What is the Minkowski metric tensor's trace?

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    Metric Minkowski Trace
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LCSphysicist
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I would appreciate if you explain to me how to get the Minkowski metric tensor's trace.
I am trying to follow the rule, that is, raising an index and the contract it.
Be ##g_{\mu v}## the metric tensor in Minkowski space.
Raising ##n^{v \mu}g_{\mu v}## and then, we need now to contract it.
Now, in this step i smell a rat (i learned this pun today, hope this mean what i think this means haha)
Can i simply say that ##\mu## is an index using Einstein notation? I am a little confused how to contract this and then reduced it to delta kronecker, which, in the end, will give us the trace equal four.
 
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LCSphysicist said:
Be ##g_{\mu v}## the metric tensor in Minkowski space.
Raising ##n^{v \mu}g_{\mu v}## and then, we need now to contract it.
If ##g_{\mu\nu}## is the metric then the inverse metric should be ##g^{\mu\nu}##. If you are meaning the metric of flat space, typically that's denoted ##\eta_{\mu\nu}## and the inverse would be denoted ##\eta^{\mu\nu}##. There's nothing wrong with using ##g## instead of ##\eta##, but you need to use it consistently.

Apart from that, what you've written seems fine. If you want to think of it in several stages, first you would use ##g^{\rho\mu}## to raise an index, giving you ##g^{\rho\mu}g_{\mu\nu}##, which is indeed ##\delta^\rho_\nu##. Then you can contract over the upper and lower indices - i.e. you needed to set ##\rho=\nu##, which (give or take using ##g## or ##\eta##) is what you wrote. Writing the sums explicitly (so no summation convention implied) it's ##\sum_{\mu=0}^4\sum_{\nu=0}^4g^{\mu\nu}g_{\mu\nu}##.
 
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Carroll's textbook Spacetime and Gravitation discusses it, I think it is in the first chapter.
 
Carroll's textbook Spacetime and Gravitation discusses it, I think it is in the first chapter. And the solution is as you wrote the trace is four. Page 28 in Carroll's textbook