Quadrupole formula: Difference between revisions

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In general relativity, the quadrupole formula describes the rate at which gravitational waves are emitted from a system of masses based on the change of the (mass) quadrupole moment. The formula reads

{\bar {h}}_{ij}(t,r)={\frac {2G}{c^{4}r}}{\ddot {I}}_{ij}(t-r/c),

where ${\bar {h}}_{ij}$ is the spatial part of the trace reversed perturbation of the metric, i.e. the gravitational wave. $G$ is the gravitational constant, $c$ the speed of light in vacuum, and $I_{ij}$ is the mass quadrupole moment.^[1]

It is useful to express the gravitational wave strain in the transverse traceless gauge, which is given by a similar formula where $I_{ij}^{T}$ is the traceless part of the mass quadrupole moment.

{I}_{ij}^{T}=\int \rho (\mathbf {x} )\left[r_{i}r_{j}-{\frac {1}{3}}r^{2}\delta _{ij}\right]d^{3}r,

The total energy (luminosity) carried away by gravitational waves is

{\frac {dE}{dt}}=\sum _{ij}{\frac {G}{5c^{5}}}\left({\frac {d^{3}I_{ij}^{T}}{dt^{3}}}\right)^{2}

The formula was first obtained by Albert Einstein in 1918. After a long history of debate on its physical correctness, observations of energy loss due to gravitational radiation in the Hulse–Taylor binary discovered in 1974 confirmed the result, with agreement up to 0.2 percent (by 2005).^[2]

References

^ Carroll, Sean M. (2004). Spacetime and Geometry. Pearson/Addison Wesley. pp. 300–307. ISBN 978-0805387322.
^ Poisson, Eric; Will, Clifford M. (2014-05-29). Gravity:Newtonian, Post-Newtonian, Relativistic. Cambridge University Press. pp. 550–563. ISBN 9781107032866.

[1] Carroll, Sean M. (2004). Spacetime and Geometry. Pearson/Addison Wesley. pp. 300–307. ISBN 978-0805387322.

[2] Poisson, Eric; Will, Clifford M. (2014-05-29). Gravity:Newtonian, Post-Newtonian, Relativistic. Cambridge University Press. pp. 550–563. ISBN 9781107032866.

[1]

[2]

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+{{Short description|Formula in general relativity}}
 In [[general relativity]], the '''quadrupole formula''' describes the rate at which [[gravitational wave]]s are emitted from a system of masses based on the change of the (mass) [[quadrupole moment]]. The formula reads
 :<math> \bar{h}_{ij}(t,r) = \frac{2 G}{c^4 r} \ddot{I}_{ij}(t-r/c), </math>
@@ Line 10: / Line 11: @@
 |year=2004
 }}</ref>
+It is useful to express the gravitational wave strain in the transverse traceless gauge, which is given by a similar formula where <math>I_{ij}^{T}</math> is the traceless part of the mass [[quadrupole moment]].
+:<math> {I}_{ij}^T = \int \rho(\mathbf{x}) \left[r_i r_j - \frac{1}{3} r^2 \delta_{ij}\right]  d^3 r, </math>
+The total energy (luminosity) carried away by gravitational waves is
+:<math> \frac{d E}{dt} = \sum_{ij} \frac{G}{5 c^5} \left( \frac{d^3 I_{ij}^{T}}{dt^3} \right)^2 </math>
 The formula was first obtained by [[Albert Einstein]] in 1918. After a long history of debate on its physical correctness, observations of energy loss due to gravitational radiation in the [[Hulse–Taylor binary]] discovered in 1974 confirmed the result, with agreement up to 0.2 percent (by 2005).<ref>{{cite book
@@ Line 22: / Line 29: @@
 |date=2014-05-29
 }}</ref>
+== See also ==
+* [[Multipole radiation]]
+* [[Birkhoff's theorem (relativity)]]
+* [[PSR J0737−3039]]
 ==References==

v t e Albert Einstein
Physics	Theory of relativity Special relativity General relativity Mass–energy equivalence (E=mc²) Brownian motion Photoelectric effect Einstein coefficients Einstein solid Equivalence principle Einstein field equations Einstein radius Einstein relation (kinetic theory) Cosmological constant Bose–Einstein condensate Bose–Einstein statistics Bose–Einstein correlations Einstein–Cartan theory Einstein–Infeld–Hoffmann equations Einstein–de Haas effect EPR paradox Bohr–Einstein debates Teleparallelism Thought experiments Unsuccessful investigations Wave–particle duality Gravitational wave Tea leaf paradox
Works	Annus mirabilis papers (1905) "Investigations on the Theory of Brownian Movement" (1905) Relativity: The Special and the General Theory (1916) The Meaning of Relativity (1922) The World as I See It (1934) The Evolution of Physics (1938) "Why Socialism?" (1949) Russell–Einstein Manifesto (1955)
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