Dayton Miller
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Dayton Clarence Miller (March 13 1866 - February 22, 1941) was an American physicist, astronomer, acoustician, and accomplished amateur flutist.
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Biography
Miller obtained a doctorate in astronomy at Princeton University under Charles A. Young. In 1890, he worked at the Case School of Applied Science in Cleveland, Ohio teaching astronomy, later becoming the head of the physics department in 1893. Following the discovery of X-rays by Wilhelm Röntgen in 1895, Miller used cathode ray tubes built by William Crookes to make some of the first photographic images of concealed objects, including a bullet within a man's limb.
Aether research
In 1900, he began work with Edward Morley on the detection of aether drift, at the time one of the "hot" areas of fundamental physics. Following on with the basic apparatus as the earlier Michelson-Morley experiment, Miller and Morley published another null result in 1904. The experiments concern many physicists dealing with Albert Einstein's theory of relativity.
Miller continued with the experiment, conducting thousands of measurements and eventually developing the most accurate interferometer in the world at that time. The type of experimental apparatus Miller used was very delicate. Dayton Miller performed over 200,000 observations and experiments dealing with the aether and aether drift. A second publication in 1926 showed what appeared to be a small amount of drift, which Miller commented on at several meetings. A third, in 1933, continued the theme. From 1902 to 1933 Miller performed experiments producing more accurate measurements. This work on aether (http://www.orgonelab.org/miller.htm) was published as a positive result for the existence of an aether drift. However, the effect Miller saw was tiny. In order for it to detect aether, the properties of aether drag would have to more pronounced. Furthermore, the measurement was statistically far from any other measurements being carried on at the time, fringe shifts of about 0.01 were being observed in many experiments, while Miller's 0.08 was not duplicated anywhere else -- including Miller's own 1904 experiments with Morley, which showed a drift of only 0.015. The measurements are perfectly consistent with a fringe difference of zero -- the null result that every other experiment was recording.
Einstein was interested in this aether drift theory and acknowledged that a positive result for the existence of aether would invalidate the theory of special relativity, but commented that altitudal influences and temperatures may have provided sources of error in the findings. Miller commented:
- "The trouble with Professor Einstein is that he knows nothing about my results. ... He ought to give me credit for knowing that temperature differences would affect the results. He wrote to me in November suggesting this. I am not so simple as to make no allowance for temperature."
During the 1920s a number of experiments, both interferometry based, as in Miller's experiment, and others using entirely different techniques, were conducted and these returned a null result as well. Even at the time, Miller's work was increasingly considered to be a statistical anomaly, an opinion which remains true today, given an ever growing body of negative results.
Shankland analysis
In 1955, Robert S. Shankland, S. W. McCuskey, F. C. Leone, and G. Kuerti performed a re-analysis of Miller's results. Shankland, who led the report, noted that the "signal" that Miller observed in 1933 is actually composed of points that are an average of several hundred measurements each, and the magnitude of the signal is more than 10 times smaller than the resolution with which the measurements were recorded. Miller's extraction of a single value for the measurement is statistically impossible, the data is too variable to say "this" number is any better than "that" -- the data, from Shankland's position, supports a null result as equally as Miller's positive.
Shankland concluded that Miller's observed signal was partly due to statistical fluctuations and partly due to local temperature conditions and, also, suggested that the results of Miller were due to a systematic error rather than an observed existence of aether. In particular he felt that Miller did not take enough care in guarding against thermal gradients in the room where the experiment took place, as, unlike most interferometry experiments, Miller conducted his in a room where the apparatus was deliberately left open to the elements to some degree.
Shankland believed that Miller's research was a major obstacle to and overshadowed any consideration of a Nobel Prize being awarded to Einstein for his relativity theory. In a 1973 review paper on the experimental development of relativity, Shankland included an August 31, 1954 letter to him by Einstein. Einstein wrote:
- I thank you very much for sending me your careful study about the Miller experiments. Those experiments, conducted with so much care, merit, of course, a very careful statistical investigation. This is more so as the existence of a not trivial positive effect would affect very deeply the fundament of theoretical physics as it is presently accepted.
- You have shown convincingly that the observed effect is outside the range of accidental deviations and must, therefore, have a systematic cause. You made it quite probable that this systematic cause has nothing to do with "ether-wind," but has to do with differences of temperature of the air traversed by the two light bundles which produced the bands of interference. Such an effect is indeed practically inevitable if the walls of the laboratory room have a not negligible difference in temperature.
- It is one of the cases where the systematic errors are increasing quickly with the dimension of the apparatus.
In Shankland's analysis, no statistically significant signal for the existence of aether was found. Shankland concluded that Miller's observed signal was partly due to error rather than an observed existence of aether holding radiant energy. Thus, a large, but indefinite, number of mainstream scientists today hold the conviction that any signal that Miller observed was the result of the experimenter effect, which was a common source of systematic error before modern experimental techniques were developed (ed, Miller did publish an early textbook on experimental techniques; cf., Ginn & Company, 1903).
William Broad and Nicholas Wade, reporters who wrote Betrayers of the Truth: Fraud in Science (1983), have stated that scientists should have reviewed Miller's research more seriously at the time, and that their refusal to do so is evidence of incompetence and unprofessional conduct. Robert Crease (http://www.sunysb.edu/philosophy/faculty/rcrease.html) argues that it would have been "irrational and unscientific" to suspend Einstein's theory because of a contrary experiment. In Crease's opinion, this would allow some antiscientific ideologues (eg., some Soviet scientists) to stop progress through falsification. [1] (http://physicsweb.org/article/world/15/12/2)
Other studies
Other studies have instead concluded that the shifts in Miller's data are statistically significant. For example, A. K. Timiriazev, R. A. Monti (Physics Essays 9, 1996) and M. Allais (Comptes Rendus de l'Académie des Sciences 327, 1999) later disproved Shankland's allegation. Dr. Maurice Allais statistical analysis of the thousands of interferometer measurements of Dayton Miller found a corresponding periodicity with the sidereal day, the equinoxes and other celestial events thus invalidating the Robert S. Shankland refutation of Miller's work. This analysis (http://www.anti-relativity.com/allaisarticle21stcentury.htm), if confirmed, either casts doubt on the second postulate of Special Relativity or opens possibilities for expansion of the theory. As of 2004, more of Miller's papers from the possession of R. S. Shankland have resurfaced and are awaiting future analysis.
Other endeavors
Dr. Miller published manuals designed to be student handbooks for the performance of experimental problems in physics. In 1908, Miller's interest in acoustics led him to develop a machine to record sound waves photographically, called the phonodeik. He used the machine to compare the waveforms produced by flutes crafted from different materials. During World War I, Miller worked with the physical characteristics of pressure waves of large guns at the request of the government. Dayton Miller was elected to the National Academy of Science in 1921.
Published works
- Laboratory Physics, a Student's Manual for Colleges and Scientific Schools. (New York: Ginn & Company, 1903)
- The Science of Musical Sounds (New York: The Macmillan Company, 1916, revised 1926)
- Anecdotal History of the Science of Sound (New York: The Macmillan Company, 1935)
- Sound Waves: Their Shape and Speed (New York: The Macmillan Company, 1937)
- Sparks, Lightning and Cosmic Rays (New York: The Macmillan Company, 1939)
- The Ether-Drift Experiments and the Determination of the Absolute Motion of the Earth (http://prola.aps.org/abstract/RMP/v5/i3/p203_1) (Reviews of Modern Physics 5, 203-242 (1933))
See also
- Aether and Luminiferous aether
- History of physics
- List of physics topics
- Michelson-Morley experiment
External links and references
Main
- William J. Maynard (1971). Dayton C. Miller: His Life, Work, and Contributions as a Scientist and Organologist (http://memory.loc.gov/ammem/dcmhtml/may0.html). Master's thesis, Long Island University
- "Dayton Clarence Miller (http://www.todayinsci.com/3/3_13.htm)". Today in Science, March 13 - births.
- "Dayton Miller images (http://www.aip.org/history/esva/catalog/esva/Miller_Clarence.html)". American Institute of Physics, 2003.
Aether
- DeMeo, James, "Dayton Miller's Ether-Drift Experiments: A Fresh Look (http://www.orgonelab.org/miller.htm)".
- Deen, Glen W., "Dayton C. Miller's 1933 Cosmic Ether Model (http://home1.gte.net/res00bfl/millers_cosmic_model.htm)"
- Schleif, Siegmar, "Repetitions of the MMX (http://www.weburbia.demon.co.uk/physics/experiments.html#II)". What is the experimental basis of the Special Relativity Theory. Jan. 17, 1998.
- Allais, Maurice, "The experiments of Dayton C. Miller (1925 - 1926) and the Theory of Relativity (http://allais.maurice.free.fr/English/media12-1.htm)". 21st century - Science & Technology. Spring 1998.
- "The experiments by Dayton C Miller (1925-1926) and relativity theory (http://www.s-line.de/homepages/keppler/allais2.htm)". (German)
- Allais, Maurice, "Very significant regularities in the interferometric observations of Dayton C. Miller 1925-1926 (http://allais.maurice.free.fr/English/media14-1.htm)". French Academy of Sciences, January 23rd, 1997.
- Allais, Maurice, "New very significant regularities in the interferometric observations of Dayton C. Miller 1925-1926 (http://allais.maurice.free.fr/English/media15-1.htm)". French Academy of Sciences, April 26th, 1999.
- Allais, Maurice, "The origin of the very significant regularities displayed in the interferometric observations of Dayton C. Miller 1925-1926: temperatures effects or space anisotropy (http://allais.maurice.free.fr/English/media16-1.htm)?". French Academy of Sciences, December 2000
- Thompson, Caroline, "Forgotten History (http://freespace.virgin.net/ch.thompson1/History/forgotten.htm)". August 27, 2000.
- Correa, Paulo, "A note on Dayton Miller's supposed discovery of an aether drift (http://www.aetherometry.com/miller.html)".
- "The Effect of solar motion upon the fringe-shifts in a Michelson-Morley interferometer µa la Miller (http://www.ensmp.fr/aflb/AFLB-272/aflb272p463.pdf)". Annales de la Fondation Louis de Broglie, Volume 27 no 3, 2002 463. (PDF)
Other endeavors
- Dayton C. Miller Flute Collection (http://memory.loc.gov/ammem/dcmhtml/dmhome.html) at The Library of Congress.
- "Crookes x-ray tubes (http://www.cwru.edu/artsci/dittrick/artifactspages/b-4tubes.htm)" Dittrick Medical History Center, Case Western Reserve University. 2004.
- "The Phonodeik (http://www.srm.com/1916/lecture3phonodeik.html)". The science of musical sounds.
- "Professor Dayton Miller's Research in Acoustics (http://people.deas.harvard.edu/~jones/cscie129/supplements/Miller/miller.html)". Engineering Sciences E-129.