Quadrupole formula: Difference between revisions

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]

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.

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)
In popular culture	Die Grundlagen der Einsteinschen Relativitäts-Theorie (1922 documentary) The Einstein Theory of Relativity (1923 documentary) Relics: Einstein's Brain (1994 documentary) Insignificance (1985 film) Young Einstein (1988 film) Picasso at the Lapin Agile (1993 play) I.Q. (1994 film) Einstein's Gift (2003 play) Einstein and Eddington (2008 TV film) Genius (2017 series) Oppenheimer (2023 film)
Prizes	Albert Einstein Award Albert Einstein Medal Kalinga Prize Albert Einstein Peace Prize Albert Einstein World Award of Science Einstein Prize for Laser Science Einstein Prize (APS)
Books about Einstein	Albert Einstein: Creator and Rebel Einstein and Religion Einstein for Beginners Einstein: His Life and Universe Einstein's Cosmos I Am Albert Einstein Introducing Relativity Subtle is the Lord
Family	Mileva Marić (first wife) Elsa Einstein (second wife; cousin) Lieserl Einstein (daughter) Hans Albert Einstein (son) Pauline Koch (mother) Hermann Einstein (father) Maja Einstein (sister) Eduard Einstein (son) Robert Einstein (cousin) Bernhard Caesar Einstein (grandson) Evelyn Einstein (granddaughter) Thomas Martin Einstein (great-grandson) Siegbert Einstein (distant cousin)
Related	Awards and honors Brain House Memorial Political views Religious views Things named after Einstein–Oppenheimer relationship Albert Einstein Archives Einstein's Blackboard Einstein Papers Project Einstein refrigerator Einsteinhaus Einsteinium Max Talmey Emergency Committee of Atomic Scientists
Category

Relativity

Special
relativity

Background	Principle of relativity (Galilean relativity Galilean transformation) Special relativity Doubly special relativity
Fundamental concepts	Frame of reference Speed of light Hyperbolic orthogonality Rapidity Maxwell's equations Proper length Proper time Proper acceleration Relativistic mass
Formulation	Lorentz transformation Textbooks
Phenomena	Time dilation Mass–energy equivalence (E=mc²) Length contraction Relativity of simultaneity Relativistic Doppler effect Thomas precession Ladder paradox Twin paradox Terrell rotation
Spacetime	Light cone World line Minkowski diagram Biquaternions Minkowski space

General
relativity

Background	Introduction Mathematical formulation
Fundamental concepts	Equivalence principle Riemannian geometry Penrose diagram Geodesics Mach's principle
Formulation	ADM formalism BSSN formalism Einstein field equations Linearized gravity Post-Newtonian formalism Raychaudhuri equation Hamilton–Jacobi–Einstein equation Ernst equation
Phenomena	Black hole Event horizon Singularity Two-body problem Gravitational waves: astronomy detectors (LIGO and collaboration Virgo LISA Pathfinder GEO) Hulse–Taylor binary Other tests: precession of Mercury lensing (together with Einstein cross and Einstein rings) redshift Shapiro delay frame-dragging / geodetic effect (Lense–Thirring precession) pulsar timing arrays
Advanced theories	Brans–Dicke theory Kaluza–Klein Quantum gravity
Solutions	Cosmological: Friedmann–Lemaître–Robertson–Walker (Friedmann equations) Lemaître–Tolman Kasner BKL singularity Gödel Milne Spherical: Schwarzschild (interior Tolman–Oppenheimer–Volkoff equation) Reissner–Nordström Axisymmetric: Kerr (Kerr–Newman) Weyl−Lewis−Papapetrou Taub–NUT van Stockum dust discs Others: pp-wave Ozsváth–Schücking Alcubierre In computational physics: Numerical relativity

Scientists

@@ Line 1: / Line 1: @@
 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>
-where <math> \bar{h}_{ij}</math> is the spatial part of the trace reversed perturbation of the metric, i.e. the gravitational wave, and <math>I_{ij}</math> is the mass quadrupole moment.<ref>{{cite book
+where <math> \bar{h}_{ij}</math> is the spatial part of the trace reversed perturbation of the metric, i.e. the gravitational wave.  <math> G </math> is the gravitational constant, <math> c </math> the speed of light in vacuum, and <math>I_{ij}</math> is the mass quadrupole moment.<ref>{{cite book
 |title=Spacetime and Geometry
 |first=Sean M.

Revision as of 09:57, 28 March 2021

References