by MASS by default?
Relativistic (like in this thread) or Invariant mass?
I was told in this forum that in modern physics mass=invariant mass as relativistic mass is just a synonym for E/c^2 and is useless.
 
The mass needs to be useful. One useful application should be for gravitational force calculation.
 
well it seems that you change in mass would be equal to your change in energy, potential or kinetic, then that divided by the speed of light squared plus your rest mass? Is there a mass that stays invariant no matter what reference frame you observe it from?
 
derek.basler said:
Is there a mass that stays invariant no matter what reference frame you observe it from?

Yes, the invariant mass [itex]m_0[/itex] which can be calculated from

[tex]m_0 c^2 = \sqrt {E^2 - (pc)^2}[/tex]

has the same value in all inertial reference frames.
 
  • #10
The relativistic mass (aka total energy) is relative. The invariant mass (aka rest mass) is invariant. Typically the unqualified term "mass" refers to "invariant mass".
 
  • #11
I was told in this forum that in modern physics mass=invariant mass as relativistic mass is just a synonym for E/c^2 and is useless.

That does seem to be a convention favored by some here, yet in books I read by Smolin, Hawking, Penrose, Greene, Randall and others, they seem to routinely use relativistic mass...I don't see it as a big deal either way...
 
  • #12
derek.basler said:
The lost potential energy is then radiated as heat, and therefore the Earth loses energy. And since energy and mass are inter-related, the Earth thereby loses mass.
True. The Earth loses invariant mass during this process. It's a pity that pervect is no longer around to give a short lecture on the meaning of "mass" in GR.
 
  • #13
Naty1 said:
That does seem to be a convention favored by some here, yet in books I read by Smolin, Hawking, Penrose, Greene, Randall and others, they seem to routinely use relativistic mass...I don't see it as a big deal either way...

The big deal is that people get replies without specifying the meaning of the "mass".
The same person can get inconsistent replies in parralel threads, like "is mass conserved? yes", "is mass invariant? yes"
 
  • #14
Naty1 said:
That does seem to be a convention favored by some here, yet in books I read by Smolin, Hawking, Penrose, Greene, Randall and others, they seem to routinely use relativistic mass...I don't see it as a big deal either way...
Are they textbooks of physics currently used at university? Because if they were, it would be serious; if they are not, then I suggest you to look up in physics textbooks.
 

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