luc Posted June 8, 2005 Posted June 8, 2005 Right now I'm reading Hawking's "The large scale-structure of space time", and he uses constantly a quantity called Energy-momentum, though I can't see it defined anywhere. I've also read in some forum that in GR, total energy is not conserved, but energy-momentum is conserved. I think that perhaps energy-momentum is (Total energy + magnitude of 4-momentum), but I'm not sure. What exactly is energy-momentum?
swansont Posted June 8, 2005 Posted June 8, 2005 There's an energy-momentum 4-vector, comprised of E and the three spatial components of pc. The scalar product with itself gives you E2 - p2c2, which is the square of the rest energy.
luc Posted June 8, 2005 Author Posted June 8, 2005 'kay, but I think that 4-momentum is the same as the energy-momentum 4-vector (at least is Special Relativity is that way). So energy-momentum is the magnitude of the energy-momentum 4-vector, is that what you're saying?
swansont Posted June 8, 2005 Posted June 8, 2005 'kay, but I think that 4-momentum is the same as the energy-momentum 4-vector (at least is Special Relativity is that way). So energy-momentum is the magnitude of the energy-momentum 4-vector, is that what you're saying? I haven't read the book, so I can't say for sure. IN GR there is also an energy-momentum tensor, aka the stress-energy tensor.
□h=-16πT Posted June 8, 2005 Posted June 8, 2005 'kay, but I think that 4-momentum is the same as the energy-momentum 4-vector (at least is Special Relativity is that way). The energy-momentum four-vector is the same as the 4-momentum vector. The 4-momentum vector has as its time component the energy of the frame and so gets its other name "energy-momentum" four-vector.
Tom Mattson Posted June 8, 2005 Posted June 8, 2005 'kay' date=' but I think that 4-momentum is the same as the energy-momentum 4-vector (at least is Special Relativity is that way). [/quote'] That's right. So energy-momentum is the magnitude of the energy-momentum 4-vector, is that what you're saying? That's not right. The norm of a particle's 4-momentum is the mass of the particle. [math] p^{\mu}=(E,\mathbf{p}) [/math] [math] p_{\mu}=(E,-\mathbf{p}) [/math] Taking their inner product yields: [math] p^{\mu}p_{\mu}=E^2-p^2=m^2 [/math] where [math]p[/math] is the norm of the 3-momentum.
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