Implications of the Mass-energy equivalence

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Discussion Overview

The discussion revolves around the implications of the mass-energy equivalence expressed by the equation E=mc². Participants explore whether this relationship necessitates that c is the cosmic speed limit and what other implications may arise from this equation, considering both theoretical and conceptual aspects.

Discussion Character

  • Exploratory
  • Debate/contested
  • Conceptual clarification
  • Mathematical reasoning

Main Points Raised

  • Some participants question whether E=mc² implies that c must be a universal constant and the cosmic speed limit.
  • One participant suggests reasoning backwards from E=mc² to derive implications for special relativity, noting that if E=mc² is accepted, it could lead to insights about the postulates of relativity.
  • Another participant argues that starting with E=mc² does not inherently imply motion or the consideration of moving mass, as E is derived from rest mass.
  • Some participants propose that if c is a universal conversion factor in the equation, it must also be a universal constant.
  • There is discussion about whether the relationship between energy and mass would logically lead to considerations of motion and relativity, with some expressing skepticism about this connection.
  • One participant introduces a transformation law that suggests c is a universal speed limit, but others question how this follows from E=mc² without prior knowledge of relativity.

Areas of Agreement / Disagreement

Participants express differing views on whether E=mc² logically leads to the concept of c as a cosmic speed limit. There is no consensus on the implications of the mass-energy equivalence regarding motion or the derivation of relativity.

Contextual Notes

Participants highlight the lack of motion implied by E=mc² and the potential assumptions involved in deriving implications for relativity. The discussion reflects varying interpretations of the relationship between energy, mass, and speed.

jpo
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Hello All,

Let m be a mass, equivalent to energy E such, that E=mc^{2}.
Does it follow that c is the cosmic speed limit?
======================================

To say the above with more words:
1) m is a mass
2) in some process, it is established that through removal/vanishing/anihilation/etc of m, energy E is released
3) it is established that E can be expressed as E= mc^{2}.

What are the implications of such energy-mass relationship? Does it follow that c must be the cosmic speed limit? What other, no matter how insignificant, implications does E= mc^{2} have on the parameter c?

Regards
 
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I guess I am trying to reason it backwards -

commonly, assuming a cosmic speed limit leads to special relativity relationships (length, time interval etc); conservation of the 4-dimensional momentum leads to E=mc^{2}

Can the relativity construct be built if we start at E=mc^{2} and follow backwards through the relativity argument.

Suppose someone wrote E=mc^{2}, not knowing anything about relativity or the meaning of c. In that case, if E=mc^{2} is accepted as true, what follows from it?
 
jpo said:
What are the implications of such energy-mass relationship? Does it follow that c must be the cosmic speed limit? What other, no matter how insignificant, implications does E= mc^{2} have on the parameter c?

As you say, E= mc^{2} is a conclusion not a starting point.

If you start with that conclusion, interpret it as suggesting that an object gains mass as its kinetic energy increases, and then work backwards, you can show that there is no necessary conflict with the two postulates of special relativity, nor with conservation of energy and momentum. But all you've really done in that exercise is demonstrate that special relativity is self-consistent.

You're asking "If B (E= mc^{2}) follows from A (the postulates of SR), then what can I say about A if I start by assuming that B is true?". The answer is "If B is true, then maybe A is true" and from there you can get to "maybe everything else that follows from A is also true". But you won't get beyond that point unless you can show that not only does A imply B, but also B implies A.
 
Well, it follows that c would need to be a universal constant. If you then take the general transformation between inertial frames:

\begin{bmatrix} t' \\ x' \end{bmatrix} = \frac{1}{\sqrt{1+\kappa v^2}} \begin{bmatrix} 1 & -\kappa v \\ -v & 1 \end{bmatrix} \begin{bmatrix} t \\ x \end{bmatrix}

where \kappa is some universal constant with dimensions 1/v2. One might therefore suspect that \kappa =-1/c^2.

From this transformation law (the Lorentz transformation), it follows that c is also a universal speed limit.
 
Last edited:
Nugatory,

Nugatory said:
If you start with E= mc^{2}, interpret it as suggesting that an object gains mass as its kinetic energy increases, ...

No motion is implied by E= mc^{2}, am I wrong? E appears as a result of converting REST MASS m to E.

How knowing E= mc^{2} would prompt us to look at moving mass m?
 
elfmotat,

elfmotat said:
Well, it follows that c would need to be a universal constant.

This sounds interesting... but HOW does it follow from E=mc^{2}?

As for looking at moving frames - the question again is - since E is a result of converting REST MASS, what would prompt us to consider motion, let alone moving frames? If we started looking at moving frames, we will eventually derive SR, but this would not be a logical consequence of E=mc^{2}, but sheer luck.

The assumption here is we know E=mc^{2} only and NOTHING about relativity yet. Will E=mc^{2} logically lead us to relativity and the concept c=const (cosmic speed limit)
 
hi.

E^2 - p^2 = m^2 proper constant in any coordinates is essence. Here I put c=1 nor E^2 - p^2 c^2 = m^2 c^4.
regards.
 
Last edited:
jpo said:
elfmotat,

This sounds interesting... but HOW does it follow from E=mc^{2}?

Well, sort of by definition. If c2 is a universal conversion factor between E and m, then it's by definition a universal constant.
 
Last edited:
jpo said:
No motion is implied by E= mc^{2}, am I wrong? E appears as a result of converting REST MASS m to E.

How knowing E= mc^{2} would prompt us to look at moving mass m?

If the energy E increases with increasing velocity (it does - that's what kinetic energy is all about) and the equality holds, then the right-hand side has to increase too.
 

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