Experimental challenges edit

Initial attempts to measure the second order transverse Doppler effect in canal rays completely failed. For example, Stark's 1906 measurements showed systematic errors ten times the predicted effect.^[5] The maximum speed achievable in early gas-discharge tubes was about 0.005 c, which implied a transverse Doppler shift of only about 1.25×10⁻⁵. The small TDE achievable was considerably less than the width of the emission lines, which were relatively diffuse due to the Doppler line-broadening resulting from non-uniformity of ion speeds.

By the 1930s, improvements in canal-ray tubes allowed for considerable sharpening of the emission lines.^[1] Even with these improvements, however, performing the experiment as usually imagined (with the observation being made at right angles to the beam) would be extremely difficult since small errors in the angle of observation would result in line-shifts of magnitude comparable to the magnitude of the anticipated effect.^[1]

To avoid the issues associated with observing the beam at right angles, Ives and Stilwell used a small mirror within the canal ray tube (See Fig. 1 and Fig. 3) to observe the beam simultaneously in two directions both with and against the motions of the particles. The TDE would manifest itself as a shift of the center of gravity of the simultaneously red- and blue-shifted spectral lines.^[1]

Theory edit

In 1937, Ives performed a detailed analysis of the spectral shifts to be expected of particle beams observed at different angles following a "test theory" which was consistent with the Michelson-Morley experiment (MMX) and the Kennedy-Thorndike experiment (KTX), but which differed from special relativity (and the mathematically equivalent theory of Lorentz and Lamor) in including a parameter ${\displaystyle n}$  whose value can not be determined by MMX and KTX alone.^[10] Various values of ${\displaystyle n}$  would correspond to various combinations of length contraction, width expansion, and time dilation, where ${\displaystyle n=1}$  would be the value predicted by special relativity. Ives proposed the optical experiment described in this article to determine the precise value of ${\displaystyle n.}$ ^[10]

We will not present Ives' 1937 analysis, but instead will compare the predictions of special relativity against the predictions of "classical" aether theory with the apparatus stationary in the hypothetical aether, even though the classical aether had already long been ruled out by MMX and KTX.^[11][12]

Classical analysis edit

In the classical Doppler effect, the wavelength of light observed by a stationary observer of light emitted by a source moving at speed ${\displaystyle v}$  away from or towards the observer is given by

${\displaystyle \lambda _{obs}=\lambda \cdot (1\pm \beta )}$  where ${\displaystyle \beta =v/c}$ 

The top sign is used if the source is receding, and the bottom sign if it is approaching the observer.

• We note that the magnitude of the wavelength shift for the source moving away from the observer exactly equals the magnitude of the wavelength shift for the source moving towards the observer
• The average of the observed wavelengths for a source moving away from the observer and the source moving towards the observer at the same speed exactly equals the wavelength of the source.^[11]

Relativistic analysis edit

In the relativistic longitudinal Doppler effect, the observed wavelength with source and observer moving away from each other at speed ${\displaystyle v}$  is given by

${\displaystyle \lambda _{obs}=\lambda \cdot {\frac {\sqrt {1+\beta }}{\sqrt {1-\beta }}}\,\,}$  where ${\displaystyle \beta =v/c}$ 

The signs will be reversed with the source and observer moving towards each other. In the Ives and Stilwell experiment, the direct view of the particle beam will be blueshifted, while the reflected view of the particle beam will be redshifted.

The first few terms of the Taylor series expansion for the direct view of the particle beam is given by

${\displaystyle \lambda _{obs}=\lambda \cdot \left(1-\beta +{\frac {\beta ^{2}}{2}}-{\frac {\beta ^{3}}{2}}+{\frac {3\beta ^{4}}{8}}\ldots \right)}$ 

while the first few terms of the Taylor series expansion for the reflected view of the particle beam is given by

${\displaystyle \lambda _{obs}=\lambda \cdot \left(1+\beta +{\frac {\beta ^{2}}{2}}+{\frac {\beta ^{3}}{2}}+{\frac {3\beta ^{4}}{8}}\ldots \right)}$ 

The even power terms have the same sign for both views, meaning that both the direct and reflected rays will show an increase in wavelength over that predicted by the classical Doppler analysis.^[11][12]

The average of the direct and reflected wavelengths is given by

${\displaystyle \lambda _{avg}=\lambda \cdot \left(1+{\frac {\beta ^{2}}{2}}+{\frac {3\beta ^{4}}{8}}\ldots \right)=}$  ${\displaystyle {\frac {\lambda }{\sqrt {1-\beta ^{2}}}}=\gamma \cdot \lambda }$ 

where ${\displaystyle \gamma }$  is the Lorentz factor. Special relativity therefore predicts that the center of gravity of Doppler-shifted emission lines emitted by a source moving towards an observer and its reflected image moving away from the observer will be offset from unshifted emission lines by an amount equal to the transverse Doppler effect.^[11][12]

The experiment of 1938 edit

In the experiment, Ives and Stilwell used hydrogen discharge tubes as the source of canal rays which consisted primarily of positive H₂⁺ and H₃⁺ ions. (Free H⁺ ions were present in too small an amount to be usable, since they quickly combined with H₂ molecules to form H₃⁺ ions.) These ions, after being accelerated to high speed in the canal ray tube, would interact with molecules of the fill gas (which sometimes included other gases than H₂) to release excited atomic hydrogen atoms whose velocities were determined by the charge-to-mass ratios of the parent H₂⁺ and H₃⁺ ions.^[12] The excited atomic hydrogen atoms emitted bright emission lines. For their paper, Ives and Stilwell focused on the blue-green 4861 Å ${\displaystyle H_{\beta }}$  line of the Balmer series. Fig. 4 shows an example of the results that they obtained, with an undisplaced emission line in the center, and lines from Doppler-shifted atomic hydrogen released from H₂⁺ and H₃⁺ ions at three different voltages on either side of the center line. The particle velocities, as measured by the first-order Doppler displacements, were consistently within 1% of the values computed by the theoretical relationship ${\displaystyle eE=M(v^{2}/c^{2})/2,}$  where e is the charge on the hydrogen atom, E is the voltage between the electrode plates, and M is the mass of the observed particle.^[1]

The asymmetry of the Doppler-shifted lines with respect to the undisplaced central emission line is not evident to casual inspection, but requires extreme precision of measurement with careful attention to sources of systematic error. In their optical arrangement, illustrated in Fig. 2, the first order (classical Doppler) displacement of emissions from H₂⁺ ions at 20,000 volts was about 2 mm. The expected second order shift of the center of gravity of direct and reflected views of the emissions was only about 0.005 mm which corresponded to 0.05 Å, requiring measurement accuracies of several tenths of a micron.^[1]

Initial measurements of the displacements were very erratic. The source of the unsystematic errors in measurement of the center of gravity of the displaced lines was found to be due to the complex molecular absorption spectrum of the fill gas. An emission line, passing adjacent to a molecular absorption line of the fill gas, would be differentially absorbed on one side or the other of its nominal center, and the measurement of its wavelength would thus be disturbed. Fig. 5 illustrates the issue. Fig. 5A illustrates an undisplaced ${\displaystyle H_{\beta }}$  emission line. Fig. 5B illustrates the molecular absorption spectrum of the fill gas, obtained by photographing the spectrum of the arc behind the electrode of the canal ray tube (see Fig. 1). Fig. 5C illustrates an undisplaced ${\displaystyle H_{\beta }}$  emission line surrounded by displaced ${\displaystyle H_{\beta }}$  emission lines from H₂⁺ and H₃⁺. At the particular voltage chosen, the lines from H₂⁺ are clear of the molecular absorption lines (see arrows), but the lines from H₃⁺ are not.^[1]

As a result of this issue, the number of voltages available yielding direct and reflected lines in clear spaces was relatively limited.^[1]

Ives and Stilwell compared their results against theoretical expectation using several approaches. Fig. 6 compares theoretical versus measured center-of-gravity shifts ${\displaystyle \Delta \lambda _{2}}$  plotted against the emission lines' first-order Doppler shifts ${\displaystyle \Delta \lambda _{1}.}$  The advantage of this method over the other method presented in their paper (plotting center-of-gravity shifts against the computed velocity, based on voltage) is that it was independent of any errors of voltage measurement and did not require any assumptions of the voltage-velocity relationship.^[1]

In terms of Ives' 1937 test theory,^[10] the close agreement between the observed center-of-gravity displacements versus theoretical expectation support ${\displaystyle n=1,}$  which corresponds to length contraction by the Lorentz factor ${\displaystyle \lambda }$  in the direction of motion, no length changes at right angles to the motion, and time dilation by the Lorentz factor.^[1] The results therefore validated a key prediction of the theory of relativity, although it might be noted that Ives himself preferred to interpret the results in terms of the obsolescent theory of Lorentz and Lamor.^[12]

The experiment of 1941 edit

In the 1938 experiment, the maximum TDE was limited to 0.047 Å. The chief difficulty that Ives and Stilwell encountered in attempts to achieve larger shifts was that when they raised the electric potential between the accelerating electrodes to above 20,000 volts, breakdown and sparking would occur that could lead to destruction of the tube.

This difficulty was overcome by using multiple electrodes. Using a four-electrode version of the canal ray tube with three gaps, a total potential difference of 43,000 volts could be achieved. A voltage drop of 5,000 volts was used across the first gap, while the remaining voltage drop was distributed between the second and third gaps. With this tube, a highest shift of 0.11 Å was achieved for H₂⁺ ions.^[2]

Other aspects of the experiment were also improved. Careful tests showed that the "undisplaced" particles yielding the central line actually acquired a small velocity imparted to them in the same direction of motion as the moving particles (no more than about 750 meters per second). Under normal circumstances, this would be of no consequence, since this effect would only result in a slight apparent broadening of the direct and reflected images of the central line. But if the mirror were tarnished, the central line might be expected to shift slightly, since the redshifted reflected view of the emission line would contribute less to the measured wavelength than the blueshifted direct view. Other controls were performed to address various objections of critics of the original experiment.

The net result of all of this attention to detail was the complete verification of Ives and Stilwell's 1938 results and the extension of these results to higher speeds.^[2]

Relativistic Doppler effect edit

A more precise confirmation of the relativistic Doppler effect was achieved by the Mössbauer rotor experiments. From a source in the middle of a rotating disk, gamma rays are sent to an absorber at the rim (in some variations this scheme was reversed), and a stationary counter was placed beyond the absorber. According to relativity, the characteristic resonance absorption frequency of the moving absorber at the rim should decrease due to time dilation, so the transmission of gamma rays through the absorber increases, which is subsequently measured by the stationary counter beyond the absorber. This effect was actually observed using the Mössbauer effect. The maximal deviation from time dilation was 10⁻⁵, thus the precision was much higher than that (10⁻²) of the Ives–Stilwell experiments. Such experiments were performed by Hay et al. (1960),^[13] Champeney et al. (1963, 1965),^[14][15] and Kündig (1963).^[16]

Isotropy of the speed of light edit

Mössbauer rotor experiments were also used to measure a possible anisotropy of the speed of light. That is, a possible aether wind should exert a disturbing influence on the absorption frequency. However, as in all other aether drift experiments (Michelson–Morley experiment), the result was negative, putting an upper limit to aether drift of 2.0 cm/s. Experiments of that kind were performed by Champeney and Moon (1961),^[17] Champeney et al. (1963),^[18] Turner and Hill (1964),^[19] and Preikschat supervised by Isaak (1968).^[20]

Fast moving clocks edit

A considerably higher precision has been achieved in modern variations of Ives–Stilwell experiments. In heavy-ion storage rings, as the TSR at the MPIK or ESR at the GSI Helmholtz Centre for Heavy Ion Research, the Doppler shift of lithium ions traveling at high speed ^[21] is evaluated by using saturated spectroscopy or optical–optical double resonance.

Due to their frequencies emitted, these ions can be considered as optical atomic clocks of high precision. Using the framework of Mansouri–Sexl^[22] a possible deviation from special relativity can be quantified by

${\displaystyle {\frac {\nu _{a}\nu _{p}}{\nu _{1}\nu _{2}}}=1+2{\hat {\alpha }}\beta ^{2},}$ ^{[dubious – discuss]}

with ${\displaystyle \nu _{a}}$  as frequency of the laser beam propagating anti-parallel to the ion beam and ${\displaystyle \nu _{p}}$  as frequency of the laser beam propagating parallel to the ion beam. ${\displaystyle \nu _{1}}$  and ${\displaystyle \nu _{2}}$  are the transition frequencies of the transitions in rest. ${\displaystyle \beta =v/c}$  with ${\displaystyle v}$  as ion velocity and ${\displaystyle c}$  as speed of light. In the case of saturation spectroscopy the formula changes to

${\displaystyle {\frac {\nu _{a}\nu _{p}}{\nu _{0}^{2}}}=1+2{\hat {\alpha }}\beta ^{2},}$ 

with ${\displaystyle \nu _{0}}$  as the transition frequency in rest. In the case that special relativity is valid ${\displaystyle {\hat {\alpha }}}$  is equal to zero.

Slow moving clocks edit

Meanwhile, the measurement of time dilation at everyday speeds has been accomplished as well. Chou et al. (2010) created two clocks each holding a single ²⁷Al⁺ ion in a Paul trap. In one clock, the Al⁺ ion was accompanied by a ⁹Be⁺ ion as a "logic" ion, while in the other, it was accompanied by a ²⁵Mg⁺ ion. The two clocks were situated in separate laboratories and connected with a 75 m long, phase-stabilized optical fiber for exchange of clock signals. These optical atomic clocks emitted frequencies in the petahertz (1 PHz = 10¹⁵ Hz) range and had frequency uncertainties in the 10⁻¹⁷ range. With these clocks, it was possible to measure a frequency shift due to time dilation of ~10⁻¹⁶ at speeds below 36 km/h (< 10 m/s, the speed of a fast runner) by comparing the rates of moving and resting aluminum ions. It was also possible to detect gravitational time dilation from a difference in elevation between the two clocks of 33 cm.^[27]

• Experimental testing of time dilation
• Tests of special relativity

• Roberts, T.; Schleif, S.; Dlugosz, J. M. (2007). "What is the experimental basis of Special Relativity?". Usenet Physics FAQ. University of California, Riverside.