Wow! signal

The Wow! signal was a strong narrowband radio signal detected on August 15, 1977, by Ohio State University's Big Ear radio telescope in the United States, then used to support the search for extraterrestrial intelligence. The signal appeared to come from the direction of the constellation Sagittarius and bore the expected hallmarks of extraterrestrial origin.

The Wow! signal represented as "6EQUJ5". The original printout with Ehman's handwritten exclamation is preserved by Ohio History Connection.[1]

Astronomer Jerry R. Ehman discovered the anomaly a few days later while reviewing the recorded data. He was so impressed by the result that he circled on the computer printout the reading of the signal's intensity, "6EQUJ5", and wrote the comment "Wow!" beside it, leading to the event's widely used name.[2]

The entire signal sequence lasted for the full 72-second window during which Big Ear was able to observe it, but has not been detected since, despite several subsequent attempts by Ehman and others. Many hypotheses have been advanced on the origin of the emission, including natural and human-made sources, but none of them adequately explain the signal.

Although the Wow! signal had no detectable modulation—a technique used to transmit information over radio waves—it remains the strongest candidate for an extraterrestrial radio transmission ever detected.[3]

Background

In a 1959 paper, Cornell University physicists Philip Morrison and Giuseppe Cocconi had speculated that any extraterrestrial civilization attempting to communicate via radio signals might do so using a frequency of 1420 megahertz (21-centimeter spectral line), which is naturally emitted by hydrogen, the most common element in the universe and therefore likely familiar to all technologically advanced civilizations.[4]

In 1973, after completing an extensive survey of extragalactic radio sources, Ohio State University assigned the now-defunct Ohio State University Radio Observatory (nicknamed "Big Ear") to the scientific search for extraterrestrial intelligence (SETI), in the longest-running program of this kind in history.[5] The radio telescope was located near the Perkins Observatory on the campus of Ohio Wesleyan University in Delaware, Ohio.[6][7]

By 1977, Ehman was working at the SETI project as a volunteer; his job involved analyzing by hand large amounts of data processed by an IBM 1130 computer and recorded on line printer paper. While perusing data collected on August 15 at 22:16 EDT (02:16 UTC), he spotted a series of values of signal intensity and frequency that left him and his colleagues astonished.[4] The event was later documented in technical detail by the observatory's director.[8]

Signal measurement

Plot of signal intensity versus time fitted with a Gaussian function.

The string 6EQUJ5, commonly misinterpreted as a message encoded in the radio signal, represents in fact the signal's intensity variation over time, expressed in the particular measuring system adopted for the experiment. The signal itself appeared to be an unmodulated continuous wave, although any modulation with a period of less than 10 seconds or longer than 72 seconds would not have been detectable.[9][10]

Intensity

The signal intensity was measured as signal-to-noise ratio, with the noise (or baseline) averaged over the previous few minutes. The signal was sampled for 10 seconds and then processed by the computer, which took 2 seconds. The result for each frequency channel was output on the printout as a single alphanumeric character, representing the 10-second average intensity, minus the baseline, expressed as a dimensionless multiple of the signal's standard deviation.[11]

In this particular intensity scale, a space character denoted an intensity between 0 and 1, that is between baseline and one standard deviation above it. The numbers 1 to 9 denoted the correspondingly numbered intensities (from 1 to 9); intensities of 10 and above were indicated by a letter: "A" corresponded to intensities between 10 and 11, "B" to 11 to 12, and so on. The Wow! signal's highest measured value was "U" (an intensity between 30 and 31), which is thirty standard deviations above background noise.[2][11]

Frequency

John Kraus, the director of the observatory, gave a value of 1420.3556 MHz in a 1994 summary written for Carl Sagan.[8] However, Ehman in 1998 gave a value of 1420.4556±0.005 MHz.[12] This is (50±5 kHz) above the hydrogen line value (with no red- or blue-shift) of 1420.4058 MHz. If due to blue-shift, it would correspond to the source moving about 10 km/s (6.2 mi/s) towards Earth.

A heat map of the computer printout, giving a spectrogram of the beam; the Wow! signal appears as a bright spot in the lower left.

An explanation of the difference between Ehman's value and Kraus's can be found in Ehman's paper. The first local oscillator in the telescope's radio receiver was specified to a frequency value of 1450.4056 MHz. However, the university's purchasing department made a typographical error in the order form, instead obtaining an oscillator with frequency 1450.5056 MHz (i.e., 0.1 MHz higher than desired). The software used in the experiment was then written to adjust for this error. When Ehman computed the frequency of the Wow! signal, he took this error into account.

Bandwidth

The Wow! signal had a bandwidth of less than 10 kHz. It is considered narrowband emission in the sense that its fractional bandwidth was relatively small (~1%). However, the 10 kHz bandwidth is not small compared to the bandwidth of some astrophysical masers (~1 kHz) or to the frequency resolution of modern narrowband SETI searches (~1 Hz).[13] The Big Ear telescope was equipped with a receiver capable of measuring fifty 10 kHz-wide channels. The output from each channel was represented in the computer printout as a column of alphanumeric intensity values. The Wow! signal is essentially confined to one column.[12]

Time variation

At the time of the observation, the Big Ear radio telescope was only adjustable for altitude (or height above the horizon), and relied on the rotation of the Earth to scan across the sky. Given the speed of Earth's rotation and the spatial width of the telescope's observation window, the Big Ear could observe any given point for just 72 seconds.[14] A continuous extraterrestrial signal, therefore, would be expected to register for exactly 72 seconds, and the recorded intensity of such signal would display a gradual increase for the first 36 seconds—peaking at the center of the observation window—and then a gradual decrease as the telescope moved away from it. All these characteristics are present in the Wow! signal.[15][16]

Celestial location

The two regions of space in the constellation Sagittarius from where the Wow! signal may have originated. The ambiguity is due to how the telescope was designed. For clarity, the widths (right ascension) of the red bands have been exaggerated.

The precise location in the sky where the signal apparently originated is uncertain due to the design of the Big Ear telescope, which featured two feed horns, each receiving a beam from slightly different directions, while following Earth's rotation. The Wow! signal was detected in one beam but not in the other, and the data was processed in such a way that it is impossible to determine which of the two horns received the signal.[17] There are, therefore, two possible right ascension (RA) values for the location of the signal (expressed below in terms of the two main reference systems):[18]

B1950 equinox J2000 equinox
RA (positive horn) 19h22m24.64s ± 5s 19h25m31s ± 10s
RA (negative horn) 19h25m17.01s ± 5s 19h28m22s ± 10s

In contrast, the declination was unambiguously determined to be as follows:

B1950 equinox J2000 equinox
Declination −27°03′ ± 20′ −26°57′ ± 20′

The galactic coordinates for the positive horn are l=11.7°, b=−18.9°, and for the negative horn l=11.9°, b=−19.5°, both being therefore about 19° toward the southeast of the galactic plane, and about 24° or 25° east of the Galactic Center. The region of the sky in question lies northwest of the globular cluster M55, in the constellation Sagittarius, roughly 2.5 degrees south of the fifth-magnitude star group Chi Sagittarii, and about 3.5 degrees south of the plane of the ecliptic. The closest easily visible star is Tau Sagittarii.[19]

Initially, no nearby Sun-like stars were known to lie within the antenna coordinates, although in any direction the antenna pattern would encompass about six distant Sun-like stars as estimated in 2016.[9] In 2022, a paper published in the International Journal of Astrobiology identified three likely Sun-like stars within the antenna-pointed coordinates. The better characterized star, 2MASS 19281982-2640123, is located 1,800 light years away, only 132 light years away from Maccone's estimation where an intelligent civilization is more likely to exist.[20] The other two candidates, 2MASS 19252173-2713537 and 2MASS 19282229-2702492, were insufficiently characterized but still likely to be Sun-like stars. Also, 14 other catalogued stars at the antenna coordinates may still turn out to be similar to the Sun after more data becomes available.[21][22][23] As a response to the discovery, Breakthrough Listen conducted the first targeted search for the Wow! Signal in its first collaboration between the Green Bank Telescope and the Allen Telescope Array of the SETI Institute.[24][25] The observations were performed on May 21, 2022, lasting 1 hour from Greenbank, 35 minutes from ATA, and 9 minutes and 40 seconds simultaneously.[26] No technosignature candidates were found.[27]

Hypotheses on the signal's origin

A number of hypotheses have been advanced as to the source and nature of the Wow! signal, but none have achieved widespread acceptance. Interstellar scintillation of a weaker continuous signal—similar in effect to atmospheric twinkling—could be an explanation, but that would not exclude the possibility of the signal being artificial in origin. The significantly more sensitive Very Large Array did not detect the signal, and the probability that a signal below the detection threshold of the Very Large Array could be detected by the Big Ear due to interstellar scintillation is low.[28] Other hypotheses include a rotating lighthouse-like source, a signal sweeping in frequency, or a one-time burst.[18]

Ehman said in 1994: "We should have seen it again when we looked for it 50 times. Something suggests it was an Earth-sourced signal that simply got reflected off a piece of space debris."[29] He later somewhat recanted his skepticism, after further research showed the unrealistic requirements that a space-borne reflector would need to have to produce the observed signal.[12] The signal's frequency of 1420 MHz is also part of a protected spectrum:[30][31] a frequency range reserved for astronomical research in which terrestrial transmissions are forbidden, although a 2010 study documented several instances of terrestrial sources either interfering from adjacent frequency bands or illegally transmitting within the spectrum.[32] In a 1997 paper, Ehman resists "drawing vast conclusions from half-vast data"—acknowledging the possibility that the source may have been military or otherwise a product of Earth-bound humans.[33] In a 2019 interview with John Michael Godier, Ehman stated: "I'm convinced that the Wow! signal certainly has the potential of being the first signal from extraterrestrial intelligence."[34]

METI president Douglas Vakoch told Die Welt that any putative SETI signal detections must be replicated for confirmation, and the lack of such replication for the Wow! signal means it has little credibility.[35]

Discredited hypotheses

In 2017, Antonio Paris, Assistant Professor of Astronomy and Astrophysics at St. Petersburg College, Florida,[36] proposed that the hydrogen cloud surrounding two comets, 266P/Christensen and 335P/Gibbs, now known to have been in the same region of the sky, could have been the source of the Wow! signal.[37][38][39] This hypothesis was dismissed by astronomers, including members of the original Big Ear research team, as the cited comets were not in the beam at the correct time. Furthermore, comets do not emit strongly at the frequencies involved, and there is no explanation for why a comet would be observed in one beam but not in the other.[40][41][42]

Searches for recurrence of the signal

Several attempts were made by Ehman and other astronomers to recover and identify the signal. The signal was expected to occur three minutes apart in each of the telescope's feed horns, but that did not happen.[16] Ehman unsuccessfully searched for recurrences using Big Ear in the months after the detection.[28]

In 1987 and 1989, Robert H. Gray searched for the event using the META array at Oak Ridge Observatory, but did not detect it.[28][43] In a July 1995 test of signal detection software to be used in its upcoming Project Argus, SETI League executive director H. Paul Shuch made several drift-scan observations of the Wow! signal's coordinates with a 12-meter radio telescope at the National Radio Astronomy Observatory in Green Bank, West Virginia, also achieving a null result.

In 1995 and 1996, Gray again searched for the signal using the Very Large Array, which is significantly more sensitive than Big Ear.[28][43] Gray and Simon Ellingsen later searched for recurrences of the event in 1999 using the 26-meter radio telescope at the University of Tasmania's Mount Pleasant Radio Observatory.[44] Six 14-hour observations were made at positions in the vicinity, but nothing like the Wow! signal was detected.[16][43]

Response

In 2012, on the 35th anniversary of the Wow! signal, Arecibo Observatory beamed a digital stream towards Hipparcos 34511, 33277, and 43587.[45] The transmission consisted of approximately 10,000 Twitter messages solicited for the purpose by the National Geographic Channel, bearing the hashtag "#ChasingUFOs" (a promotion for one of the channel's TV series).[46] The sponsor also included a series of video vignettes featuring verbal messages from various celebrities.[47]

To increase the probability that any extraterrestrial recipients would recognize the signal as an intentional communication from another intelligent life form, Arecibo scientists attached a repeating-sequence header to each individual message, and beamed the transmission at roughly 20 times the power of the most powerful commercial radio transmitter.[46]

See also

References

  1. Wood, Lisa (July 3, 2010). "WOW!". Ohio History Connection Collections Blog. Retrieved July 2, 2016.
  2. Krulwich, Robert (May 29, 2010). "Aliens Found In Ohio? The 'Wow!' Signal". National Public Radio. Retrieved July 2, 2016.
  3. Ferreira, Becky (May 18, 2014). "The Wow! Signal Is The Strongest Candidate For an Alien Radio Transmission Yet". VICE. Retrieved January 3, 2022.
  4. Kiger, Patrick J. (June 21, 2012). "What is the Wow! signal?". National Geographic Channel. Retrieved July 2, 2016.
  5. "Big Ear Radio Observatory – Big Ear Entered in Guinness Book of Records". www.bigear.org. Retrieved May 30, 2021.
  6. "Big Ear Radio Observatory – Ohio History Central". ohiohistorycentral.org. Retrieved May 30, 2021.
  7. "Radio Astronomy and SETI – Big Ear Radio Observatory Memorial Website". www.bigear.org. Retrieved May 30, 2021.
  8. John Kraus, Director, Ohio State Radio Observatory 31, January 1994, "The Tantalizing WOW! Signal", Copy of letter to Carl Sagan containing an unpublished paper describing the event.
  9. Shuch, H. Paul (November 9, 1996). "SETI Sensitivity: Calibrating on a Wow! Signal". SETI League. Retrieved June 25, 2016.
  10. Ehman, Jerry R. (2011). Shuch, H. Paul (ed.). Searching for Extraterrestrial Intelligence: SETI Past, Present, and Future. Springer Science & Business Media. p. 59. ISBN 9783642131967.
  11. Ehman, Jerry. "Explanation of the Code "6EQUJ5" On the Wow! Computer Printout". Retrieved July 2, 2016.
  12. Ehman, Jerry R. (February 3, 1998). "The Big Ear Wow! Signal. What We Know and Don't Know About It After 20 Years". Retrieved July 2, 2016.
  13. Margot, Jean-Luc; et al. (January 6, 2021). "A Search for Technosignatures around 31 Sun-like Stars with the Green Bank Telescope at 1.15–1.73 GHz". The Astronomical Journal. 161 (2): 55. arXiv:2011.05265. Bibcode:2021AJ....161...55M. doi:10.3847/1538-3881/abcc77. S2CID 226290131.
  14. Dunning, Brian (December 25, 2012). "Skeptoid #342: Was the Wow! Signal Alien?". Skeptoid. Retrieved October 8, 2016.
  15. Deffree, Suzanne (August 15, 2019). "Big Ear receives 'Wow! Signal,' August 15, 1977". EDN Moments. Retrieved July 2, 2016.
  16. Shostak, Seth (December 5, 2002). "Interstellar Signal From the 70s Continues to Puzzle Researchers". Space.com. Retrieved July 2, 2016.
  17. "Big Ear's Twin Feed Horns". Retrieved July 2, 2016.
  18. Gray, Robert; Marvel, Kevin (2001). "A VLA Search for the Ohio State 'Wow'" (PDF). The Astrophysical Journal. 546 (2): 1171–77. Bibcode:2001ApJ...546.1171G. doi:10.1086/318272. S2CID 17141857.
  19. Ehman, Jerry R. (May 28, 2010). "The Big Ear Wow! Signal (30th Anniversary Report)". North American AstroPhysical Observatory. Retrieved July 2, 2016.
  20. Maccone, Claudio. "Statistical drake equation". {{cite journal}}: Cite journal requires |journal= (help)
  21. Caballero, Alberto (2022). "An approximation to determine the source of the WOW! Signal". International Journal of Astrobiology. 21 (3): 129–136. arXiv:2011.06090. Bibcode:2022IJAsB..21..129C. doi:10.1017/S1473550422000015. ISSN 1473-5504. S2CID 226307031.
  22. Anderson, Paul Scott (December 2, 2020). "Did the Wow! signal come from this star?". EarthSky. Retrieved May 14, 2022.
  23. Adam Mann (May 24, 2022). "Famous 'alien' Wow! signal may have come from distant, sunlike star". Space.com. Retrieved June 6, 2022.
  24. "1st Coordinated Green Bank Telescope/Allen Telescope Array Observes Possible Source of the WOW! Signal".
  25. Elizabeth Howell (November 7, 2022). "No signs of alien life found near source of famous 'Wow!' signal". Space.com. Retrieved November 9, 2022.
  26. Perez, Karen I.; Farah, Wael; Sheikh, Sofia Z.; Croft, Steve; Siemion, Andrew; Pollak, Alexander W.; Brzycki, Bryan; Cruz, Luigi F.; Czech, Daniel; DeBoer, David; Drew, Jamie; Gajjar, Vishal; Garrett, Michael A.; Isaacson, Howard; Lebofsky, Matt (September 26, 2022). "Breakthrough Listen Search for the WOW! Signal*". Research Notes of the AAS. 6 (9): 197. Bibcode:2022RNAAS...6..197P. doi:10.3847/2515-5172/ac9408. ISSN 2515-5172. S2CID 252540293.
  27. "Breakthrough Listen Search for the WOW! Signal". seti.berkeley.edu. Retrieved November 9, 2022.
  28. "The 'Wow!' Signal". Discovery Channel. Archived from the original on May 7, 2016. Retrieved July 2, 2016.
  29. Kawa, Barry (September 18, 1994). "The Wow! signal". Cleveland Plain Dealer. Retrieved July 2, 2016.
  30. "Significant Radio Astronomy Frequencies". SETI League. Retrieved July 2, 2016.
  31. Committee on Radio Astronomy Frequencies Handbook for Radio Astronomy (PDF) (3rd ed.). European Science Foundation. 2005. p. 101. Archived from the original (PDF) on June 3, 2016. Retrieved November 29, 2007.
  32. "SMOS Water mission winning battle with interference". The European Space Agency. October 6, 2010. Retrieved August 24, 2021.
  33. Frank, Adam (July 10, 2012). "Talking To Aliens From Outer Space". NPR. Retrieved July 2, 2016.
  34. Ehman, Jerry (December 20, 2019). "The Wow! Signal with Discoverer Dr. Jerry Ehman". Event Horizon (Interview). Interviewed by John Michael Godier. Retrieved June 11, 2022.
  35. Marsiske, Hans-Arthur (September 12, 2007). "Welche Sprache sprechen Außerirdische?". Die Welt (in German).
  36. "Prof. Antonio Paris | Faculty Profile | SPC".
  37. Paris, Antonio (January 1, 2016). "Hydrogen Clouds from Comets 266/P Christensen and P/2008 Y2 (Gibbs) are Candidates for the Source of the 1977 "WOW" Signal". Journal of the Washington Academy of Sciences. arXiv:1706.04642. Bibcode:2017arXiv170604642P. Archived from the original on June 15, 2017. Retrieved June 13, 2017.
  38. Paris, Antonio (April 1, 2017). "Hydrogen Line Observations of Cometary Spectra at 1420 MHZ". Journal of the Washington Academy of Sciences. 103 (2). Retrieved June 13, 2017.
  39. Paris, Antonio; Davies, Evan (2017). "Hydrogen Clouds from Comets 266P Christensen and P2008 Y2 (Gibbs) are Candidates for the Source of the 1977 WOW!Signal". arXiv:1706.04642 [astro-ph.EP].
  40. Dixon, Robert S, Dr. "Rebuttal of the claim that the "WOW!" signal was caused by a comet". NAAPO. North American Astrophysical Observatory. Retrieved June 13, 2017.{{cite web}}: CS1 maint: multiple names: authors list (link)
  41. Emspak, Jesse (January 11, 2016). "Famous Wow! signal might have been from comets, not aliens". New Scientist. Retrieved June 13, 2017.
  42. Mack, Eric (June 14, 2017). "Aliens could still explain the 'Wow signal,' scientists say". CNET. Retrieved May 31, 2021.
  43. Gray, Robert H (2012). The Elusive WOW: Searching for Extraterrestrial Intelligence. Chicago: Palmer Square Press. ISBN 978-0-9839584-4-4.
  44. Gray, Robert; Ellingsen, S. (2002). "A Search for Periodic Emissions at the Wow Locale". The Astrophysical Journal. 578 (2): 967–71. Bibcode:2002ApJ...578..967G. doi:10.1086/342646.
  45. Noyes, Katherine (November 22, 2012). "Earth Replies to Space Signal After 35-Year Delay". TechNewsWorld. Archived from the original on November 30, 2020. Retrieved October 29, 2020.
  46. Wolchover, Natalie (June 27, 2012). "Possible Alien Message to Get Reply from Humanity". Discovery News.
  47. Staff (August 12, 2012). "Humanity Responds to 'Alien' Wow Signal, 35 Years Later". Space.com.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.