![\"EU2014](\"https:\/\/www.thunderbolts.info\/wp\/wp-content\/uploads\/2013\/12\/EU2014-Wal-IMG_3039-550X440-280x223.jpg\")
Congratulations Rosetta, Shame About The Science\u2026\nBy Wal Thornhill<\/h1>\n
Congratulations Rosetta, Shame About The Science\u2026 The Rosetta mission was named after the famed Rosetta Stone, which allowed the decipherment of ancient Egyptian hieroglyphs. The term \u2018<\/span>Rosetta Stone\u2019<\/i><\/span> is now used in other contexts as the name for the essential clue to a new field of knowledge. But context\u00a0is a\u00a0problem because\u00a0the remote past is inaccessible. So we have simply projected our modern experience\u00a0on to the past and come up with stories\u00a0to satisfy our craving\u00a0for order and certainty. Mysteries still abound in Egyptology and comet science but they\u00a0don\u2019t feature in\u00a0the stories\u00a0we are confidently\u00a0taught.<\/span><\/p>\n Here on the left is an artist\u2019s impression of a comet surface before the first flyby of \u00a0the nucleus of a comet on March 14, 1986. It shows icy vapours wafting into space. In the centre is an artist\u2019s impression of the Philae lander on the surface of comet 67 P where you can see the surface still appears icy, the only concession to images of other comet nuclei being the crater and ridges. On the right is the real surface of comet 67 P, which is actually blacker than photocopier toner. But despite the stark reality,\u00a0the story of comets remains\u00a0unchanged. The ice \u2018must be\u2019 buried beneath that rocky-looking crust. This is a\u00a0favourite recourse of astrophysicists to have mechanisms\u00a0buried out of sight inside celestial bodies or black holes where they are difficult or impossible to verify. But this time the Philae lander may have sent sufficient information to expose this convenient fiction.<\/span><\/p>\n So powerful is the belief in the story of comets as primordial dirty-ice bodies that cognitive dissonance is on show when we get new data. And with the Rosetta spacecraft orbiting comet 67 P at a distance of a few tens of kilometers there is a flood of new data. At a media briefing following the Philae Lander\u2019s unexpected multiple touchdowns, Eric Hand of Science magazine asked how cometary processes might account for the comet\u2019s rocky appearance. Holger Sierks, the OSIRIS Imaging System Principal Investigator replied, \u201cit\u2019s rocky-like stuff, but not rock.\u201d<\/em> This unequivocal statement is based on the measured average density of the comet, which is less than half that of water. Rock has a density roughly between 2.5 and 3 times that of water. Even if the comet were made of water ice, the only way to match such a low density is to require the comet nucleus to be porous. So the Philae lander harpoons were designed to penetrate compacted snow. It\u2019s fortunate the harpoons\u00a0didn\u2019t fire because the ricochet from solid rock would probably have the lander ricocheting back into space to be lost forever, a present danger I suggested before the landing attempt. As it happened, the lander\u2019s multiple bounces over\u00a0a hard surface caught scientists by surprise but happily Philae was able to remain on the comet\u00a0and return useful data before its battery power was spent. I expect data about the interior of the comet to be confounding with little sign of the porosity required to produce\u00a0its low measured\u00a0density. It is even possible that the comet has internal cavities, which is not expected by the accretion model.<\/p>\n The selective blindness that occurs when information\u00a0doesn\u2019t fit our preconceptions is shown by the apparent rockiness of other comets and asteroids that have been imaged in earlier close flybys. Why were ESA scientists surprised by the jagged, rocky appearance of comet 67 P when the Stardust mission to comet Wild 2 in 2004 showed (above) the same features? \u201c<\/em><\/span>Pinnacles range from tens of meters to over 100 m in height, and they have varied shapes including spires with pointed tops near the resolution of the images. The pinnacles were not anticipated land forms on primitive bodies, and their origin on Wild 2 is a mystery.\u201d<\/em><\/p>\n So it is instructive to re-examine the comments made on the first close flyby of\u00a0an active comet nucleus, which took place at comet Halley in March 1986. The editor of Nature, John Maddox wrote in a supplement on May 15, 1986 devoted to the first results, \u201cthere is a sense, even in science, when the journalistic principle applies that first impressions have a value of their own.\u201d<\/em> I would argue that first impressions are priceless because the surprises expressed are unfiltered by subsequent accommodation to the \u2018one true story.\u2019 Maddox summarizes the first reports, \u201cWhat stands out from this symposium of papers is the surprising complexity of the environment of comet Halley.\u201d<\/em>No one was able or courageous enough to \u2018think outside the box\u2019 and suggest that the new discoveries invalidated the old story of dust and gas blowing away from an icy\u00a0comet in the solar wind. There was no mention of scientists in the 19<\/span>th<\/span><\/sup> century who compared cometary appearance and behavior to low-pressure electrical discharge phenomena in Geissler tubes. That model was simple and it made sense. But scientists in the space age have been indoctrinated that electricity plays no role in space. Meanwhile the results were no surprise to a few scientists who a decade or more before had published, perforce obscurely, a model of the Sun and comets as electrically discharging bodies. They were early pioneers of the Electric Universe\u00a0who saw comets as a basic test of that paradigm.<\/span><\/p>\n We are\u00a0taught that comets are \u2018leftover\u2019 primordial bodies of interstellar dust and water ice from which the Sun and planets were born. A bizarre ESA publicity video for the Rosetta mission argues that the Earth\u2019s oceans were filled early on by comet impacts. Incongruously, ESA released a report on 10th December titled, \u201cROSETTA FUELS DEBATE ON ORIGIN OF EARTH\u2019S OCEANS,\u201d that discredits that notion. \u00a0It has been found that the D\/H ratio of deuterium (D, proton plus a neutron) to hydrogen (H, proton) from comet 67 P is three times that found in our oceans. So now attention is turning to asteroids as the source of Earth\u2019s water because meteorites are considered to be fragments of rocky asteroids and meteorites generally have a D\/H ratio similar to the Earth. This is a typical response to contrary evidence in astronomy. The myth must be maintained even though asteroids and comets show so little evidence of surface water. However, using deuterium as a marker relies on assumptions about its origin\u00a0in the hypothetical big bang and destruction in stellar nucleosynthesis, which are both unverifiable.<\/p>\n Returning to comet Halley in 1986, water molecules are supposed to sublimate (change directly from solid to gas) off the comet nucleus in the heat of the Sun. Later, ultraviolet light from the Sun is thought to split the water molecule into OH and H. So we should expect more H<\/span>2<\/span><\/sub>O near the nucleus than OH. However, the Vega 2 spacecraft found the reverse, which \u201cmay indicate the existence of parents of OH other than H<\/em><\/span>2<\/span><\/sub><\/em>O.\u201d<\/em> This finding supports the Electric Universe\u00a0model, which proposes comet nuclei as fragments of planetary surfaces. Their rocky surfaces are spark-machined by a cold cathode type of coronal discharge. The electricity is provided by the comet\u2019s motion in the solar plasma\u2019s weak electric field (which is also responsible for the acceleration of the solar wind away from the Sun despite its powerful gravity). OH is produced easily from clay and rock minerals by an electric discharge.<\/span><\/p>\n The small size of the dust particles from comet Halley was a surprise. \u201cThe dust particle mass spectra do not exhibit the expected low-mass cutoff at 10<\/em><\/span>-14<\/span><\/sup> gm; instead they continue to rise to 10<\/span>-16<\/span><\/sup><\/em> gm.\u201d \u201cThe most striking feature is the large number of low-mass particles.\u201d \u201cIndeed, the first particles encountered at the \u2018fringes\u2019 of the coma had the lowest masses measured, instead of the higher masses predicted by the \u2018fountain\u2019 model first introduced by Eddington and later widely developed to predict the mass distribution of cometary dust.\u201d<\/em> Low mass particles fit with electrical sputtering of surface atoms and molecules but not with the standard model of gas jet dispersal of interstellar dust grains trapped in dusty ice. Electrostatic clumping of sputtered atoms and molecules gives rise to the extreme fluffiness of dust particles, remarked upon by Rosetta mission scientists. But it gives a misleading impression of the composition and structure of a comet. As for Eddington\u2019s \u2018fountain\u2019 model, \u201cthe coma is highly dynamical on all spatial and temporal scales, suggesting a complex structure of localized regions of dust emission from the nucleus,\u201d<\/em> says one report. And gas expands explosively into a vacuum rather than forming a fountain. Such a gas model cannot explain a tiny comet nucleus, \u201cwhich near perihelion can produce a hydrogen corona larger than the Sun.\u201d<\/em><\/span><\/p>\n Halley has a high gas and dust production rate, comparable to those of new comets. So it may have\u00a0more to tell us about energetic phenomena than the short-period comet 67 P. The Giotto high-resolution camera imaging the nucleus suffered a power supply glitch about 12 seconds before closest approach to comet Halley. But it was the first to show a comet nucleus to be cratered and its emissions localized to high-energy jets. The inability to accept this jarring data is highlighted in the bland artistic renditions of comet nuclei in science news, which look nothing like the real thing. The power supply problem may have a simple explanation related to the electrical charging of the spacecraft\u00a0in the\u00a0comet\u2019s highly active environment.<\/p>\n
\nCongratulations to the\u00a0team responsible for the success of the Rosetta mission<\/span>\u00a0to comet 67 P Churyumov-Gerasimenko (henceforth 67 P). However, it\u2019s a shame that scientists misled the engineers with their cherished story of icy comets, which resulted in an inappropriate design for the lander, Philae. Chris Reeve writes,\u00a0\u201cWe train all physicists to adopt the same basic scientific framework \u2014 at the expense of also teaching them how to analyze the same phenomenon from multiple perspectives \u2014 and then we wonder why certain problems remain unresolved despite the investment of massive resources, people and time. The very act of rigidly training everybody in the same framework seems to me the problem which precludes their solution.\u201d<\/em><\/p>\n![\"Artist's](\"http:\/\/www.holoscience.com\/wp\/wp-content\/uploads\/2014\/12\/Artists-impressions-cf-P-67.jpg\")
<\/a><\/p>\n<\/a><\/p>\n<\/a>This image of Halley s Comet was taken on 14 March 1986 during the fly-by of ESA s Giotto space probe. \u00a9 MPS<\/span><\/p>\n