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arXiv:gr-qc/0305076v4 10 Jun 2003
Chapter 1
ISOTROPY OF THE VELOCITY OF LIGHT AND THE SAGNAC EFFECT
J.-F. Pascual-Sa´nchez A. San Miguel F. Vicente
Dept. Matem´atica Aplicada Fundamental Seccio´n Facultad de Ciencias Universidad de Valladolid 47005, Valladolid, Spain
jfpascua@maf.uva.es
asmiguel@maf.uva.es
fvicente@maf.uva.es
Abstract
In this paper, it is shown, using a geometrical approach, the isotropy of the velocity of light measured in a rotating frame in the Minkowski space-time, and it is verified that this result is compatible with the Sagnac effect. Furthermore, we find that this problem can be reduced to the solution of geodesic triangles in a Minkowskian cylinder. A relationship between the problems established on the cylinder and on the Minkowskian plane is obtained through a local isometry.
Keywords: isotropy, velocity of light, Sagnac effect
1. Introduction
One of the most celebrated results of the Theory of Relativity is the one known as the Sagnac effect [1], which appears when two photons describe, in opposite directions, a closed path on a rotating disk returning to the starting point. Physically, the Sagnac effect is essentially a phase shift between two coherent beams of light travelling along paths in opposite senses in an interferometer placed on a rigidly rotating platform [2]. This phase shift can be explained as a consequence of a time delay, so the Sagnac effect can also be measured with atomic clocks timing light
2
rays sent, e.g., around the rotating Earth via the satellites of the Global Positioning System [3]. From a geometrical approach, such phase shift has also been related [4] to the fact that the time component of the anholonomity object, corresponding to the choice of an orthonormal frame on the space-time, is different from zero.
The Sagnac effect outlines the problem of the isotropy of the velocity of light with respect to a non-inertial observer fixed on the rotating disk. This problem has been treated from different points of view. In [5], it is pointed out that the Sagnac time delay, measured by one single clock, is due to an anisotropy in the global speed of light for the non-inertial observer, in contradiction with the local Einstein synchronization convention. Another approach is found in [6]. There, the speed of light in opposite directions is the same, both locally and globally. The proof is performed using three clocks located at the initial and final positions of the two photons, and by extrapolating point to point, the local Einstein synchronization procedure to the whole periphery of the disk. The disagreements between both approaches are connected with the problem of the global time synchronization of points on the periphery of a rotating disk. Only if this global synchronization were possible there would exist a well defined spatial length between different points on the boundary of the rotating disk.
In this paper we consider an ideal rotating disk with negligible gravitational effects, thus the effects due to gravitational fields —that require the application of general relativistic techniques as those in [7] or [8], where exact and post-Minkowskian solutions are used— are not considered here. We will also show the isotropy of the velocity of light measured in a rotating frame in the Minkowski space-time. We verify that this isotropy is compatible with the Sagnac effect. For this we take into account that every kinematical problem in special relativity can always be translated into a geometrical problem on space-time.
Note on this respect that some authors have need to introduce some dynamical explanations for explaining the rotating disk problem [9].
An outline of the paper is as follows. In Sec. 1.2 we give a brief account of the technique used by Rizzi and Tartaglia [6] and describe how the use of the hypothesis of locality, (see [10]) offers an explanation of the Sagnac effect in the framework of special relativity, without using the anisotropy of a global speed of light. In Sec. 1.3, we solve this problem in terms of the world-function associated to the geodesic determined by the world-lines of the observer and the photon and the simultaneity space corresponding to the observer. In Sec. 1.4 a formulation of the problem using the solution of geodesic triangles is obtained. Finally, in
Isotropy of the velocity of light
3
Sec. 1.5 a relationship between the problem stated on a Minkowskian cylinder and on a Minkowskian plane is obtained.
2. The rotating disk and the Sagnac effect
Let D ⊂ R3 be a disk of radius ρ, and let us denote by ∂D the circle bounding D. We consider an inertial reference frame F : (O, {ei}3i=1), where O is the center of D and {ei}3i=1 is an orthonormal basis for the Euclidean space R3. In the coordinate system (x, y, z) associated to F ,
the points in D have coordinate z equal to zero. It will also be useful
to consider polar coordinates (r, θ) on D. Now we assume that the disk D is uniformly rotating about the O axis, with angular velocity ω. In
the space-time (M, η) of Special Relativity in Minkowski coordinates, with η = diag (1, 1, 1, c2), the motion of the points P ∈ ∂D with
polar coordinates (θ, t), is given by world-lines γP : t → γθ (t), that in coordinates (x, y, z, t) can be expressed as
γθ (t) : (ρ cos(ωt + θ), ρ sin(ωt + θ), 0, t).
(1.1)
This congruence of time-like curves determines a cylinder C ⊂ M. On the cylinder C both a metric g is induced by the metric η, which in comoving coordinates (θ, t), reads
g = ρ2dθ2 2 ωρ2dtdθ + α2(ω)c2 dt2,
(1.2)
where
α2(ω) := 1 (cρ)2,
(1.3)
and a Killing vector field Γ given by a combination of a rotation and a time translation, that, at each point P = (θ, t), is Γ(P ) = γ˙P (t), are defined. The associated Killing congruence has non null vorticity within the cylinder but is zero outside it. So, the vorticity and the 4-velocity play an analogous role to the magnetic field and the 4-electromagnetic potential, respectively, of the Aharonov-Bohm effect in electrodynamics, [11]. The metric (1.2) is globally stationary and locally static; therefore a local splitting of C can be obtained using local hypersurfaces locally orthogonal to the trajectory of the rotating observer, as in [12]. Even a global operational quotient space by the Killing congruence can be build, by using the radar distance as a spatial distance [13].
In general, for every two points A, B, joined by a geodesic γ(u), being u a special parameter with γ(u1) = A, γ(u2) = B, there is a function Ω(AB) —the world function in Synges terminology, [14]— defined by
u2
Ω(A
B)
:=
1 2
g(v, v) ds
u1
(1.4)
4
where v = γ˙ (u) denotes the tangent vector to the geodesic γ(u). Let us
now consider, at the time t = t1, a point O ∈ ∂D and the world-line γO (t) corresponding to a curve in the congruence (1.1), with θ = 0. On γO (t) one may build a field of non-inertial reference frames F (t). The proper
time interval between two events P0, P1 with coordinate times t1 and t2 measured by the observer F is given in terms of the world-function (1.4)
as
τ2 τ1 := c1 2Ω(P0P1) = α(ω)(t2 t1).
(1.5)
Suppose that the rotating observer fixed on the circle ∂D carries a device which emits, at the time t = 0, two photons in opposite directions along the periphery of the disk. The world-lines of both photons are null helices. Their equations in the inertial reference frame F read
γL± (t) : (xL = ρ cos(±̟t), yL = ρ sin(±̟t), t = t) , (1.6)
where ±̟ denotes the angular speeds of the photons given by ̟ρ = c,
being the plus (resp. minus) sign associated to the photon moving in
the same (resp. opposite) sense as the rotating disk.
At the initial time t = 0 it is assumed that γO (0) = γL(0). The
world-line corresponding to each photon cuts the curve γO at times t±,
for which it is satisfied the condition γL(t±) = γO (t±). Therefore one
obtains
t±
=
2π ̟∓
ω.
(1.7)
The relationship between proper time on γO and the inertial coordinate time given in (1.5) establishes that the proper time in F runs slow with respect to an inertial one. Hence, using (1.7) one obtains
τ±
=
α(ω) ̟∓ω
.
(1.8)
The proper time increment measured by the observer F among the
arrival times of the two photons P1 = γO (t1) and P2 = γO (t2) is (see,
e.g. [11]):
τ+
τ−
=
4ωS c2
α1
(ω)
(1.9)
that, in the limit of small rotational speeds, takes the classical form
given in [1]:
τ+
τ−
=
4ωS c2
+
O(c4)
(1.10)
where S = πr02 is the disk area.
Isotropy of the velocity of light
5
The Sagnac time delay is the desynchronization of a pair of clocks after a complete round trip, which has been initially synchronized and sent by the rotating observer to travel in opposite directions, [6]. In this case, the time differences along a complete round trip on the periphery ∂D of the disk, are not uniquely defined and the measurement of each one must be corrected by half the Sagnac time delay when compared with an identical clock remaining fixed at the initial position. After this correction is made, the global light speed is the same for the photon moving on ∂D in opposite sense. This is in fact what is done in the Global Positioning System, [3]. Note, on the other hand, that if the readings of both clocks are not corrected by half the Sagnac time (1.9), one obtains an anisotropic velocity of light, as in [5].
3. Measurement of relative speeds in Minkowski space-time
Let us assume that at the time t = 0, in the inertial reference frame F , a non-inertial observer F at a fixed point P0 ∈ ∂C emits a pulse of light in the same direction of the movement of the disk. The event P0 corresponds in the cylinder C to the point with cylindrical coordinates (θ, t) = (0, 0). We now determine the relative speed of the ray of light with respect to the non-inertial frame F .
The world-lines for the observer and the photon can be expressed in cylindrical coordinates, in the form
γO (t) : (θ = 0, t = t), γL(t) : (θ = (̟ ω)t, t = t) (1.11)
respectively. The curve γO (t) is the time-like helix corresponding to a non-inertial observer fixed at the point O on the disk. The curve γL(t) describes the null helix of the photon co-rotating with the disk.
On the world-line γO one can determine a vector field Λ such that the orthogonality condition, g(Λ, γ˙O (t)) = 0, is satisfied. For each point P on γO , one builds a space-like geodesic γS on the cylinder (C, g), corresponding to the initial data P, Λ(P )
γS : θ = (̟2 ω2) ω1 (t t0), t = t .
(1.12)
The geodesic γS can be interpreted as the locus of locally simultaneous events on an arc of the circle ∂C as seen by the rotating observer. For the
construction of the simultaneity space γS , the hypothesis of locality given in [10] is used, which establishes the local equivalence of an accelerated
frame and a local inertial frame with the same local speed. In this way,
a slicing of the cylinder C through a family of sections γS orthogonal to the congruence of curves γP is obtained.
6
When the rotating frame reaches the point P1 = (0, t1) in the curve γO , the world-function Ω(P0P1) is the square of the proper time (up to a constant factor) between the events P0 and P1 of space-time, measured by the non-inertial observer. At the time t1 the photon lies on the point P2 of the local simultaneity space relative to the non-inertial rotating observer. Since both the non-inertial observer and the photon move on
∂C, the corresponding points in space-time remain on the Minkowskian
cylinder C. Consider the point P2 given by the intersection of the curves γS and γL, (see Fig. 1.1):
P2 = (̟2 ω2) ̟1 t0, (̟ + ω) ̟1 t0 .
(1.13)
P2 γS
P1
γO
γL
P0
Figure 1.1. Geodesic triangle on the cylinder (C, g). γO , γL denote, respectively, the world-line of the observer and the photon. γS represents the simultaneity space at the point P1.
Using the metric (1.2), the world-function corresponding to the pairs
of points (P0, P1) and (P1, P2), calculated along the curves γO and γS , are
Ω(P0P1) = −Ω(P1P2) = ct0 α(ω).
(1.14)
respectively. Therefore, taking into account (1.5), the relative speed of the photon with respect to the non-inertial frame defined by
v2 L,O
:= c2
Ω(P1P2 Ω(P0P1
) )
,
(1.15)
coincides with c2.
Isotropy of the velocity of light
7
4. Equivalent formulation of the problem
Result (1.15) can be compared with that obtained by using the solu-
tion of geodesic triangles on the semi-Riemannian manifold (S, g) For
this we consider a geodesic triangle P0P1P2 on a 2-manifold (S, g) as shown in Fig. 1.2. For arbitrary points A and B, let Ωa(AB) denote the covariant derivative of (1.4) with respect to the coordinates of A,
and denote by Ωa(AB) the vector associated to Ωa(AB) by means of the metric g.
Let us assume that the Riemannian curvature of a surface S is small
and we will use the same notation as in [14], Chapter II. If {λ0(P0), λ1(P0)}
is an orthonormal basis on TP0S, one can build a field of reference frames on C by parallel transport of this frame along all geodesics xi(v) through
P0. On the field {λ0(P ), λ1(P )}, the vector field V i := ∂xi/∂v, tangent
to one of these geodesics on an arbitrary point, has constant components V (a) = V iλi(a). On the other hand, the components of the symmetrized Riemann tensor
Sijkl
:=
1 3
(Rijkm
+
Rimjk),
(1.16)
will be denoted by S(abcd).
P1(u1, v¯)
P2(u2, v¯) γ(u)
P (u, v) γ 2(v)
γ1 (v)
P0(0, 0)
Figure 1.2. Geodesic triangle on a surface with small curvature. The family of curves γ(v) emanating from the point P0, are geodesics parametrized by u ∈ [0, v¯]. Transversal curves are geodesics parametrized by u ∈ [u1, u2].
For the geodesic triangle determined by the curves P0P1 : γ1(v), P0P2 : γ2(v) and P1P2 : γ(u) (with u ∈ [u1, u2], v ∈ [0, v¯], see Fig. 1.2) a relationship between the world-functions of the sides of this triangle is
8
obtained in [14]:
Ω(P1 P2) = Ω(P0 P1) + Ω(P0 P2) Ωa(P0 P1)Ωa(P0 P2) + φ, (1.17)
where
φ
:=
1 6
(v¯ v)3Dv4Ω dv
0
(1.18)
and Dv4Ω denotes the covariant derivative of fourth order of the worldfunction Ω(γ1(v), γ2(v)) for an arbitrary v ∈ [0, v¯]. An explicit approx-
imate expression for φ appears in [14] p. 73, written in terms of the
Riemann tensor and its covariant derivatives. An application of this
solution to build Fermi coordinates in general space-times of small cur-
vature is given in [15]. In general it is satisfied that
φ0
=
(u2
3 u1)3
v¯ 0
u2
q(u, v) [1122] du dv,
u1
where q(u, v) is the polynomial
(1.19)
q(u, v) := (v¯ v)3((u2 u)2 + (u u1)2),
(1.20)
and symbol [1122], defined as
[1122]
:=
1 3
S(a1
b1 c2 d2
)V
(a1 ) V
(b1)V
(c2)V
(d2 ) ,
(1.21)
is constant on S, so that φ0 vanishes. In (1.21) V (i1), V (i2) are the components of V at points P1, P2 respectively. In the problem considered in this work, the metric (1.2) is uniform on the cylinder C, and the Riemannian curvature is zero, therefore expression (1.18) vanish.
Therefore, one obtains for the solution of the same triangle in the point P1
Ω(P0 P2) = Ω(P1 P0) + Ω(P1 P2) Ωa(P1 P0)Ωa(P1 P2),
(1.22)
where the covariant derivatives are calculated now at the point P1. Now, since the geodesic P0 P2 is null and the geodesics P1 P0 and P1 P2 are orthogonal in P1; then, from (1.22) one obtains
Ω(P1 P2) = −Ω(P0 P1)
(1.23)
Consequently, the ratio
v2 L,O
:=
c2
Ω(P1 Ω(P0
P2) P1)
,
(1.24)
coincides with (1.15).
Isotropy of the velocity of light
9
5. Reduction to the Minkowskian plane
In this section, we will see that the rotating observer on the disk has a specific characteristic which other different non-inertial observers do not have in general. In the first place, it is observed that expression (1.5), which relates the proper time τ of a non-inertial observer fixed on the rotating disk (moving with constant angular speed ω, such that ωρ = v) to the coordinate time t, coincides with the expression relating the inertial observers time to the time of another inertial reference frame boosted with rectilinear speed v. Then one concludes that only by measuring proper time, a rotating observer will not be able to determine the local inertial or non-inertial character of the frame rotating uniformly on the disk. The only magnitude that he will be able to measure in that case is the speed modulus v.
Now, let us consider a boosted rectilinear inertial frame K. To measure the speed of a photon moving in the same direction as K with respect to this frame we consider the configuration shown in Fig. 1.3.
γ
P2
S
P1
γ
γ
O
L
P0
Figure 1.3.
Geodesic
triangle
on
the Minkowskian
plane
(P, η).
γ , γ OL
denote,
re-
spectively, the world-line of the observer and the photon. γS represents the simul-
taneity space at the point P1.
Here γ represents the straight line described by the observer (we are O
assuming that the speed is v) in a Minkowskian plane (P, η). On the
other hand, the null straight line γ represents the trajectory that one
photon
describes,
and,
finally,
the
L
line
γ
is the space-like straight line
S
of simultaneous events to the emission event of the photon. This line is
everywhere ηorthogonal to the observer line at the event P1 : (vt0, t0).
10
Explicitly, taking P0 = (0, 0), these curves are given by
γL : (x = ct, t), γS : (x = v1c2(t t0α2(v)), t)
(1.25)
where now α2(v) := 1 v2/c2. This can be verified directly from Figure
2.
Moreover,
point
P2
at
which
γ S
cuts
to
γ L
has
the
coordinates
P2 : t0(c + v), c1t0(c + v) .
(1.26)
Therefore, keeping in mind again that P1 = (vt0, t0), one obtains that
the distances γ are
between
P1
and
P2
along
γ L
and
between
P0
and
P1
along
O
−Ω˜ (P1 P2) = Ω˜ (P0P1) = α(v)ct0
(1.27)
where Ω˜ (AB) denotes the world-function associated to points A, B and
the metric η. The relative speed between the light ray and the boosted
rectilinear inertial observer, defined through the ratio
v2 L,O
=
c2
Ω˜ (P1 Ω˜ (P0
P2 ) P1 )
,
(1.28)
coincides with c2. The identity between these expressions and those obtained before in
Sec. 1.3 is clear. Indeed, if v is substituted for ωρ those expressions are coincident. The fact that the values of Ω˜ (P0P1) and Ω˜ (P1P2) coincide with the values Ω(P0P1) and Ω(P1P2) obtained in the problem solved on the cylinder is due to a local isometry between the Minkowskian plane (P, η), which contains the line of universe of the boosted rectilinear inertial observer, and the Minkowskian cylinder (C, g), which contains the world-line of the non-inertial rotating frame.
As pointed out at the beginning of this section, the non-inertial rotating observer on the disk has a specific characteristic which other different non-inertial observers do not have, in general. In this case, the expression (1.5), relating the proper time τ and the coordinate time t, is the same as in inertial frames. This allows to build an isometry between cylinder C and the plane P as follows.
Let φ : U ⊂ C → P be a smooth map between a neighborhood of U , which contains the geodesic triangle considered above, and the plane P. Denote by TP C and Tφ(P )P the tangent spaces to C and P at the points P, φ(P ) respectively. The map φ is such that its differential, dφ : TP C → Tφ(P )P, is a linear isometry for every point P ∈ U :
η(dφ (v), dφ(w)) = g(v, w),
(1.29)
Isotropy of the velocity of light
11
for every v, w ∈ TP C. Let us consider a map φ such that φ(t, θ) = (t, x(t, θ)). We determine a function x(t, θ) satisfying condition (1.29). This function is determined through the partial differential system
∂x ∂t
=
ωρ,
∂x ∂θ
=
ρ,
(1.30)
whose solution is the function x(t, θ) = ρ(ωt + θ). Therefore an isometry
as
φ : (t, θ) −→ (t, ρ(ωt + θ)) ,
(1.31)
maps (C; g) into (P; η), retaining the same coordinate time in both manifolds.
The geodesic triangle of vertices P0, P1, P2 in C is mapped into the straight triangle P0, P1, P2 in P. Therefore, it is possible to translate the problem of measuring the speed of light with respect to a non-inertial reference frame, which describes a circumference rotating uniformly, to the problem of measuring the speed of light by an inertial reference frame, being the velocity equal to c in both cases. By means of this local isometry, for the point P2 on the cylinder there exists a corresponding P2 in the plane, which has the same coordinates as the event P2, obtained in Sec. 1.3 by means of the hypothesis of locality with the slicing of C.
Returning to the initial problem of two photons describing the periphery of a rotating disk in opposite senses, it is observed that one obtains the same result for both photons, as it may be verified solving the corresponding problem on the Minkowskian plane, where the speed of light is independent of the direction followed by the photons.
6. Concluding remarks
In [6], using the locus of locally simultaneous events to the non-inertial rotating observer (given by space-like helices in a Minkowski space-time), it is shown that the speed of light measured by a non-inertial observer fixed on the disk rim always turns out to be c both locally and globally. The local isometry (1.31), shows how this coincidence is obtained. In fact, this local isometry allows to calculate relative speeds (1.24) and (1.28) in the problem of the rotating disk, mapping the problem from the multiply connected Minkowskian cylinder to another one established in the simply connected Minkowskian plane.
From the above reasoning, one observes that although the observer is non-inertial this is not reflected on the measurements of relative speeds. This is because the module of the centripetal acceleration of the observer ω2ρ α2(ω), coincides with the module of the normal curvature of the world-line of the observer on the cylinder (C, g). A rotating observer
12
corresponds to a Killing trajectory, so its world-line is a geodesic on this cylinder. Moreover, the Gaussian curvature of the cylinder is zero. So, the non-inertiality of the rotating observer is not reflected in the measurement procedure, because this is only based on the first fundamental form of C.
Finally, we remark that the frame of reference considered in the problem of a rotating disk is very special, so the problem can be established on a circular cylinder. A more general case would be, for example, that of a deformable closed loop filament moving and preserving a non-circular shape.
Acknowledgments
The authors wish to thank A. Tartaglia for a discussion on the subject of this work. This work was completed with the support of the Junta de Castilla y Leo´n (Spain), project VA014/02.
Isotropy of the velocity of light
13
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