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... Science Frontiers ONLINE No. 17: Fall 1981 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects The gravitational "constant" is not!For too many years, physicists have been content with laboratory determinations of G (the gravitational constant) using the old Cavendish Balance. In this paper, Stacey and Tuck offer a disturbing collection of values of G determined from geophysical measurements; i.e ., measurements in mines, boreholes, and under the sea. These measurements are unanimous in producing G's that are larger than the usually accepted value by about 1%. Furthermore, the deeper the experiment, the greater the departure from the standard value. (Stacey, F.D ., and Tuck, G.J .; ... Geophysical Evidence for Non-Newtonian Gravity," Nature, 292:230, 1981.) Comment. These geophysical measurements must be added to recent laboratory experiments indicating that gravity may not be best described by an inverse square law. See our Handbook Mysterious Universe. Ordering details here . From Science Frontiers #17, Fall 1981 . 1981-2000 William R. Corliss ...
Terms matched: 2 - Score: 315 - 15 May 2017 - URL: /sf017/sf017p10.htm
... Science Frontiers ONLINE No. 62: Mar-Apr 1989 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects More challenges to newton's law of gravitation Two experiments reported at the 1988 meeting of the American Geophysical Union in San Francisco can be added to the others that question Newton's venerable Law of Gravitation. The abstracts of these papers are short and to-the-point, so we quote them: "We have performed an experimental test of Newton's inverse-square law of gravitation. The test compared accurately measured gravity values along the 600 m WTVD tower near Raleigh, North Carolina, with upward, continued gravity estimates calculated from ground measurements. We found a significant departure from the inverse-square law, asymptotically approaching ... 547 36 microGal at the top of the tower. If this departure is derived from a scalar Yukawa potential, the coupling parameter is alpha = 0.023, the range is lambda = 280 m, and the Newtonian Gravitational Constant is G = (6 .52 0.01) x 1011 m3 kg-1 s-2 . We do not yet have adequate resolution to discriminate this scalar model from a scalarvector model." (Eckhardt, D.H ., et al; "Experimental Evidence for a Violation of Newton's Inverse-Square Law of Gravitation," Eos, 69:1046, 1988.) "In the late summer of 1987, an ex periment was performed to determine the value of the Newtonian gravitational constant, G, by measuring the variation ...
Terms matched: 2 - Score: 243 - 15 May 2017 - URL: /sf062/sf062p13.htm
... was the first to be discovered. Even the Neanderthals knew of it! That's hardly surprising; it's everywhere. Unfortunately, we don't know much more about it than the Neanderthals. Though it seems powerful when you trip and fall, gravity is the weakest of the fundamental four. In a helium nucleus, the force of repulsion between two protons is 1040 times the gravitational attraction between them. Weak though it may be, gravity controls the trajectory of a baseball, the motion of the planets, and the shape of our Galaxy. Physicists describe gravitation with Newton's Law of Gravitation, which incorporates the Gravitational Constant G. Here's where the embarrassment arises. Many other constants of nature, such as the charge on the electron, are known to ... Science Frontiers ONLINE No. 116: Mar-Apr 1998 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects G: The Embarrassing Constant Of Nature Of the four fundamental forces of nature, gravity was the first to be discovered. Even the Neanderthals knew of it! That's hardly surprising; it's everywhere. Unfortunately, we don't know much more about it than the Neanderthals. Though it seems powerful when you trip and fall, gravity is the weakest of the fundamental four. In a helium nucleus, the force of repulsion between two protons is 1040 times the gravitational attraction between them. Weak though it may be, gravity controls the trajectory of a baseball, the motion of the planets, and the shape of our ...
Terms matched: 2 - Score: 218 - 15 May 2017 - URL: /sf116/sf116p19.htm
... Science Frontiers ONLINE No. 33: May-Jun 1984 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects High g-values in mines Measurements of G, the constant in Newton's Law of Gravitation, made in mines are always significantly higher than those made in surface laboratories. No one is quite sure why. It has been suggested that a lack of knowledge of the densities of surrounding rocks might account for this discrepancy. But Holding and Tuck report new measurements in Australian mines, where the densities are very well known. The G values are still high. Mine measurements of G differ in the fact that the masses employed can be much farther apart. (Holding, S.C ., and Tuck, G.J . ... Science Frontiers ONLINE No. 33: May-Jun 1984 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects High g-values in mines Measurements of G, the constant in Newton's Law of Gravitation, made in mines are always significantly higher than those made in surface laboratories. No one is quite sure why. It has been suggested that a lack of knowledge of the densities of surrounding rocks might account for this discrepancy. But Holding and Tuck report new measurements in Australian mines, where the densities are very well known. The G values are still high. Mine measurements of G differ in the fact that the masses employed can be much farther apart. (Holding, S.C ., and Tuck, G.J . ...
Terms matched: 2 - Score: 180 - 15 May 2017 - URL: /sf033/sf033p23.htm
... Two amusing examples are: The size of a planet is roughly the geometric mean of the size of the universe and the size of the atom; and The mass of man is the geometric mean of the mass of a planet and the mass of the proton. Less hilarious is the observation that the age of the universe is of the order of the quotient of the electron time scale and the gravitational fine structure constant; and that only at the present time are physical conditions in the universe favorable to the existence of life-as-we-know-it! The surprising number of coincidences that have been identified suggests that we exist and are aware of the universe around us only when certain coincidences prevail among physical constants. Is "now" a magic moment in the history of the ... Science Frontiers ONLINE No. 8: Fall 1979 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects Due to a fortunate coincidence you can read about a fortunate coincidence There are embedded in the fabric of our universe a number of curious coincidences among the so-called physical constants. Two amusing examples are: The size of a planet is roughly the geometric mean of the size of the universe and the size of the atom; and The mass of man is the geometric mean of the mass of a planet and the mass of the proton. Less hilarious is the observation that the age of the universe is of the order of the quotient of the electron time scale and the gravitational fine structure constant; and that only at the present time are physical ...
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... . 50: Mar-Apr 1987 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects On The Trail Of The Fifth Force Well publicized lately has been the modern reanalysis of the old Eotvos balance experiments. Some think they show the presence of that famous "fifth force" which is supposed, according to some theories, to modify Newton's Law of Gravitation, and become measurable at distances of about 100 to 1000 meters. The Eotvos results may also be explicable in terms of laboratory air currents. But the fifth force may be showing up in geophysical experiments. "One of the most comprehensive geophysical experiments so far has been conducted by Frank Stacey at University of Queensland in Brisbane, Australia, and his colleagues. Working in two metal mines, ... researchers have measured a gravitational constant that is 0.7 percent greater than that measured in the laboratory -- suggesting the presence of a fifth force." (Weisburd, Stefi; "Geophysics on the Fifth Force's Trail," Science News, 131: 6, 1987.) From Science Frontiers #50, MAR-APR 1987 . 1987-2000 William R. Corliss ...
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... Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects Flattened Sun Means Trouble For Einstein Recent measurements of the sun's diameter by P. Goode and H. Hill show: (1 ) The sun is "ringing like a bell" due to constant sunquakes; and (2 ) The sun is flattened enough at itse poles to signifcantly affect the precession of Mercury's orbit. The gravitational influence of the sun's bulge is so large that it, in effect, competes with relativistic effects as an explanation of Mercury's precession. Goode, in fact, has suggested that the Theory of Relativity must be in error. (Anonymous; "Reputed Mistake Found in Einstein's Theory of Relativity," Baltimore Sun, April 6, 1982. An Associated Press item ... Science Frontiers ONLINE No. 21: May-Jun 1982 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects Flattened Sun Means Trouble For Einstein Recent measurements of the sun's diameter by P. Goode and H. Hill show: (1 ) The sun is "ringing like a bell" due to constant sunquakes; and (2 ) The sun is flattened enough at itse poles to signifcantly affect the precession of Mercury's orbit. The gravitational influence of the sun's bulge is so large that it, in effect, competes with relativistic effects as an explanation of Mercury's precession. Goode, in fact, has suggested that the Theory of Relativity must be in error. (Anonymous; "Reputed Mistake Found in Einstein ...
Terms matched: 2 - Score: 144 - 15 May 2017 - URL: /sf021/sf021p05.htm
... Science Frontiers Online All Issues Last Issue Next Issue Sourcebook Project Sourcebook Subjects Contents Archaeology Were the British Megaliths Built As Scientific Instruments? Astronomy Mysteries Around Uranus Saturn is Still Cooking Away Biology Was There Really A Big Bang? What Was, Is, and Shall Be Why Conserve Junk? Geology Submarine Canyons: A 50-year Perspective Shergottites and Nakhlites: Young and Mysterious Too Many Pages Missing Geophysics The Gravitational "constant" is Not! Bioluminescent Cartwheels and Whirlpools in the Arabian Sea Solar Cosmic Rays Stimulate Thunderstorms Psychology How NDEs Differ From OBEs ...
Terms matched: 2 - Score: 144 - 15 May 2017 - URL: /sf017/index.htm
... Science Frontiers ONLINE No. 12: Fall 1980 Issue Contents Other pages Home Page Science Frontiers Online All Issues This Issue Sourcebook Project Sourcebook Subjects Gravity down, mass up The variation of the gravitational constant, G, with time would not be considered seriously were it not for the surprising coincidence of two enormous dimensionless numbers: (1 ) The ratio of the electrical to gravitational force between the electron and the proton in a hydrogen atom; and (2 ) The ratio of the age of the universe and the atomic unit of time. If these two ratios are truly equal, then G must decrease with time. Beyond the unstable feeling one gets, there is nothing in physics or cosmology to discourage a belief in time-varying gravity. Indeed, some as-tronomical data weakly support ... idea. It is geophysics, though, where one finds strong evidence. Measurements of the decreasing length of the day and the expansion of the earth give about the same value for a decreasing G -- after other contributing factors have been eliminated. An interesting consequence of all this is that astrophysical theory seems to require that a decreasing G be balanced by increasing mass. Experiments are now underway to detect the continual creation of mass in terrestrial objects. (Wesson, Paul S.; "Does Gravity Change with Time?" Physics Today, 33:32, July 1980.) From Science Frontiers #12, Fall 1980 . 1980-2000 William R. Corliss ...
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... arise from the general expansion of the universe; The microwave background radiation of 3 K, which was gleefully embraced by Big Bangers as an echo of their version of creation, is actually of the same energy density as starlight, cosmic rays, etc., and need not have anything to do with the Big Bang; and The Big Bang Theory and General Relativity assume a constant G (the gravitational constant), but some recent lunar orbit measurements suggest that G is slowly decreasing! (Narlikar, Jayant; "Was There a Big Bang?" New Scientist, 91:19, 1981.) Comment. Perhaps the most disturbing aspect of the whole Big Bang business is the contempt with which theory supporters dismiss all objections. Is the Big Bang a scientific theory or a belief system ... Big Bang theory may arise from the general expansion of the universe; The microwave background radiation of 3 K, which was gleefully embraced by Big Bangers as an echo of their version of creation, is actually of the same energy density as starlight, cosmic rays, etc., and need not have anything to do with the Big Bang; and The Big Bang Theory and General Relativity assume a constant G (the gravitational constant), but some recent lunar orbit measurements suggest that G is slowly decreasing! (Narlikar, Jayant; "Was There a Big Bang?" New Scientist, 91:19, 1981.) Comment. Perhaps the most disturbing aspect of the whole Big Bang business is the contempt with which theory supporters dismiss all objections. Is the Big Bang a scientific theory ...
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... ," Science News, 150:239, 1996) In a related news item, Mexican scientists have proposed that most of the matter in the universe (that elusive "dark" matter) may exist in the form of particles they dub "dilatons." Dilatons might also explain the formation of the aforesaid galactic shells. "The Mexican researchers have explored a situation in which G [the gravitational constant], instead of becoming fixed after gravity separated from the other forces [after the Big Bang], has continued to oscillate by a few per cent. They have found that the mass of dilatons required to allow G to vary in this way could account for all the Universe's dark matter." A consequence of an oscillating G would be a varying rate of expansion for ... universe -- a sort of ebb and flow of the whole cosmos. One can then visualize galaxies gradually clustering together into shells much as sand particles drift into ripples under the influence of waves along a beach. (Parsons, Paul; "Weird Matter Makes Gravity Wobble," New Scientist, p. 19, October 5, 1996) Clustering of distant galaxies From Science Frontiers #109, JAN-FEB 1997 . 1997-2000 William R. Corliss ...
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... 's Abstract: "An anomalous variation in gravity totaling 3.87 mGal (3 .87 x 10- 5 m/s 2 ) in a depth interval of 1460 m was observed. This may be attributed either to a breakdown of Newtonian gravity or to unexpected density variations in the rock below the ice." (Zumberge, Mark A., et al; "The Greenland Gravitational Constant Experiment," Journal of Geophysical Research, 95:15483, 1990.) From Science Frontiers #74, MAR-APR 1991 . 1991-2000 William R. Corliss ...
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... , chunks of tree stems that are sealed to prevent water from flowing in or out will still expand and contract according to the 24-hour, 49-minute lunar cycle as long as the cambium, the most active growing region, survives. The dimensional changes are small -- only tenths of a millimeter, but even these seem too large, given the weakness of the moon's gravitational field here on earth. (Ref. 2 and 3) References 1. Burr, H.S .; "Moon Madness," Yale Journal of Biology and Medicine, 19:249, 1944. 2. Zurcher, Ernst, and Cantiana, MariaGiulia; "Tree Stem Diameters Fluctuate with Tide," Nature, 392:665, 1998.) 3. Milius, S ... The influence of the moon upon trees is even more palpable: the diameters of tree stems also bloat and shrink with the position of the moon in the sky. There is a tide in the affairs of trees, it seems. If tides occur twice a day, so do the swellings and shrinkings of trees. These tidal patterns are evident even when the trees are kept in darkness and at constant pressure and humidity. Even more surprising, chunks of tree stems that are sealed to prevent water from flowing in or out will still expand and contract according to the 24-hour, 49-minute lunar cycle as long as the cambium, the most active growing region, survives. The dimensional changes are small -- only tenths of a millimeter, but even these seem too large, ...
Terms matched: 2 - Score: 124 - 15 May 2017 - URL: /sf118/sf118p07.htm