Bill Ryan
12th August 2020, 21:37
I found this extremely interesting, The Allais Effect is recognized but controversial, and to this day there's no agreed explanation for it.
An excellent article about this was actually by NASA, 21 years ago:
https://science.nasa.gov/science-news/science-at-nasa/1999/ast06aug99_1
The main article title is Decrypting the Eclipse. But my thread title is a lot better. :)
~~~
A Solar Eclipse, Global Measurements, and a Mystery
6 August, 1999
"During the total eclipses of the sun on June 30, 1954, and October 22, 1959, quite analogous deviations of the plane of oscillation of the paraconical pendulum were observed..." - Maurice Allais, 1988 Nobel autobiographical lecture.
The natural phenomenon of a solar eclipse has historically brought kings to assemble armies and, in the modern era, brought camera-toting astronomers to remote locations around the world. On August 11 [1999], a solar eclipse will bring scientists together in an effort to solve a 45-year mystery.
https://science.nasa.gov/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/07/28/ast06aug99_1_resources/eclipsepurple.jpg?
When the Moon eclipses the Sun, the solar corona becomes visible. The corona is faint compared to the Sun, so it can only be seen when the Sun is blocked from view. Jean Bernard Leon Foucault, with the physicist Armand Fizeau, took the first clear photograph of the Sun in 1845.
The mystery lies in the question: Does a solar eclipse somehow affect a Foucault pendulum? In 1954, Maurice Allais reported that a Foucault pendulum exhibited peculiar movements at the time of a solar eclipse. If true, his finding raises new questions about the nature of such phenomena.
For the upcoming eclipse, the NASA/Marshall Space Sciences Lab is coordinating an internet and video collaboration between observatories and universities to test the Allais effect. Participants on 4 continents (Central Europe, North America, Middle Asia, and Australasia), are from at least 7 countries (US, Austria, Germany, Italy, Australia, 4 sites in the United Arab Emirates, and England) and 11 cities (Huntsville AL, Indianapolis, Louisville, Denver, Boulder, Richmond, Vienna, Greifswald, Trento, Abu Dhabi, and Sydney).
The inventor of the gyroscope, Jean Bernard Leon Foucault, demonstrated during the 1851 World's Fair that a pendulum could track the rotation of the Earth. A scientific tour de force, Foucault's demonstration forever attached his name both to the effect itself (the Foucault effect) and to the universal joint pendulum that freely swings and rotates at the same time (the Foucault pendulum).
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/07/22/ast06aug99_1_resources/pendulumSmithsonian.gif?itok=HpTeTX5H (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/07/22/ast06aug99_1_resources/pendulumSmithsonian.gif)
Time-elapsed photo of a Foucault pendulum at the Smithsonian Museum. As the Earth rotates under the pendulum, the bob strikes down red pegs.
A basic Foucault pendulum is simply a weight on a wire. Practically any pocket watch has the potential to act as a pendulum, exhibiting up to a 10 to 15 degree rotation per hour around its hinge point. To an observer in a windowless room, the rotation that accompanies the swing is a kind of optical illusion: the pendulum is not turning, instead the Earth is actually rotating under the pendulum. Foucault's dramatic proof at the World's Fair is considered to be the first non-astronomical proof of the Earth's rotation.
With rotating hinges raised to heights in excess of 90 feet, Foucault pendulums are now massive display pieces in the lobbies of more than 60 museums and entrance halls around the world, including the United Nations Building in New York and at the Smithsonian Museum in Washington.
Remarkably, little more than two long-term scientific records for Foucault pendulums have been published. Both experiments were conducted by eventual Nobel Prize winners: Heike Kamerlingh-Onnes, who won the 1913 Nobel prize in Physics for his investigations on the properties of matter at low temperatures (which led to the production of liquid helium), and Maurice Allais, who won the 1988 Nobel prize in Economics for his contributions to the theory of markets and efficient utilization of resources.
An Abrupt Excursion in the Plane: What Allais Published
In a marathon experiment, Maurice Allais released a Foucault pendulum every 14 minutes - for 30 days and nights -without missing a data point. He recorded the direction of rotation (in degrees) at his Paris laboratory. This energetic show of human endurance happened to overlap with the 1954 solar eclipse. During the eclipse, the pendulum took an unexpected turn, changing its angle of rotation by 13.5 degrees.
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/07/23/ast06aug99_1_resources/allaisNobel.gif?itok=tW6BJhxK (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/07/23/ast06aug99_1_resources/allaisNobel.gif)
Maurice Allais (1911 - ) won the Nobel Prize in Economics in 1988. He stated, "All my researches in theoretical and applied physics which, at first sight, appear to be remote from my main activity as an economist, have, in reality, enriched me with valuable experience." Both before and after the eclipse, the pendulum experienced normal rotation (Foucault effect of 0.19 degrees/minute). This 13.5-degree excursion in the angular plane persisted throughout the length of the eclipse, a total of 2.5 hours of observations. Allais got similar results when he later repeated the experiment during a solar eclipse in 1959.
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/08/02/ast06aug99_1_resources/foucauClock.gif?itok=XpdKYQQi (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/08/02/ast06aug99_1_resources/foucauClock.gif)
Click the image above for a Foucault clock animation - each tick shown is one hour worth of observed rotation. Depending on geographic position, the rotation of the Earth on a Foucault clock can be measured as different rotation rates: infinite period at the equator; approximately 24 hours at the poles; clockwise in the Southern Hemisphere; counter-clockwise in the Northern Hemisphere. The Allais effect observed over 2 and an half hours during the shadow of an extended solar eclipse's onset and departure equals nearly the magnitude of the Foucault effect itself (or about one tick shown).
Allais' pendulum experiments earned him the 1959 Galabert Prize of the French Astronautical Society, and in 1959 he was made a laureate of the United States Gravity Research Foundation.
A handful of scientists have since tested Allais' findings, and the results have polarized the publication record:
An Overview of Publications About Eclipse Phenomena
France, June 1954;
October 1959 pendulum
YES: http://projectavalon.net/tick.gif
Allais' original observations were repeated 3 times in 1954 and 1959 in France. In two locations: "two identical installations at St. Germain and Bougival, in an underground gallery (57 m deep) showing that the previously observed anomalies are still present." Allais, 1959.
Scotland, 1954;
Italy, 1965 gravimeter
NO: http://projectavalon.net/cross.gif
Given a null report in 1954 in Shetland, Scotland using static gravity meters, and in 1965 in Trieste, Italy.
Romania, 1961
pendulum
YES: http://projectavalon.net/tick.gif
The Allais effect was repeated in 1961 in Romania. "A number of observations were made of the behavior of a Foucault pendulum during the eclipse of the Sun of February 15, 1961. A similar result concerning a shift of the oscillation plane on June 30, 1954 was seen by Prof. Maurice Allais at St. Germain-Laye. These experiments should be repeated during other total eclipses of the sun." G.T. Jeverdan, et al, 1961 (A footnote states that after recording their deviations in the Foucault pendulum, the researchers discovered the Allais observations. In other words, they weren't looking for it.)
Boston, 1970
pendulum
YES: http://projectavalon.net/tick.gif
Allais effect repeated using a torsion pendulum. In the observations at Harvard, a 0.0372% increase in the period (29.570 second baseline) began with the eclipse onset, peaked just after the eclipse maximum (29.581 second max.) and then decreased to an offset value. The researchers conclude that "this agrees qualitatively with the work of Allais with a paraconical (Foucault) pendulum. The change of azimuth increased substantially in the first half of the eclipse of June 30, 1954." These effects manifest as an "apparent wavelike structure observed over the course of many years at our Harvard laboratory. It cannot be predicted on the basis of classical gravitational theory nor has it been observed in the quasistationary experiments underlying this theory (e.g. spring-operated gravimeters, seismographs, and interferometer devices)." Saxl and Allen, Phys. Rev. D3, 1971.
Finland, 1990
pendulum
NO: http://projectavalon.net/cross.gif
Not observed in 1990 Finland eclipse using a torsion pendulum. "In July 1990 there was a total solar eclipse in Helsinki, Finland. The results of Saxl and Allen, made at Harvard University during the total solar eclipse in March 1970, were tested using equipment which was quite similar to that used in Harvard. Four measurements, each lasting nine hours, were performed during the night preceding the eclipse, during the eclipse and the night after the eclipse and two weeks after the eclipse. In the limits of errors no effects were observed." Ullakko, et al, 1991.
Mexico City, 1991
pendulum
MAYBE:http://projectavalon.net/tick.gifhttp://projectavalon.net/cross.gif
The team that conducted the Finland 1990 study detected an indefinite signal one year later in Mexico City. "In the y-position of the pendulum there are two distinct shifts which seem to appear at the beginning and the end of the eclipse... Our experiment cannot determine whether these shifts are produced by some eclipse-coordinated phenomena, e.g. some sort of tidal waves on the shell of the Earth which has altered the position of the pendulum system."
India, 1995
gravimeter
YES: http://projectavalon.net/tick.gif
A gravimeter detected slight changes during a solar eclipse. "[A one hour feature of the gravimeter record] of 10-12 microGal (10-8cm/s2)...can neither be classified under short period variations due to tidal effect or drift of the gravimeter nor under high frequency noise which have special patterns. Therefore, this variation is highly significant as it occurs with the onset of an eclipse...to understand its actual nature and mechanism, more planned experiments of this kind should be carried out during solar eclipses throughout the world whenever such opportunities are available." D.C. Mishra, M.B.S. Rao, National Geophysical Research Institute, Current Science, 72 (11) 1997 (783).
"The initial interpretation of the record points to three possibilities," says Dr. David Noever of NASA/Marshall, "A systematic error, a local effect, or the unexplored. To eliminate the first two possibilities, we and several other observers will use different kinds of measuring instruments in a distributed global network of observing stations."
Worldwide Effort, August 11, 1999
Testing and then verifying the effects of a solar eclipse is a difficult enterprise. Because an eclipse has a short duration, it is difficult to conduct very many tests. Also, eclipse effects usually get attributed to some local effect like seismic or temperature changes because the experiments are not conducted in several different places at once. Therefore, in order to determine whether or not the effects of any single eclipse are one-time, localized events, many observing stations are needed to test eclipse peculiarities.
During the next solar eclipse, Noever's team and volunteer scientists at several museums will simultaneously observe Foucault pendulums. Noever and other scientists will also use a gravimeter - a super-sensitive device that reports very small changes in the gravitational force acting on a mechanical spring.
After the eclipse, Noever's team will compare the results of all the tests, including observations from areas in Europe that lie in the path of the eclipse.
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/06/17/ast17jun99_1_resources/gravitometer.gif?itok=KmJ2mM8V (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/06/17/ast17jun99_1_resources/gravitometer.gif)
Cutaway view of gravimeter, with magnetic, thermal and pressure shielding. The instrument reports very small changes in the gravitational force acting on a mechanical spring-mass. Gravitational changes are expressed as the electrical force (measured as voltage) required to maintain the spring-mass system at a predetermined position (the null point). The modified LaCoste-Romberg gravimeter (Edcon, Inc. Denver, CO) measures relative gravity until calibrated against a reference. The instrument is routinely calibrated along the 10-station Rocky Mountain Calibration range established by NOAA, Edcon and the Colorado School of Mines. The calibration is validated by comparing the measure of absolute gravity in Huntsville Alabama with reference values from the USAF gravity disk. Data collection begins on August 11. The times of the solar eclipse are 3am-9am in North America, and 9a.m.-3p.m. in Europe and Middle Asia. These times can be adjusted for exact locations, for instance, in Boulder, CO, a data set for recording would be about 2:30a.m., continuing until 8:30a.m. That would cover the approach of the shadow, the actual eclipse, and the retreat of the shadow. The total length of the eclipse from initial contact in the Atlantic to last contact in the Indian Ocean is about 3½ hours.
Eclipsing Speculation
If the scientists do observe the Allais effect, the prevailing question will be "Why does it occur?" So far, explanations have included the anisotropy of space (the condition of having different properties in different directions), gravitational waves, and solar radiation.
But before the cause of the Allais effect can be determined, scientists first need to settle the question about whether a pendulum really does act differently during a solar eclipse. By having a global network of scientists collaborating on a single eclipse, the answer to that question will perhaps finally be resolved. Results of August 11 eclipse will have to be coordinated with lunar opposition (2 weeks later) before a first summary of eclipse data will be available. Realistically, scientists think it will take at least a decade before all opinions are settled.
In his Nobel Prize autobiographical speech, Allais stated, "My main idea at the start was that a link could be established between magnetism and gravitation by observing the movements of a pendulum consisting of a glass ball oscillating in a magnetic field. Of all the observations made in 1952 and 1953 I was not able to draw any definitive conclusion. Through certain experimental devices, I obtained positive effects, but with other devices I obtained no effect whatsoever....all these phenomena are quite inexplicable within the framework of the currently accepted theories."
An excellent article about this was actually by NASA, 21 years ago:
https://science.nasa.gov/science-news/science-at-nasa/1999/ast06aug99_1
The main article title is Decrypting the Eclipse. But my thread title is a lot better. :)
~~~
A Solar Eclipse, Global Measurements, and a Mystery
6 August, 1999
"During the total eclipses of the sun on June 30, 1954, and October 22, 1959, quite analogous deviations of the plane of oscillation of the paraconical pendulum were observed..." - Maurice Allais, 1988 Nobel autobiographical lecture.
The natural phenomenon of a solar eclipse has historically brought kings to assemble armies and, in the modern era, brought camera-toting astronomers to remote locations around the world. On August 11 [1999], a solar eclipse will bring scientists together in an effort to solve a 45-year mystery.
https://science.nasa.gov/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/07/28/ast06aug99_1_resources/eclipsepurple.jpg?
When the Moon eclipses the Sun, the solar corona becomes visible. The corona is faint compared to the Sun, so it can only be seen when the Sun is blocked from view. Jean Bernard Leon Foucault, with the physicist Armand Fizeau, took the first clear photograph of the Sun in 1845.
The mystery lies in the question: Does a solar eclipse somehow affect a Foucault pendulum? In 1954, Maurice Allais reported that a Foucault pendulum exhibited peculiar movements at the time of a solar eclipse. If true, his finding raises new questions about the nature of such phenomena.
For the upcoming eclipse, the NASA/Marshall Space Sciences Lab is coordinating an internet and video collaboration between observatories and universities to test the Allais effect. Participants on 4 continents (Central Europe, North America, Middle Asia, and Australasia), are from at least 7 countries (US, Austria, Germany, Italy, Australia, 4 sites in the United Arab Emirates, and England) and 11 cities (Huntsville AL, Indianapolis, Louisville, Denver, Boulder, Richmond, Vienna, Greifswald, Trento, Abu Dhabi, and Sydney).
The inventor of the gyroscope, Jean Bernard Leon Foucault, demonstrated during the 1851 World's Fair that a pendulum could track the rotation of the Earth. A scientific tour de force, Foucault's demonstration forever attached his name both to the effect itself (the Foucault effect) and to the universal joint pendulum that freely swings and rotates at the same time (the Foucault pendulum).
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/07/22/ast06aug99_1_resources/pendulumSmithsonian.gif?itok=HpTeTX5H (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/07/22/ast06aug99_1_resources/pendulumSmithsonian.gif)
Time-elapsed photo of a Foucault pendulum at the Smithsonian Museum. As the Earth rotates under the pendulum, the bob strikes down red pegs.
A basic Foucault pendulum is simply a weight on a wire. Practically any pocket watch has the potential to act as a pendulum, exhibiting up to a 10 to 15 degree rotation per hour around its hinge point. To an observer in a windowless room, the rotation that accompanies the swing is a kind of optical illusion: the pendulum is not turning, instead the Earth is actually rotating under the pendulum. Foucault's dramatic proof at the World's Fair is considered to be the first non-astronomical proof of the Earth's rotation.
With rotating hinges raised to heights in excess of 90 feet, Foucault pendulums are now massive display pieces in the lobbies of more than 60 museums and entrance halls around the world, including the United Nations Building in New York and at the Smithsonian Museum in Washington.
Remarkably, little more than two long-term scientific records for Foucault pendulums have been published. Both experiments were conducted by eventual Nobel Prize winners: Heike Kamerlingh-Onnes, who won the 1913 Nobel prize in Physics for his investigations on the properties of matter at low temperatures (which led to the production of liquid helium), and Maurice Allais, who won the 1988 Nobel prize in Economics for his contributions to the theory of markets and efficient utilization of resources.
An Abrupt Excursion in the Plane: What Allais Published
In a marathon experiment, Maurice Allais released a Foucault pendulum every 14 minutes - for 30 days and nights -without missing a data point. He recorded the direction of rotation (in degrees) at his Paris laboratory. This energetic show of human endurance happened to overlap with the 1954 solar eclipse. During the eclipse, the pendulum took an unexpected turn, changing its angle of rotation by 13.5 degrees.
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/07/23/ast06aug99_1_resources/allaisNobel.gif?itok=tW6BJhxK (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/07/23/ast06aug99_1_resources/allaisNobel.gif)
Maurice Allais (1911 - ) won the Nobel Prize in Economics in 1988. He stated, "All my researches in theoretical and applied physics which, at first sight, appear to be remote from my main activity as an economist, have, in reality, enriched me with valuable experience." Both before and after the eclipse, the pendulum experienced normal rotation (Foucault effect of 0.19 degrees/minute). This 13.5-degree excursion in the angular plane persisted throughout the length of the eclipse, a total of 2.5 hours of observations. Allais got similar results when he later repeated the experiment during a solar eclipse in 1959.
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/08/02/ast06aug99_1_resources/foucauClock.gif?itok=XpdKYQQi (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/08/02/ast06aug99_1_resources/foucauClock.gif)
Click the image above for a Foucault clock animation - each tick shown is one hour worth of observed rotation. Depending on geographic position, the rotation of the Earth on a Foucault clock can be measured as different rotation rates: infinite period at the equator; approximately 24 hours at the poles; clockwise in the Southern Hemisphere; counter-clockwise in the Northern Hemisphere. The Allais effect observed over 2 and an half hours during the shadow of an extended solar eclipse's onset and departure equals nearly the magnitude of the Foucault effect itself (or about one tick shown).
Allais' pendulum experiments earned him the 1959 Galabert Prize of the French Astronautical Society, and in 1959 he was made a laureate of the United States Gravity Research Foundation.
A handful of scientists have since tested Allais' findings, and the results have polarized the publication record:
An Overview of Publications About Eclipse Phenomena
France, June 1954;
October 1959 pendulum
YES: http://projectavalon.net/tick.gif
Allais' original observations were repeated 3 times in 1954 and 1959 in France. In two locations: "two identical installations at St. Germain and Bougival, in an underground gallery (57 m deep) showing that the previously observed anomalies are still present." Allais, 1959.
Scotland, 1954;
Italy, 1965 gravimeter
NO: http://projectavalon.net/cross.gif
Given a null report in 1954 in Shetland, Scotland using static gravity meters, and in 1965 in Trieste, Italy.
Romania, 1961
pendulum
YES: http://projectavalon.net/tick.gif
The Allais effect was repeated in 1961 in Romania. "A number of observations were made of the behavior of a Foucault pendulum during the eclipse of the Sun of February 15, 1961. A similar result concerning a shift of the oscillation plane on June 30, 1954 was seen by Prof. Maurice Allais at St. Germain-Laye. These experiments should be repeated during other total eclipses of the sun." G.T. Jeverdan, et al, 1961 (A footnote states that after recording their deviations in the Foucault pendulum, the researchers discovered the Allais observations. In other words, they weren't looking for it.)
Boston, 1970
pendulum
YES: http://projectavalon.net/tick.gif
Allais effect repeated using a torsion pendulum. In the observations at Harvard, a 0.0372% increase in the period (29.570 second baseline) began with the eclipse onset, peaked just after the eclipse maximum (29.581 second max.) and then decreased to an offset value. The researchers conclude that "this agrees qualitatively with the work of Allais with a paraconical (Foucault) pendulum. The change of azimuth increased substantially in the first half of the eclipse of June 30, 1954." These effects manifest as an "apparent wavelike structure observed over the course of many years at our Harvard laboratory. It cannot be predicted on the basis of classical gravitational theory nor has it been observed in the quasistationary experiments underlying this theory (e.g. spring-operated gravimeters, seismographs, and interferometer devices)." Saxl and Allen, Phys. Rev. D3, 1971.
Finland, 1990
pendulum
NO: http://projectavalon.net/cross.gif
Not observed in 1990 Finland eclipse using a torsion pendulum. "In July 1990 there was a total solar eclipse in Helsinki, Finland. The results of Saxl and Allen, made at Harvard University during the total solar eclipse in March 1970, were tested using equipment which was quite similar to that used in Harvard. Four measurements, each lasting nine hours, were performed during the night preceding the eclipse, during the eclipse and the night after the eclipse and two weeks after the eclipse. In the limits of errors no effects were observed." Ullakko, et al, 1991.
Mexico City, 1991
pendulum
MAYBE:http://projectavalon.net/tick.gifhttp://projectavalon.net/cross.gif
The team that conducted the Finland 1990 study detected an indefinite signal one year later in Mexico City. "In the y-position of the pendulum there are two distinct shifts which seem to appear at the beginning and the end of the eclipse... Our experiment cannot determine whether these shifts are produced by some eclipse-coordinated phenomena, e.g. some sort of tidal waves on the shell of the Earth which has altered the position of the pendulum system."
India, 1995
gravimeter
YES: http://projectavalon.net/tick.gif
A gravimeter detected slight changes during a solar eclipse. "[A one hour feature of the gravimeter record] of 10-12 microGal (10-8cm/s2)...can neither be classified under short period variations due to tidal effect or drift of the gravimeter nor under high frequency noise which have special patterns. Therefore, this variation is highly significant as it occurs with the onset of an eclipse...to understand its actual nature and mechanism, more planned experiments of this kind should be carried out during solar eclipses throughout the world whenever such opportunities are available." D.C. Mishra, M.B.S. Rao, National Geophysical Research Institute, Current Science, 72 (11) 1997 (783).
"The initial interpretation of the record points to three possibilities," says Dr. David Noever of NASA/Marshall, "A systematic error, a local effect, or the unexplored. To eliminate the first two possibilities, we and several other observers will use different kinds of measuring instruments in a distributed global network of observing stations."
Worldwide Effort, August 11, 1999
Testing and then verifying the effects of a solar eclipse is a difficult enterprise. Because an eclipse has a short duration, it is difficult to conduct very many tests. Also, eclipse effects usually get attributed to some local effect like seismic or temperature changes because the experiments are not conducted in several different places at once. Therefore, in order to determine whether or not the effects of any single eclipse are one-time, localized events, many observing stations are needed to test eclipse peculiarities.
During the next solar eclipse, Noever's team and volunteer scientists at several museums will simultaneously observe Foucault pendulums. Noever and other scientists will also use a gravimeter - a super-sensitive device that reports very small changes in the gravitational force acting on a mechanical spring.
After the eclipse, Noever's team will compare the results of all the tests, including observations from areas in Europe that lie in the path of the eclipse.
https://science.nasa.gov/files/science-pink/s3fs-public/styles/large/public/mnt/medialibrary/1999/06/17/ast17jun99_1_resources/gravitometer.gif?itok=KmJ2mM8V (https://science.nasa.gov/files/science-pink/s3fs-public/mnt/medialibrary/1999/06/17/ast17jun99_1_resources/gravitometer.gif)
Cutaway view of gravimeter, with magnetic, thermal and pressure shielding. The instrument reports very small changes in the gravitational force acting on a mechanical spring-mass. Gravitational changes are expressed as the electrical force (measured as voltage) required to maintain the spring-mass system at a predetermined position (the null point). The modified LaCoste-Romberg gravimeter (Edcon, Inc. Denver, CO) measures relative gravity until calibrated against a reference. The instrument is routinely calibrated along the 10-station Rocky Mountain Calibration range established by NOAA, Edcon and the Colorado School of Mines. The calibration is validated by comparing the measure of absolute gravity in Huntsville Alabama with reference values from the USAF gravity disk. Data collection begins on August 11. The times of the solar eclipse are 3am-9am in North America, and 9a.m.-3p.m. in Europe and Middle Asia. These times can be adjusted for exact locations, for instance, in Boulder, CO, a data set for recording would be about 2:30a.m., continuing until 8:30a.m. That would cover the approach of the shadow, the actual eclipse, and the retreat of the shadow. The total length of the eclipse from initial contact in the Atlantic to last contact in the Indian Ocean is about 3½ hours.
Eclipsing Speculation
If the scientists do observe the Allais effect, the prevailing question will be "Why does it occur?" So far, explanations have included the anisotropy of space (the condition of having different properties in different directions), gravitational waves, and solar radiation.
But before the cause of the Allais effect can be determined, scientists first need to settle the question about whether a pendulum really does act differently during a solar eclipse. By having a global network of scientists collaborating on a single eclipse, the answer to that question will perhaps finally be resolved. Results of August 11 eclipse will have to be coordinated with lunar opposition (2 weeks later) before a first summary of eclipse data will be available. Realistically, scientists think it will take at least a decade before all opinions are settled.
In his Nobel Prize autobiographical speech, Allais stated, "My main idea at the start was that a link could be established between magnetism and gravitation by observing the movements of a pendulum consisting of a glass ball oscillating in a magnetic field. Of all the observations made in 1952 and 1953 I was not able to draw any definitive conclusion. Through certain experimental devices, I obtained positive effects, but with other devices I obtained no effect whatsoever....all these phenomena are quite inexplicable within the framework of the currently accepted theories."