Gravitational shielding

The term gravitational shielding refers to a hypothetical process of shielding an object from the influence of a gravitational field. Such processes, if they existed, would have the effect of reducing the weight of an object. The shape of the shielded region would be similar to a shadow from the gravitational shield. For example, the shape of the shielded region above a disk would be conical. The height of the cone's apex above the disk would vary directly with the height of the shielding disk above the Earth.^[1] Experimental evidence to date indicates that no such effect exists. Gravitational shielding is considered to be a violation of the equivalence principle and therefore inconsistent with both Newtonian theory and general relativity.^[2]

The concept of gravity shielding is a common concept in science fiction literature, especially for space travel. One of the first and best known examples is the fictional gravity shielding substance "Cavorite" that appears in H. G. Wells' classic 1901 novel The First Men in the Moon. Wells was promptly criticized for using it by Jules Verne.^[3]

Tests of the equivalence principle

As of 2008^[update], no experiment was successful in detecting positive shielding results. To quantify the amount of shielding, at the beginning of 20th century Quirino Majorana^[4] suggested an extinction coefficient h that modifies Newton's gravitational force law as follows:

${\displaystyle F={\frac {GMm}{r^{2}}}e^{-h\int \rho (r)dr}}$

The best laboratory measurements have established an upper bound limit for shielding of 4.3×10⁻¹⁵ m²/kg.^[5] The best estimate based on the most accurate gravity anomaly data during the 1997 solar eclipse has provided a new constraint on the shielding parameter 6×10⁻¹⁹ m²/kg.^[6] However, astronomical observations impose much more stringent limits. Based on lunar observations available in 1908, Poincaré^[7] established that h can be no greater than 10⁻¹⁸ m²/kg. Subsequently, this bound has been greatly improved. Eckhardt^[8] showed that lunar ranging data implies an upper bound of 10⁻²² m²/kg, and Williams, et al.,^[9] have improved this to h = (3 ± 5)×10⁻²² m²/kg. Note that the value is smaller than the uncertainty. The consequence of the negative results of those experiments (which are in good agreement with the predictions of general relativity) is, that every theory which contains shielding effects like Le Sage's theory of gravitation, must reduce those effects to an undetectable level. For a review of the current experimental limits on possible gravitational shielding, see the survey article by Bertolami, et al.^[2] Also, for a discussion of recent observations during solar eclipses, see the paper by Unnikrishnan et al.^[10]

Majorana's experiments and Russell's criticism

Some shielding experiments were conducted in the early 20th century by Quirino Majorana.^[4][11] Majorana claimed to have measured positive shielding effects. Henry Norris Russell's analysis of the tidal forces showed that Majorana's positive results had nothing to do with gravitational shielding.^[12] To bring Majorana's experiments in accordance with the equivalence principle of General Relativity he proposed a model, in which the mass of a body is diminished by the proximity of another body, but he denied any connection between gravitational shielding and his proposal of mass variation. For another explanation of Majorana's experiments, see Coïsson et al.^[13] But Majorana's results could not be confirmed up to this day (see the section above) and Russell's mass variation theory, although meant as a modification of general relativity, is inconsistent with standard physics as well.

Minority views

The consensus view of the scientific community is that gravitational shielding does not exist, but there have been occasional investigations into this topic, such as the 1999 NASA-funded paper which reported negative results.^[14][15][16] Eugene Podkletnov claimed in two papers, one of which he later withdrew, that objects held above a magnetically-levitated, superconducting, rotating disc underwent a reduction of between 0.5 and 2% in weight.^[17] Theoreticians have attempted to reconcile Podkletnov's claims with quantum gravity theory.^[18][19] In 2006, a research group funded by ESA claimed to have created a similar device that demonstrated positive results for the production of gravitomagnetism, although it produced only 0.0001 g.^[20]

Electrets

In his 1976 paper, Electromagnetism and Gravitation, physicist Edward Teller discussed experimentation with electrets, or materials with a permanent electric dipole moment, near its transition point to discover the transition between dipole states.^[21] On July 9, 1997, William Rhodes, an inventor, made a posting on Usenet concerning a discovery of an antigravity effect related to electrets.^[22] Also, Dr. Martin Tajmar, a physicist and professor for Space Systems at the Dresden University of Technology has written a paper on propellantless propulsion and makes numerous references to electrets.^[23] A patent for a gravitational attenuating material that utilizes an organic based material was made by inventor Ronald J. Kita.^[24][25][26]

See also

• Breakthrough Propulsion Physics Program
• Anti-gravity
• Artificial gravity
• Eugene Podkletnov
• Ning Li
• Electromagnetic shielding

References

1. Unnikrishnan, C.S. (1996). "Does a superconductor shield gravity?". Physica C: Superconductivity. 266 (1–2). Elsevier BV: 133–137. Bibcode:1996PhyC..266..133U. doi:10.1016/0921-4534(96)00340-1.
2. Bertolami, Orfeu; Páramos, Jorge; Turyshev, Slava G. (2008). "General Theory of Relativity: Will It Survive the Next Decade?". Lasers, Clocks and Drag-Free Control. Astrophysics and Space Science Library. Vol. 349. pp. 27–74. doi:10.1007/978-3-540-34377-6_2. ISBN 978-3-540-34376-9. S2CID 12079261.
3. Giblin, James (2000). The Century that was: Reflections on the Last One Hundred Years. Simon and Schuster. p. 8. ISBN 978-0-689-82281-0. I sent my travelers to the moon with gunpowder, something one sees every day. Where is Monsieur Wells' 'Cavorite'? Let him show it to me!
4. Majorana, Q. (1920). "XLVIII. On gravitation. Theoretical and experimental researches". The London, Edinburgh, and Dublin Philosophical Magazine and Journal of Science. 39 (233). Informa UK Limited: 488–504. doi:10.1080/14786440508636063.
5. Unnikrishnan, C. S.; Gillies, G. T. (2000-04-13). "New limits on the gravitational Majorana screening from the Zürich G experiment". Physical Review D. 61 (10). American Physical Society (APS): 101101(R). Bibcode:2000PhRvD..61j1101U. doi:10.1103/physrevd.61.101101.
6. Yang, Xin-She; Wang, Qian-Shen (2002). "Gravity Anomaly During the Mohe Total Solar Eclipse and New Constraint on Gravitational Shielding Parameter". Astrophysics and Space Science. 282 (1). Springer Science and Business Media LLC: 245–253. Bibcode:2002Ap&SS.282..245Y. doi:10.1023/a:1021119023985. S2CID 118497439.
7. Poincaré, Henri (1908). "La dynamique de l'électron" [The dynamics of the electron] (PDF). Revue générale des sciences pures et appliquées (in French). 19: 386–402.
8. Eckhardt, Donald H. (1990-09-15). "Gravitational shielding". Physical Review D. 42 (6). American Physical Society (APS): 2144–2145. Bibcode:1990PhRvD..42.2144E. doi:10.1103/physrevd.42.2144. PMID 10013064.
9. Williams, James G.; Turyshev, Slava G.; Boggs, Dale H. (1 July 2009). "Lunar laser ranging tests of the equivalence principle with the earth and moon". International Journal of Modern Physics D. 18 (7): 1129–1175. arXiv:gr-qc/0507083. Bibcode:2009IJMPD..18.1129W. doi:10.1142/S021827180901500X. S2CID 119086896.
10. Unnikrishnan, C. S.; Mohapatra, A. K.; Gillies, G. T. (12 February 2001). "Anomalous gravity data during the 1997 total solar eclipse do not support the hypothesis of gravitational shielding". Physical Review D. 63 (6): 062002. Bibcode:2001PhRvD..63f2002U. doi:10.1103/PhysRevD.63.062002.
11. Martins, Roberto de Andrade (2002). "Majorana's experiments on gravitational absorption". In Edwards, Matthew R (ed.). Pushing gravity: new perspectives on Le Sage's theory of gravitation. Apeiron. pp. 219–238. ISBN 978-1-4237-1624-2. OCLC 61151058.
12. Russell, Henry Norris (December 1921). "On Majorana's Theory of Gravitation". The Astrophysical Journal. 54: 334. Bibcode:1921ApJ....54..334R. doi:10.1086/142649.
13. Coïsson, R.; Mambriani, G.; Podini, P. (April 2002). "A new interpretation of Quirino Majorana's experiments on gravitation and a proposal for testing his results". Nuovo Cimento B. 117 (4): 469. Bibcode:2002NCimB.117..469C.
14. N. Li; D. Noever; T. Robertson; R. Koczor; W. Brantley (August 1997). "Static Test for a Gravitational Force Coupled to Type II YBCO Superconductors". Physica C. 281 (2–3): 260–267. Bibcode:1997PhyC..281..260L. doi:10.1016/S0921-4534(97)01462-7.
15. Koczor, Ronald; Noever, David (1999). "Fabrication of large bulk ceramic superconductor disks for gravity modification experiments and performance of YBCO disks under EM field excitation". 35th Joint Propulsion Conference and Exhibit. doi:10.2514/6.1999-2147.
16. Space.com on NASA funding Archived February 10, 2006, at the Wayback Machine
17. Podkletnov, E; Nieminen, R (December 10, 1992). "A possibility of gravitational force shielding by bulk YBa2Cu3O7−x superconductor". Physica C. 203 (3–4): 441–444. Bibcode:1992PhyC..203..441P. doi:10.1016/0921-4534(92)90055-H.
18. Modanese, G (1996-08-20). "Theoretical analysis of a reported weak-gravitational-shielding effect". Europhysics Letters (EPL). 35 (6): 413–418. arXiv:hep-th/9505094. Bibcode:1996EL.....35..413M. doi:10.1209/epl/i1996-00129-8. S2CID 10365722.
19. Ning, Wu (2004-04-15). "Gravitational Shielding Effect in Gauge Theory of Gravity". Communications in Theoretical Physics. 41 (4): 567–572. arXiv:hep-th/0307225. Bibcode:2004CoTPh..41..567W. doi:10.1088/0253-6102/41/4/567. S2CID 119407101.
20. "Toward a new test of general relativity?". Esa.int. Archived from the original on December 28, 2017. Retrieved 2013-08-06.
21. Teller, Edward (1 July 1977). "Electromagnetism and gravitation". Proceedings of the National Academy of Sciences. 74 (7): 2664–2666. Bibcode:1977PNAS...74.2664T. doi:10.1073/pnas.74.7.2664. PMC 431235. PMID 16592415.
22. William Rhodes Usenet posting https://groups.google.com/forum/#!search/rhodes$20%22gravity$20shield%22/sci.systems/3_11GyUQYUw/rc1Q5O_2EVQJ
23. Tajmar, M (July 2013). Propellantless Propulsion with Negative Matter Generated by Electric Charges (PDF). 49th AIAA/ASME/SAE/ASEE Joint Propulsion Conference. San Jose, CA.
24. Gravitational Attenuating Material Ronald J. Kita https://pdfpiw.uspto.gov/.piw?PageNum=0&docid=08901943&IDKey=74419F9AD76C%0D%0A&HomeUrl=http%3A%2F%2Fpatft.uspto.gov%2Fnetacgi%2Fnph-Parser%3FSect1%3DPTO2%2526Sect2%3DHITOFF%2526p%3D1%2526u%3D%25252Fnetahtml%25252FPTO%25252Fsearch-bool.html%2526r%3D1%2526f%3DG%2526l%3D50%2526co1%3DAND%2526d%3DPTXT%2526s1%3D%252522kita%252Bronald%252522%2526OS%3D%252522kita%252Bronald%252522%2526RS%3D%252522kita%252Bronald%252522
25. Gravitational attenuating material (Patent) https://pubchem.ncbi.nlm.nih.gov/patent/US-8901943-B1
26. Gravitational attenuating material Google Patents https://patents.google.com/patent/US8901943B1/en

External links

• Martins, Roberto de Andrade (1 December 1998). "The Search for Gravitational Absorption in the Early 20th Century". In Goenner, Hubert; Renn, Jürgen; Ritter, Jim; Sauer, Tilman (eds.). The Expanding Worlds of General Relativity. Springer Science & Business Media. pp. 3–44. ISBN 978-0-8176-4060-6.