McCullagh's parametrization of the Cauchy distributions

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The parameterized post-Newtonian formalism or PPN formalism is a version of this formulation that explicitly details the parameters in which a general theory of gravity can differ from Newtonian gravity. It is used as a tool to compare Newtonian and Einsteinian gravity in the limit in which the gravitational field is weak and generated by objects moving slowly compared to the speed of light. In general, PPN formalism can be applied to all metric theories of gravitation in which all bodies satisfy the Einstein equivalence principle (EEP). The speed of light remains constant in PPN formalism and it assumes that the metric tensor is always symmetric.

History

The earliest parameterizations of the post-Newtonian approximation were performed by Sir Arthur Stanley Eddington in 1922. However, they dealt solely with the vacuum gravitational field outside an isolated spherical body. Dr. Ken Nordtvedt (1968, 1969) expanded this to include 7 parameters. Clifford Martin Will (1971) introduced a stressed, continuous matter description of celestial bodies.

The versions described here are based on Wei-Tou Ni (1972), Will and Nordtvedt (1972), Charles W. Misner et al. (1973) (see Gravitation (book)), and Will (1981, 1993) and have 10 parameters.

Beta-delta notation

Ten post-Newtonian parameters completely characterize the weak-field behavior of the theory. The formalism has been a valuable tool in tests of general relativity. In the notation of Will (1971), Ni (1972) and Misner et al. (1973) they have the following values:

γ How much space curvature gij is produced by unit rest mass ?
β How much nonlinearity is there in the superposition law for gravity g00 ?
β1 How much gravity is produced by unit kinetic energy 12ρ0v2 ?
β2 How much gravity is produced by unit gravitational potential energy ρ0/U ?
β3 How much gravity is produced by unit internal energy ρ0Π ?
β4 How much gravity is produced by unit pressure p ?
ζ Difference between radial and transverse kinetic energy on gravity
η Difference between radial and transverse stress on gravity
Δ1 How much dragging of inertial frames g0j is produced by unit momentum ρ0v ?
Δ2 Difference between radial and transverse momentum on dragging of inertial frames

gμν is the 4 by 4 symmetric metric tensor and indexes i and j go from 1 to 3.

In Einstein's theory, the values of these parameters are chosen (1) to fit Newton's Law of gravity in the limit of velocities and mass approaching zero, (2) to ensure conservation of energy, mass, momentum, and angular momentum, and (3) to make the equations independent of the reference frame. In this notation, general relativity has PPN parameters γ=β=β1=β2=β3=β4=Δ1=Δ2=1 and ζ=η=0

Alpha-zeta notation

In the more recent notation of Will & Nordtvedt (1972) and Will (1981, 1993, 2006) a different set of ten PPN parameters is used.

γ=γ
β=β
α1=7Δ1+Δ24γ4
α2=Δ2+ζ1
α3=4β12γ2ζ
ζ1=ζ
ζ2=2β+2β23γ1
ζ3=β31
ζ4=β4γ
ξ is calculated from 3η=12β3γ9+10ξ3α1+2α22ζ1ζ2

The meaning of these is that α1, α2 and α3 measure the extent of preferred frame effects. ζ1, ζ2, ζ3, ζ4 and α3 measure the failure of conservation of energy, momentum and angular momentum.

In this notation, general relativity has PPN parameters

γ=β=1 and α1=α2=α3=ζ1=ζ2=ζ3=ζ4=ξ=0

The mathematical relationship between the metric, metric potentials and PPN parameters for this notation is:

g00=1+2U2βU22ξΦW+(2γ+2+α3+ζ12ξ)Φ1+2(3γ2β+1+ζ2+ξ)Φ2+2(1+ζ3)Φ3+2(3γ+3ζ42ξ)Φ4(ζ12ξ)A(α1α2α3)w2Uα2wiwjUij+(2α3α1)wiVi+O(ϵ3)
g0i=12(4γ+3+α1α2+ζ12ξ)Vi12(1+α2ζ1+2ξ)Wi12(α12α2)wiUα2wjUij+O(ϵ52)
gij=(1+2γU)δij+O(ϵ2)

where repeated indexes are summed. ϵ is on the order of potentials such as U, the square magnitude of the coordinate velocities of matter, etc. wi is the velocity vector of the PPN coordinate system relative to the mean rest-frame of the universe. w2=wiwjδij is the square magnitude of that velocity. δij=1 if and only if i=j, 0 otherwise.

There are ten metric potentials, U, Uij, ΦW, A, Φ1, Φ2, Φ3, Φ4, Vi and Wi, one for each PPN parameter to ensure a unique solution. 10 linear equations in 10 unknowns are solved by inverting a 10 by 10 matrix. These metric potentials have forms such as:

U=ρ0|xx|d3x

which is simply another way of writing the Newtonian gravitational potential.

A full list of metric potentials can be found in Misner et al. (1973), Will (1981, 1993, 2006) and in many other places.

How to apply PPN

Examples of the process of applying PPN formalism to alternative theories of gravity can be found in Will (1981, 1993). It is a nine step process:

  • Step 1: Identify the variables, which may include: (a) dynamical gravitational variables such as the metric gμν, scalar field ϕ, vector field Kμ, tensor field Bμν and so on; (b) prior-geometrical variables such as a flat background metric ημν, cosmic time function t, and so on; (c) matter and non-gravitational field variables.
  • Step 2: Set the cosmological boundary conditions. Assume a homogeneous isotropic cosmology, with isotropic coordinates in the rest frame of the universe. A complete cosmological solution may or may not be needed. Call the results gμν(0)=diag(c0,c1,c1,c1), ϕ0, Kμ(0), Bμν(0).
  • Step 4: Substitute these forms into the field equations, keeping only such terms as are necessary to obtain a final consistent solution for hμν. Substitute the perfect fluid stress tensor for the matter sources.
  • Step 5: Solve for h00 to O(2). Assuming this tends to zero far from the system, one obtains the form h00=2αU where U is the Newtonian gravitational potential and α may be a complicated function including the gravitational "constant" G. The Newtonian metric has the form g00=c0+2αU, g0j=0, gij=δijc1. Work in units where the gravitational "constant" measured today far from gravitating matter is unity so set Gtoday=α/c0c1=1.
  • Step 6: From linearized versions of the field equations solve for hij to O(2) and h0j to O(3).
  • Step 7: Solve for h00 to O(4). This is the messiest step, involving all the nonlinearities in the field equations. The stress-energy tensor must also be expanded to sufficient order.
  • Step 8: Convert to local quasi-Cartesian coordinates and to standard PPN gauge.

Comparisons between theories of gravity

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A table comparing PPN parameters for 23 theories of gravity can be found in Alternatives to general relativity#PPN parameters for a range of theories.

Most metric theories of gravity can be lumped into categories. Scalar theories of gravitation include conformally flat theories and stratified theories with time-orthogonal space slices.

In conformally flat theories such as Nordström's theory of gravitation the metric is given by g=fη and for this metric γ=1, which violently disagrees with observations. In stratified theories such as Yilmaz theory of gravitation the metric is given by g=f1dtdt+f2η and for this metric α1=4(γ+1), which also disagrees violently with observations.

Another class of theories is the quasilinear theories such as Whitehead's theory of gravitation. For these ξ=β. The relative magnitudes of the harmonics of the Earth's tides depend on ξ and α2, and measurements show that quasilinear theories disagree with observations of Earth's tides.

Another class of metric theories is the bimetric theory. For all of these α2 is non-zero. From the precession of the solar spin we know that α2<4×107, and that effectively rules out bimetric theories.

Another class of metric theories is the scalar tensor theories, such as Brans-Dicke theory. For all of these, γ=1+ω2+ω. The limit of γ1<2.3×105 means that ω would have to be very large, so these theories are looking less and less likely as experimental accuracy improves.

The final main class of metric theories is the vector-tensor theories. For all of these the gravitational "constant" varies with time and α2 is non-zero. Lunar laser ranging experiments tightly constrain the variation of the gravitational "constant" with time and α2<4×107, so these theories are also looking unlikely.

There are some metric theories of gravity that do not fit into the above categories, but they have similar problems.

Accuracy from experimental tests

Bounds on the PPN parameters Will (2006)

Parameter Bound Effects Experiment
γ1 2.3 x 105 Time delay, Light deflection Cassini tracking
β1 3 x 103 Perihelion shift Perihelion shift
β1 2.3 x 104 Nordtvedt effect with assumption ηN=4βγ3 Nordtvedt effect
ξ 0.001 Earth tides Gravimeter data
α1 104 Orbit polarization Lunar laser ranging
α2 4 x 107 Spin precession Sun axis' alignment with ecliptic
α3 4 x 1020 Self-acceleration Pulsar spin-down statistics
ηN 9 x 104 Nordtvedt effect Lunar Laser Ranging
ζ1 0.02 - Combined PPN bounds
ζ2 4 x 105 Binary pulsar acceleration PSR 1913+16
ζ3 108 Newton's 3rd law Lunar acceleration
ζ4 0.006 - Kreuzer experiment

† Will, C.M., Is momentum conserved? A test in the binary system PSR 1913 + 16, Astrophysical Journal, Part 2 - Letters (ISSN 0004-637X), vol. 393, no. 2, July 10, 1992, p. L59-L61.

‡ Based on 6ζ4=3α3+2ζ13ζ3 from Will (1976, 2006). It is theoretically possible for an alternative model of gravity to bypass this bound, in which case the bound is |ζ4|<0.4 from Ni (1972).

References

  • Eddington, A. S. (1922) The Mathematical Theory of Relativity, Cambridge University Press.
  • Misner, C. W., Thorne, K. S. & Wheeler, J. A. (1973) Gravitation, W. H. Freeman and Co.
  • Nordtvedt Jr, K. (1968) Equivalence principle for massive bodies II: Theory, Phys. Rev. 169, 1017-1025.
  • Nordtvedt Jr, K. (1969) Equivalence principle for massive bodies including rotational energy and radiation pressure, Phys. Rev. 180, 1293-1298.
  • Will, C. M. (1971) Theoretical frameworks for testing relativistic gravity II: Parameterized post-Newtonian hydrodynamics and the Nordtvedt effect, Astrophys. J. 163, 611-628.
  • Will, C. M. (1976) Active mass in relativistic gravity: Theoretical interpretation of the Kreuzer experiment, Astrophys. J., 204, 224-234.
  • Will, C. M. (1981, 1993) Theory and Experiment in Gravitational Physics, Cambridge University Press. ISBN 0-521-43973-6.
  • Will, C. M., (2006) The Confrontation between General Relativity and Experiment, http://relativity.livingreviews.org/Articles/lrr-2006-3/
  • Will, C. M., and Nordtvedt Jr., K (1972) Conservation laws and preferred frames in relativistic gravity I, The Astrophysical Journal 177, 757.

See also

Template:Theories of gravitation Template:Relativity