Covariant derivative of stress-energy tensor

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Discussion Overview

The discussion revolves around the covariant derivative of the stress-energy tensor, specifically addressing the conditions under which the divergence of the tensor is zero and the role of Christoffel symbols in curved space.

Discussion Character

  • Technical explanation
  • Debate/contested

Main Points Raised

  • One participant asserts that the condition \( T^{ab}_{;b} = 0 \) arises from the negative divergence of density, questioning why the Christoffel symbols vanish in this context.
  • Another participant challenges this assumption, suggesting that the initial equation may be applicable only in flat space and not in curved space.
  • A third participant notes that the equation \( \nabla_{\mu} T^{\mu \nu} = 0 \) can be derived from \( \nabla_{\mu} G^{\mu \nu} = 0 \), referencing the second Bianchi identity and suggesting a local equivalence of the divergence conditions across coordinate systems.

Areas of Agreement / Disagreement

Participants express differing views on the applicability of the Christoffel symbols and the conditions under which the divergence of the stress-energy tensor is zero, indicating that multiple competing views remain without consensus.

Contextual Notes

There are unresolved assumptions regarding the applicability of equations in different geometrical contexts, particularly between flat and curved spaces.

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hi, I understand that Tab,b=0 because the change in density equals the negative divergence, but why do the christoffel symbols vanish for Tab;b=0?
 
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They don't. Why would you think that?

I think your first equation came from flat space, because it is not true in curved space.
 
\triangledown _{\mu }T^{\mu \nu } = 0 can be gotten from \triangledown_{\mu }G^{\mu \nu } = 0 which is a consequence of the second bianchi identity. You also know that T^{\mu \nu }, _{\mu } = 0 but what you can do is say that locally this is the same thing as T^{\mu \nu }; _{\mu } = 0 and if this is true for some coordinate system it will be true for all coordinate systems.
 
thank you
 

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