Gravitational redshift

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The gravitational redshift of a light wave as it moves upwards against a gravitational field (produced by the yellow star below). The effect is greatly exaggerated in this diagram. Gravitational red-shifting2.png
The gravitational redshift of a light wave as it moves upwards against a gravitational field (produced by the yellow star below). The effect is greatly exaggerated in this diagram.

In physics and general relativity, gravitational redshift (known as Einstein shift in older literature) [1] [2] is the phenomenon that electromagnetic waves or photons travelling out of a gravitational well lose energy. This loss of energy corresponds to a decrease in the wave frequency and increase in the wavelength, known more generally as a redshift . The opposite effect, in which photons gain energy when travelling into a gravitational well, is known as a gravitational blueshift (a type of blueshift ). The effect was first described by Einstein in 1907, [3] [4] eight years before his publication of the full theory of relativity.

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Gravitational redshift can be interpreted as a consequence of the equivalence principle (that gravity and acceleration are equivalent and the redshift is caused by the Doppler effect) [5] or as a consequence of the mass–energy equivalence and conservation of energy ('falling' photons gain energy), [6] [7] though there are numerous subtleties that complicate a rigorous derivation. [5] [8] A gravitational redshift can also equivalently be interpreted as gravitational time dilation at the source of the radiation: [8] [2] if two oscillators (attached to transmitters producing electromagnetic radiation) are operating at different gravitational potentials, the oscillator at the higher gravitational potential (farther from the attracting body) will tick faster; that is, when observed from the same location, it will have a higher measured frequency than the oscillator at the lower gravitational potential (closer to the attracting body).

To first approximation, gravitational redshift is proportional to the difference in gravitational potential divided by the speed of light squared, , thus resulting in a very small effect. Light escaping from the surface of the Sun was predicted by Einstein in 1911 to be redshifted by roughly 2 ppm or 2 × 10−6. [9] Navigational signals from GPS satellites orbiting at 20000 km altitude are perceived blueshifted by approximately 0.5 ppb or 5 × 10−10, [10] corresponding to a (negligible) increase of less than 1 Hz in the frequency of a 1.5 GHz GPS radio signal (however, the accompanying gravitational time dilation affecting the atomic clock in the satellite is crucially important for accurate navigation [11] ). On the surface of the Earth the gravitational potential is proportional to height, , and the corresponding redshift is roughly 10−16 (0.1 parts per quadrillion) per meter of change in elevation and/or altitude.

In astronomy, the magnitude of a gravitational redshift is often expressed as the velocity that would create an equivalent shift through the relativistic Doppler effect. In such units, the 2 ppm sunlight redshift corresponds to a 633 m/s receding velocity, roughly of the same magnitude as convective motions in the Sun, thus complicating the measurement. [9] The GPS satellite gravitational blueshift velocity equivalent is less than 0.2 m/s, which is negligible compared to the actual Doppler shift resulting from its orbital velocity. In astronomical objects with strong gravitational fields the redshift can be much greater; for example, light from the surface of a white dwarf is gravitationally redshifted on average by around (50 km/s)/c (around 170 ppm). [12]

Observing the gravitational redshift in the Solar System is one of the classical tests of general relativity. [13] Measuring the gravitational redshift to high precision with atomic clocks can serve as a test of Lorentz symmetry and guide searches for dark matter.

Prediction by the equivalence principle and general relativity

Uniform gravitational field or acceleration

Einstein's theory of general relativity incorporates the equivalence principle, which can be stated in various different ways. One such statement is that gravitational effects are locally undetectable for a free-falling observer. Therefore, in a laboratory experiment at the surface of the Earth, all gravitational effects should be equivalent to the effects that would have been observed if the laboratory had been accelerating through outer space at g. One consequence is a gravitational Doppler effect. If a light pulse is emitted at the floor of the laboratory, then a free-falling observer says that by the time it reaches the ceiling, the ceiling has accelerated away from it, and therefore when observed by a detector fixed to the ceiling, it will be observed to have been Doppler shifted toward the red end of the spectrum. This shift, which the free-falling observer considers to be a kinematical Doppler shift, is thought of by the laboratory observer as a gravitational redshift. Such an effect was verified in the 1959 Pound–Rebka experiment. In a case such as this, where the gravitational field is uniform, the change in wavelength is given by

where is the change in height. Since this prediction arises directly from the equivalence principle, it does not require any of the mathematical apparatus of general relativity, and its verification does not specifically support general relativity over any other theory that incorporates the equivalence principle.

On Earth's surface (or in a spaceship accelerating at 1 g), the gravitational redshift is approximately 1.1×10−16, the equivalent of a 3.3×10−8 m/s Doppler shift for every 1 m of altitude.

Spherically symmetric gravitational field

When the field is not uniform, the simplest and most useful case to consider is that of a spherically symmetric field. By Birkhoff's theorem, such a field is described in general relativity by the Schwarzschild metric, , where is the clock time of an observer at distance R from the center, is the time measured by an observer at infinity, is the Schwarzschild radius , "..." represents terms that vanish if the observer is at rest, is the Newtonian constant of gravitation, the mass of the gravitating body, and the speed of light. The result is that frequencies and wavelengths are shifted according to the ratio

where

This can be related to the redshift parameter conventionally defined as .

In the case where neither the emitter nor the observer is at infinity, the transitivity of Doppler shifts allows us to generalize the result to . The redshift formula for the frequency is . When is small, these results are consistent with the equation given above based on the equivalence principle.

The redshift ratio may also be expressed in terms of a (Newtonian) escape velocity at , resulting in the corresponding Lorentz factor:

.

For an object compact enough to have an event horizon, the redshift is not defined for photons emitted inside the Schwarzschild radius, both because signals cannot escape from inside the horizon and because an object such as the emitter cannot be stationary inside the horizon, as was assumed above. Therefore, this formula only applies when is larger than . When the photon is emitted at a distance equal to the Schwarzschild radius, the redshift will be infinitely large, and it will not escape to any finite distance from the Schwarzschild sphere. When the photon is emitted at an infinitely large distance, there is no redshift.

Newtonian limit

In the Newtonian limit, i.e. when is sufficiently large compared to the Schwarzschild radius , the redshift can be approximated as

where is the gravitational acceleration at . For Earth's surface with respect to infinity, z is approximately 7×10−10 (the equivalent of a 0.2 m/s radial Doppler shift); for the Moon it is approximately 3×10−11 (about 1 cm/s). The value for the surface of the Sun is about 2×10−6, corresponding to 0.64 km/s. (For non-relativistic velocities, the radial Doppler equivalent velocity can be approximated by multiplying z with the speed of light.)

The z-value can be expressed succinctly in terms of the escape velocity at , since the gravitational potential is equal to half the square of the escape velocity, thus:

where is the escape velocity at .

It can also be related to the circular orbit velocity at , which equals , thus

.

For example, the gravitational blueshift of distant starlight due to the Sun's gravity, which the Earth is orbiting at about 30 km/s, would be approximately 1 × 10−8 or the equivalent of a 3 m/s radial Doppler shift.

For an object in a (circular) orbit, the gravitational redshift is of comparable magnitude as the transverse Doppler effect, where β = v/c, while both are much smaller than the radial Doppler effect, for which .

Prediction of the Newtonian limit using the properties of photons

The formula for the gravitational red shift in the Newtonian limit can also be derived using the properties of a photon: [14]

In a gravitational field a particle of mass and velocity changes it's energy according to:

.

For a massless photon described by its energy and momentum this equation becomes after dividing by the Planck constant :

Inserting the gravitational field of a spherical body of mass within the distance

and the wave vector of a photon leaving the gravitational field in radial direction

the energy equation becomes

Using an ordinary differential equation which is only dependent on the radial distance is obtained:

For a photon starting at the surface of a spherical body with a Radius with a frequency the analytical solution is:

In a large distance from the body an observer measures the frequency :

Therefore, the red shift is:

In the linear approximation

the Newtonian limit for the gravitational red shift of General Relativity is obtained.

Experimental verification

Astronomical observations

A number of experimenters initially claimed to have identified the effect using astronomical measurements, and the effect was considered to have been finally identified in the spectral lines of the star Sirius B by W.S. Adams in 1925. [15] However, measurements by Adams have been criticized as being too low [15] [16] and these observations are now considered to be measurements of spectra that are unusable because of scattered light from the primary, Sirius A. [16] The first accurate measurement of the gravitational redshift of a white dwarf was done by Popper in 1954, measuring a 21 km/s gravitational redshift of 40 Eridani B. [16] The redshift of Sirius B was finally measured by Greenstein et al. in 1971, obtaining the value for the gravitational redshift of 89±16 km/s, with more accurate measurements by the Hubble Space Telescope, showing 80.4±4.8 km/s. [17] [ citation needed ]

James W. Brault, a graduate student of Robert Dicke at Princeton University, measured the gravitational redshift of the sun using optical methods in 1962. [18] In 2020, a team of scientists published the most accurate measurement of the solar gravitational redshift so far, made by analyzing Fe spectral lines in sunlight reflected by the Moon; their measurement of a mean global 638 ± 6 m/s lineshift is in agreement with the theoretical value of 633.1 m/s. [19] [20] Measuring the solar redshift is complicated by the Doppler shift caused by the motion of the Sun's surface, which is of similar magnitude as the gravitational effect. [20]

In 2011, the group of Radek Wojtak of the Niels Bohr Institute at the University of Copenhagen collected data from 8000 galaxy clusters and found that the light coming from the cluster centers tended to be red-shifted compared to the cluster edges, confirming the energy loss due to gravity. [21]

In 2018, the star S2 made its closest approach to Sgr A*, the 4-million solar mass supermassive black hole at the centre of the Milky Way, reaching 7650 km/s or about 2.5% of the speed of light while passing the black hole at a distance of just 120 AU, or 1400 Schwarzschild radii. Independent analyses by the GRAVITY collaboration [22] [23] [24] [25] (led by Reinhard Genzel) and the KECK/UCLA Galactic Center Group [26] [27] (led by Andrea Ghez) revealed a combined transverse Doppler and gravitational redshift up to 200 km/s/c, in agreement with general relativity predictions.

In 2021, Mediavilla (IAC, Spain) & Jiménez-Vicente (UGR, Spain) were able to use measurements of the gravitational redshift in quasars up to cosmological redshift of z ≈ 3 to confirm the predictions of Einstein's equivalence principle and the lack of cosmological evolution within 13%. [28]

In 2024, Padilla et al. have estimated the gravitational redshifts of supermassive black holes (SMBH) in eight thousand quasars and one hundred Seyfert type 1 galaxies from the full width at half maximum (FWHM) of their emission lines, finding log z ≈ −4, compatible with SMBHs of ~ 1 billion solar masses and broadline regions of ~ 1 parsec radius. This same gravitational redshift was directly measured by these authors in the SAMI sample of LINER galaxies, using the redshift differences between lines emitted in central and outer regions. [29]

Terrestrial tests

The effect is now considered to have been definitively verified by the experiments of Pound, Rebka and Snider between 1959 and 1965. The Pound–Rebka experiment of 1959 measured the gravitational redshift in spectral lines using a terrestrial 57Fe gamma source over a vertical height of 22.5 metres. [30] This paper was the first determination of the gravitational redshift which used measurements of the change in wavelength of gamma-ray photons generated with the Mössbauer effect, which generates radiation with a very narrow line width. The accuracy of the gamma-ray measurements was typically 1%.

An improved experiment was done by Pound and Snider in 1965, with an accuracy better than the 1% level. [31]

A very accurate gravitational redshift experiment was performed in 1976, [32] where a hydrogen maser clock on a rocket was launched to a height of 10000 km, and its rate compared with an identical clock on the ground. It tested the gravitational redshift to 0.007%.

Later tests can be done with the Global Positioning System (GPS), which must account for the gravitational redshift in its timing system, and physicists have analyzed timing data from the GPS to confirm other tests. When the first satellite was launched, it showed the predicted shift of 38 microseconds per day. This rate of the discrepancy is sufficient to substantially impair the function of GPS within hours if not accounted for. An excellent account of the role played by general relativity in the design of GPS can be found in Ashby 2003. [33]

In 2010, an experiment placed two aluminum-ion quantum clocks close to each other, but with the second elevated 33 cm compared to the first, making the gravitational red shift effect visible in everyday lab scales. [34] [35]

In 2020, a group at the University of Tokyo measured the gravitational redshift of two strontium-87 optical lattice clocks. [36] The measurement took place at Tokyo Skytree where the clocks were separated by approximately 450 m and connected by telecom fibers. The gravitational redshift can be expressed as

,

where is the gravitational redshift, is the optical clock transition frequency, is the difference in gravitational potential, and denotes the violation from general relativity. By Ramsey spectroscopy of the strontium-87 optical clock transition (429 THz, 698 nm) the group determined the gravitational redshift between the two optical clocks to be 21.18 Hz, corresponding to a z-value of approximately 5 × 10−14. Their measured value of , , is an agreement with recent measurements made with hydrogen masers in elliptical orbits. [37] [38]

In October 2021, a group at JILA led by physicist Jun Ye reported a measurement of gravitational redshift in the submillimeter scale. The measurement is done on the 87Sr clock transition between the top and the bottom of a millimeter-tall ultracold cloud of 100,000 strontium atoms in an optical lattice. [39] [40]

Early historical development of the theory

The gravitational weakening of light from high-gravity stars was predicted by John Michell in 1783 and Pierre-Simon Laplace in 1796, using Isaac Newton's concept of light corpuscles (see: emission theory) and who predicted that some stars would have a gravity so strong that light would not be able to escape. The effect of gravity on light was then explored by Johann Georg von Soldner (1801), who calculated the amount of deflection of a light ray by the Sun, arriving at the Newtonian answer which is half the value predicted by general relativity. All of this early work assumed that light could slow down and fall, which is inconsistent with the modern understanding of light waves.

Once it became accepted that light was an electromagnetic wave, it was clear that the frequency of light should not change from place to place, since waves from a source with a fixed frequency keep the same frequency everywhere. One way around this conclusion would be if time itself were altered  if clocks at different points had different rates. This was precisely Einstein's conclusion in 1911. [41] He considered an accelerating box, and noted that according to the special theory of relativity, the clock rate at the "bottom" of the box (the side away from the direction of acceleration) was slower than the clock rate at the "top" (the side toward the direction of acceleration). Indeed, in a frame moving (in direction) with velocity relative to the rest frame, the clocks at a nearby position are ahead by (to the first order); so an acceleration (that changes speed by per time ) makes clocks at the position to be ahead by , that is, tick at a rate

The equivalence principle implies that this change in clock rate is the same whether the acceleration is that of an accelerated frame without gravitational effects, or caused by a gravitational field in a stationary frame. Since acceleration due to gravitational potential is , we get

so – in weak fields – the change in the clock rate is equal to .

Since the light would be slowed down by gravitational time dilation (as seen by outside observer), the regions with lower gravitational potential would act like a medium with higher refractive index causing light to deflect. This reasoning allowed Einstein in 1911 to reproduce the incorrect Newtonian value for the deflection of light. [41] At the time he only considered the time-dilating manifestation of gravity, which is the dominating contribution at non-relativistic speeds; however relativistic objects travel through space a comparable amount as they do though time, so purely spatial curvature becomes just as important. After constructing the full theory of general relativity, Einstein solved in 1915 [42] the full post-Newtonian approximation for the Sun's gravity and calculated the correct amount of light deflection – double the Newtonian value. Einstein's prediction was confirmed by many experiments, starting with Arthur Eddington's 1919 solar eclipse expedition.

The changing rates of clocks allowed Einstein to conclude that light waves change frequency as they move, and the frequency/energy relationship for photons allowed him to see that this was best interpreted as the effect of the gravitational field on the mass–energy of the photon. To calculate the changes in frequency in a nearly static gravitational field, only the time component of the metric tensor is important, and the lowest order approximation is accurate enough for ordinary stars and planets, which are much bigger than their Schwarzschild radius.

See also

Citations

  1. "Einstein shift definition and meaning | Collins English Dictionary". www.collinsdictionary.com. Retrieved 2021-01-21.
  2. 1 2 Eddington, A. S. (1926). "Einstein Shift and Doppler Shift". Nature. 117 (2933): 86. Bibcode:1926Natur.117...86E. doi: 10.1038/117086a0 . ISSN   1476-4687. S2CID   4092843.
  3. Einstein, Albert (1907). "Relativitätsprinzip und die aus demselben gezogenen Folgerungen" [On the Relativity Principle and the Conclusions Drawn from It](PDF). Jahrbuch der Radioaktivität (4): 411–462.
  4. Valente, Mário Bacelar (2018-12-06). "Einstein's redshift derivations: its history from 1907 to 1921". Circumscribere: International Journal for the History of Science. 22: 1–16. doi: 10.23925/1980-7651.2018v22;1-16 . ISSN   1980-7651. S2CID   239568887.
  5. 1 2 Florides, Petros S. "Einstein's Equivalence Principle and the Gravitational Red Shift" (PDF). School of Mathematics, Trinity College, Ireland.
  6. Chang, Donald C. (2018). "A quantum mechanical interpretation of gravitational redshift of electromagnetic wave". Optik. 174: 636–641. doi:10.1016/j.ijleo.2018.08.127. S2CID   126341445.
  7. Evans, R. F.; Dunning-Davies, J. (2004). "The Gravitational Red-Shift". arXiv: gr-qc/0403082 .
  8. 1 2 Scott, Robert B (2015). Teaching the gravitational redshift: lessons from the history and philosophy of physics. Spanish Relativity Meeting (ERE 2014). Journal of Physics: Conference Series. Vol. 600, no. 1. p. 012055. Bibcode:2015JPhCS.600a2055S. doi: 10.1088/1742-6596/600/1/012055 .
  9. 1 2 Gräfe, Franziska (23 October 2020). "New study verifies prediction from Einstein's General Theory of Relativity — English". Leibniz Institute for Astrophysics Potsdam. Retrieved 2021-01-14.
  10. Ashby, Neil (July 20–21, 2006). "Relativity in the Global Positioning System". American Association of Physics Teachers. Retrieved 2021-01-14.
  11. Ashby, Neil (2003). "Relativity in the Global Positioning System". Living Reviews in Relativity. 6 (1): 1. Bibcode:2003LRR.....6....1A. doi: 10.12942/lrr-2003-1 . ISSN   1433-8351. PMC   5253894 . PMID   28163638.
  12. Trimble, Virginia; Barstow, Martin (November 2020). "Gravitational redshift and White Dwarf stars". Einstein Online . Max Planck Institute for Gravitational Physics . Retrieved 2021-01-16.
  13. Alley, Carrol Overton. "GPS Setup Showed General Relativistic Effects on Light Operate at Emission and Reception, Not In-Flight as Required by Big Bang's Friedman-Lemaitre Spacetime Expansion Paradigm" (PDF). The Orion Foundation.
  14. A. Malcherek: Elektromagnetismus und Gravitation, Vereinheitlichung und Erweiterung der klassischen Physik. 2. Edition, Springer-Vieweg, Wiesbaden, 2023, ISBN 978-3-658-42701-6. doi:10.1007/978-3-658-42702-3
  15. 1 2 Hetherington, N. S., "Sirius B and the gravitational redshift - an historical review", Quarterly Journal Royal Astronomical Society, vol. 21, Sept. 1980, pp. 246–252. Accessed 6 April 2017.
  16. 1 2 3 Holberg, J. B., "Sirius B and the Measurement of the Gravitational Redshift", Journal for the History of Astronomy, vol. 41, 1, 2010, pp. 41–64. Accessed 6 April 2017.
  17. Effective Temperature, Radius, and Gravitational Redshift of Sirius B, J. L. Greenstein, J.B. Oke, H. L. Shipman, Astrophysical Journal169 (Nov. 1, 1971), pp. 563566.
  18. Brault, James W. (1962). The Gravitational Redshift in the Solar Spectrum (PhD). ProQuest   302083560 via ProQuest.
  19. Hernández, J. I. González; Rebolo, R.; Pasquini, L.; Curto, G. Lo; Molaro, P.; Caffau, E.; Ludwig, H.-G.; Steffen, M.; Esposito, M.; Mascareño, A. Suárez; Toledo-Padrón, B. (2020-11-01). "The solar gravitational redshift from HARPS-LFC Moon spectra - A test of the general theory of relativity". Astronomy & Astrophysics. 643: A146. arXiv: 2009.10558 . Bibcode:2020A&A...643A.146G. doi:10.1051/0004-6361/202038937. ISSN   0004-6361. S2CID   221836649.
  20. 1 2 Smith, Keith T. (2020-12-18). "Editors' Choice". Science. 370 (6523): 1429–1430. Bibcode:2020Sci...370Q1429S. doi: 10.1126/science.2020.370.6523.twil . ISSN   0036-8075. Gravitational redshift of the Sun
  21. Bhattacharjee, Yudhijit (2011). "Galaxy Clusters Validate Einstein's Theory". News.sciencemag.org. Retrieved 2013-07-23.
  22. Abuter, R.; Amorim, A.; Anugu, N.; Bauböck, M.; Benisty, M.; Berger, J. P.; Blind, N.; Bonnet, H.; Brandner, W.; Buron, A.; Collin, C. (2018-07-01). "Detection of the gravitational redshift in the orbit of the star S2 near the Galactic centre massive black hole". Astronomy & Astrophysics. 615: L15. arXiv: 1807.09409 . Bibcode:2018A&A...615L..15G. doi:10.1051/0004-6361/201833718. ISSN   0004-6361. S2CID   118891445.
  23. Witze, Alexandra (2018-07-26). "Milky Way's black hole provides long-sought test of Einstein's general relativity". Nature. 560 (7716): 17. Bibcode:2018Natur.560...17W. doi: 10.1038/d41586-018-05825-3 . PMID   30065325. S2CID   51888156.
  24. "Tests of General Relativity". www.mpe.mpg.de. Retrieved 2021-01-17.
  25. "First Successful Test of Einstein's General Relativity Near Supermassive Black Hole - Culmination of 26 years of ESO observations of the heart of the Milky Way". www.eso.org. Retrieved 2021-01-17.
  26. Do, Tuan; Hees, Aurelien; Ghez, Andrea; Martinez, Gregory D.; Chu, Devin S.; Jia, Siyao; Sakai, Shoko; Lu, Jessica R.; Gautam, Abhimat K.; O’Neil, Kelly Kosmo; Becklin, Eric E. (2019-08-16). "Relativistic redshift of the star S0-2 orbiting the Galactic center supermassive black hole". Science. 365 (6454): 664–668. arXiv: 1907.10731 . Bibcode:2019Sci...365..664D. doi:10.1126/science.aav8137. ISSN   0036-8075. PMID   31346138. S2CID   198901506.
  27. Siegel, Ethan (2019-08-01). "General Relativity Rules: Einstein Victorious In Unprecedented Gravitational Redshift Test". Medium. Retrieved 2021-01-17.
  28. Mediavilla, E.; Jiménez-Vicente, J. (2021). "Testing Einstein's Equivalence Principle and Its Cosmological Evolution from Quasar Gravitational Redshifts". The Astrophysical Journal. 914 (2): 112. arXiv: 2106.11699 . Bibcode:2021ApJ...914..112M. doi: 10.3847/1538-4357/abfb70 . S2CID   235593322.
  29. N. D. Padilla; S. Carneiro; J. Chaves-Montero; C. J. Donzelli; C. Pigozzo; P. Colazo; J. S. Alcaniz (2024). "Active galactic nuclei and gravitational redshifts". Astronomy and Astrophysics. 683: 120–126. arXiv: 2304.13036 . Bibcode:2024A&A...683A.120P. doi:10.1051/0004-6361/202348146.
  30. Pound, R.; Rebka, G. (1960). "Apparent Weight of Photons". Physical Review Letters. 4 (7): 337–341. Bibcode:1960PhRvL...4..337P. doi: 10.1103/PhysRevLett.4.337 .
  31. Pound, R. V.; Snider J. L. (November 2, 1964). "Effect of Gravity on Nuclear Resonance". Physical Review Letters . 13 (18): 539–540. Bibcode:1964PhRvL..13..539P. doi: 10.1103/PhysRevLett.13.539 .
  32. Vessot, R. F. C.; M. W. Levine; E. M. Mattison; E. L. Blomberg; T. E. Hoffman; G. U. Nystrom; B. F. Farrel; R. Decher; et al. (December 29, 1980). "Test of Relativistic Gravitation with a Space-Borne Hydrogen Maser". Physical Review Letters. 45 (26): 2081–2084. Bibcode:1980PhRvL..45.2081V. doi:10.1103/PhysRevLett.45.2081.
  33. Ashby, Neil (2003). "Relativity in the Global Positioning System". Living Reviews in Relativity. 6 (1): 1. Bibcode:2003LRR.....6....1A. doi: 10.12942/lrr-2003-1 . PMC   5253894 . PMID   28163638.
  34. Chou, C.W.; Hume, D.B.; Rosenband, T.; Wineland, D.J. (2010). "Optical Clocks and Relativity". Science. 329 (5999): 1630–1633. Bibcode:2010Sci...329.1630C. doi:10.1126/science.1192720. PMID   20929843. S2CID   125987464.
  35. "Einstein's time dilation apparent when obeying the speed limit" (Press release). Ars Technica. 24 September 2010. Retrieved 2015-04-10.
  36. Takamoto, M.; Ushijima, I.; Ohmae, N.; et al. (6 April 2020). "Test of general relativity by a pair of transportable optical lattice clocks". Nat. Photonics. 14 (7): 411–415. Bibcode:2020NaPho..14..411T. doi:10.1038/s41566-020-0619-8. S2CID   216309660.
  37. Sven Herrmann; Felix Finke; Martin Lülf; Olga Kichakova; Dirk Puetzfeld; Daniela Knickmann; Meike List; Benny Rievers; Gabriele Giorgi; Christoph Günther; Hansjörg Dittus; Roberto Prieto-Cerdeira; Florian Dilssner; Francisco Gonzalez; Erik Schönemann; Javier Ventura-Traveset; Claus Lämmerzahl (December 2018). "Test of the Gravitational Redshift with Galileo Satellites in an Eccentric Orbit". Physical Review Letters. 121 (23): 231102. arXiv: 1812.09161 . Bibcode:2018PhRvL.121w1102H. doi:10.1103/PhysRevLett.121.231102. PMID   30576165. S2CID   58537350.
  38. P. Delva; N. Puchades; E. Schönemann; F. Dilssner; C. Courde; S. Bertone; F. Gonzalez; A. Hees; Ch. Le Poncin-Lafitte; F. Meynadier; R. Prieto-Cerdeira; B. Sohet; J. Ventura-Traveset; P. Wolf (December 2018). "Gravitational Redshift Test Using Eccentric Galileo Satellites". Physical Review Letters. 121 (23): 231101. arXiv: 1812.03711 . Bibcode:2018PhRvL.121w1101D. doi:10.1103/PhysRevLett.121.231101. PMID   30576203. S2CID   58666075.
  39. Bothwell, Tobias; Kennedy, Colin J.; Aeppli, Alexander; Kedar, Dhruv; Robinson, John M.; Oelker, Eric; Staron, Alexander; Ye, Jun (2022). "Resolving the gravitational redshift across a millimetre-scale atomic sample" (PDF). Nature. 602 (7897): 420–424. arXiv: 2109.12238 . Bibcode:2022Natur.602..420B. doi:10.1038/s41586-021-04349-7. PMID   35173346. S2CID   237940816.
  40. McCormick, Katie (2021-10-25). "An Ultra-Precise Clock Shows How to Link the Quantum World With Gravity". Quanta Magazine. Retrieved 2021-10-29.
  41. 1 2 Einstein, A. (1911). "On the Influence of Gravitation on the Propagation of Light". Annalen der Physik. 35 (10): 898–908. Bibcode:1911AnP...340..898E. doi:10.1002/andp.19113401005.
  42. "Explanation of the Perihelion Motion of Mercury from the General Theory of Relativity".

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The Kerr metric or Kerr geometry describes the geometry of empty spacetime around a rotating uncharged axially symmetric black hole with a quasispherical event horizon. The Kerr metric is an exact solution of the Einstein field equations of general relativity; these equations are highly non-linear, which makes exact solutions very difficult to find.

<span class="mw-page-title-main">Proper time</span> Elapsed time between two events as measured by a clock that passes through both events

In relativity, proper time along a timelike world line is defined as the time as measured by a clock following that line. The proper time interval between two events on a world line is the change in proper time, which is independent of coordinates, and is a Lorentz scalar. The interval is the quantity of interest, since proper time itself is fixed only up to an arbitrary additive constant, namely the setting of the clock at some event along the world line.

Gravitational time dilation is a form of time dilation, an actual difference of elapsed time between two events, as measured by observers situated at varying distances from a gravitating mass. The lower the gravitational potential, the slower time passes, speeding up as the gravitational potential increases. Albert Einstein originally predicted this in his theory of relativity, and it has since been confirmed by tests of general relativity.

In physics, the Brans–Dicke theory of gravitation is a competitor to Einstein's general theory of relativity. It is an example of a scalar–tensor theory, a gravitational theory in which the gravitational interaction is mediated by a scalar field as well as the tensor field of general relativity. The gravitational constant is not presumed to be constant but instead is replaced by a scalar field which can vary from place to place and with time.

<span class="mw-page-title-main">Friedmann equations</span> Equations in physical cosmology

The Friedmann equations, also known as the Friedmann–Lemaître (FL) equations, are a set of equations in physical cosmology that govern cosmic expansion in homogeneous and isotropic models of the universe within the context of general relativity. They were first derived by Alexander Friedmann in 1922 from Einstein's field equations of gravitation for the Friedmann–Lemaître–Robertson–Walker metric and a perfect fluid with a given mass density ρ and pressure p. The equations for negative spatial curvature were given by Friedmann in 1924.

The Kerr–Newman metric describes the spacetime geometry around a mass which is electrically charged and rotating. It is a vacuum solution which generalizes the Kerr metric by additionally taking into account the energy of an electromagnetic field, making it the most general asymptotically flat and stationary solution of the Einstein–Maxwell equations in general relativity. As an electrovacuum solution, it only includes those charges associated with the magnetic field; it does not include any free electric charges.

<span class="mw-page-title-main">Sagnac effect</span> Relativistic effect due to rotation

The Sagnac effect, also called Sagnac interference, named after French physicist Georges Sagnac, is a phenomenon encountered in interferometry that is elicited by rotation. The Sagnac effect manifests itself in a setup called a ring interferometer or Sagnac interferometer. A beam of light is split and the two beams are made to follow the same path but in opposite directions. On return to the point of entry the two light beams are allowed to exit the ring and undergo interference. The relative phases of the two exiting beams, and thus the position of the interference fringes, are shifted according to the angular velocity of the apparatus. In other words, when the interferometer is at rest with respect to a nonrotating frame, the light takes the same amount of time to traverse the ring in either direction. However, when the interferometer system is spun, one beam of light has a longer path to travel than the other in order to complete one circuit of the mechanical frame, and so takes longer, resulting in a phase difference between the two beams. Georges Sagnac set up this experiment in 1913 in an attempt to prove the existence of the aether that Einstein's theory of special relativity makes superfluous.

<span class="mw-page-title-main">Pound–Rebka experiment</span> Test of gravitational redshift

The Pound–Rebka experiment monitored frequency shifts in gamma rays as they rose and fell in the gravitational field of the Earth. The experiment tested Albert Einstein's 1907 and 1911 predictions, based on the equivalence principle, that photons would gain energy when descending a gravitational potential, and would lose energy when rising through a gravitational potential. It was proposed by Robert Pound and his graduate student Glen A. Rebka Jr. in 1959, and was the last of the classical tests of general relativity to be verified. The measurement of gravitational redshift and blueshift by this experiment validated the prediction of the equivalence principle that clocks should be measured as running at different rates in different places of a gravitational field. It is considered to be the experiment that ushered in an era of precision tests of general relativity.

In theoretical physics, Nordström's theory of gravitation was a predecessor of general relativity. Strictly speaking, there were actually two distinct theories proposed by the Finnish theoretical physicist Gunnar Nordström, in 1912 and 1913 respectively. The first was quickly dismissed, but the second became the first known example of a metric theory of gravitation, in which the effects of gravitation are treated entirely in terms of the geometry of a curved spacetime.

Alternatives to general relativity are physical theories that attempt to describe the phenomenon of gravitation in competition with Einstein's theory of general relativity. There have been many different attempts at constructing an ideal theory of gravity.

<span class="mw-page-title-main">Distance measure</span> Definitions for distance between two objects or events in the universe

Distance measures are used in physical cosmology to give a natural notion of the distance between two objects or events in the universe. They are often used to tie some observable quantity to another quantity that is not directly observable, but is more convenient for calculations. The distance measures discussed here all reduce to the common notion of Euclidean distance at low redshift.

The two-body problem in general relativity is the determination of the motion and gravitational field of two bodies as described by the field equations of general relativity. Solving the Kepler problem is essential to calculate the bending of light by gravity and the motion of a planet orbiting its sun. Solutions are also used to describe the motion of binary stars around each other, and estimate their gradual loss of energy through gravitational radiation.

In general relativity, Lense–Thirring precession or the Lense–Thirring effect is a relativistic correction to the precession of a gyroscope near a large rotating mass such as the Earth. It is a gravitomagnetic frame-dragging effect. It is a prediction of general relativity consisting of secular precessions of the longitude of the ascending node and the argument of pericenter of a test particle freely orbiting a central spinning mass endowed with angular momentum .

A synchronous frame is a reference frame in which the time coordinate defines proper time for all co-moving observers. It is built by choosing some constant time hypersurface as an origin, such that has in every point a normal along the time line and a light cone with an apex in that point can be constructed; all interval elements on this hypersurface are space-like. A family of geodesics normal to this hypersurface are drawn and defined as the time coordinates with a beginning at the hypersurface. In terms of metric-tensor components , a synchronous frame is defined such that

<span class="mw-page-title-main">Baryon acoustic oscillations</span> Fluctuations in the density of the normal matter of the universe

In cosmology, baryon acoustic oscillations (BAO) are fluctuations in the density of the visible baryonic matter of the universe, caused by acoustic density waves in the primordial plasma of the early universe. In the same way that supernovae provide a "standard candle" for astronomical observations, BAO matter clustering provides a "standard ruler" for length scale in cosmology. The length of this standard ruler is given by the maximum distance the acoustic waves could travel in the primordial plasma before the plasma cooled to the point where it became neutral atoms, which stopped the expansion of the plasma density waves, "freezing" them into place. The length of this standard ruler can be measured by looking at the large scale structure of matter using astronomical surveys. BAO measurements help cosmologists understand more about the nature of dark energy by constraining cosmological parameters.

In astrophysics, the virial mass is the mass of a gravitationally bound astrophysical system, assuming the virial theorem applies. In the context of galaxy formation and dark matter halos, the virial mass is defined as the mass enclosed within the virial radius of a gravitationally bound system, a radius within which the system obeys the virial theorem. The virial radius is determined using a "top-hat" model. A spherical "top hat" density perturbation destined to become a galaxy begins to expand, but the expansion is halted and reversed due to the mass collapsing under gravity until the sphere reaches equilibrium – it is said to be virialized. Within this radius, the sphere obeys the virial theorem which says that the average kinetic energy is equal to minus one half times the average potential energy, , and this radius defines the virial radius.

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