Below is the online edition of In the Beginning: Compelling Evidence for Creation and the Flood, by Dr. Walt Brown. Copyright © Center for Scientific Creation. All rights reserved.

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[ The Fountains of the Great Deep > The Origin of Asteroids, Meteoroids, and Trans-Neptunian Objects > References and Notes ]

References and Notes

1. “About 16% of near-Earth asteroids larger than 200 meters in diameter [those detected by Earth-based radar] may be binary systems.” J. L. Margot, “Binary Asteroids in the Near-Earth Object Populations,” Science, Vol. 296, 24 May 2002, p. 1445.

u www.johnstonsarchive.net/astro/asteroidmoons.html

2. D. T. Britt et al., “Asteroid Density, Porosity, and Structure,” Asteroids III, editors W. F. Bottke et al. (Tucson, Arizona: University of Arizona Press, 2002), pp. 485–500.

3. www.minorplanetcenter.org/iau/MPCORB.html

4. “A common misconception is that asteroids are the remains of a large planet that mysteriously exploded long ago. Today there is hardly enough material in the asteroid belt to make a small moon.”  Derek C. Richardson, “Giants in the Asteroid Belt,” Nature, Vol. 411, 21 June 2001, p. 899.

5. Jupiter’s gravity is often given as a simplistic reason a planet did not form. If that were true, why didn’t Jupiter prevent even dust or the tiniest grains of sand from forming big rocks? Actually, Jupiter’s gravity flings asteroids from the asteroid belt at a rate that is rapid relative to the evolutionist’s age for the solar system—4,600,000,000 years.

u One of the big problems in the current story on how asteroids evolved is: “How do gas and dust in a hypothetical solar nebula condense into dense boulders (asteroids, planetesimals, and meteoroids)?” As one expert on meteorites admitted:

even Earth’s most evolved brains still haven’t grasped why space dust condensed into boulders. William Speed Weed, “Philip Bland: Meteor Man,” Discover, Vol. 22, March 2001, p. 46.

6. “Although Jovian perturbations are widely invoked to explain [why asteroids failed to grow to become planets in] the asteroid belt, the precise mechanism that halted planet formation is still a subject of some dispute.”  Jack J. Lissauer and Glen R. Stewart, “Growth of Planets from Planetesimals,” Protostars and Planets III, editors Eugene H. Levy and Jonathan I. Luine (London: The University of Arizona Press, 1993), pp. 1080–1081.

These authors then explain why the several explanations proposed are unsatisfactory.

7. “The predicted mean time between major asteroid collisions [for each asteroid] is about 5% of the age of the solar system. All asteroids should already be highly fragmented unless their origin is relatively recent, as in the exploded planet theory.”  Tom C. Van Flandern, Dark Matter, Missing Planets and New Comets (Berkeley, California: North Atlantic Books, 1993), p. 216.

8. The estimated mass of all asteroids (excluding TNOs) is 2.6 x 10²⁴ grams. For a fuller discussion of the mass launched, see page 620.

9. “Here we report the detection of water vapour around Ceres, with at least 10²⁶ molecules being produced per second, [13 pounds/sec] originating from localized sources that seem to be linked to mid-latitude regions on the surface.” Michael Kuppers et al., “Localized Sources of Water Vapour on the Dwarf Planet (1) Ceres,” Nature, Vol. 505, 23 January 2014, p. 525.

10. “.... Ceres is a partially differentiated body, with a rocky core overlaid by a volatile-rich shell.” R. S. Park et al. “A Partially Differentiated Interior for (1) Ceres Deduced from its Gravity Field and Shape,” Nature, Vol. 537, 22 September 2016, p. 515.

11. “But it was the components of the cliffs and pits that caught Sierks’ eye. Embedded along their edges are strange spheres, most between 1 and 3 meters in diameter.” Andrew Grant, “Comet May Expose Its Building Blocks,” Science News, Vol. 187, 10 January 2015, p. 8.

u “The researchers described three-meter-wide pebble-like features that are found all over the comet, which they nicknamed ‘goosebumps’.” Elizabeth Gibney, “Philae Hunt Hangs in the Balance,” Nature, Vol. 517, 29 January 2015, p. 537.

u “In the walls of other pits, OSIRIS [Rosetta’s powerful camera] has spotted what could be features dating back to the comet’s formation: what the team calls “goosebumps” or “dinosaur eggs,” nodules about 3 meters across that could represent the fundamental chunks of material that coalesced into 67P.” Eric Hand, “Comet Close-up Reveals a World of Surprises,” Science, Vol. 347, 23 January 2015, p. 358.

u Eric Hand, “‘Dinosaur Eggs’ Spotted on Rosetta’s Comet,” Science Online, 18 December 2014.

12. Erik Asphaug, “The Small Planets,” Scientific American, Vol. 282, May 2000, p. 48.

13. Some of this water vapor also condensed as frost in permanently shadowed craters on the Moon, Mercury, and Mars.

14. Some asteroids, called C-type asteroids, are darker than coal! They typically lie in the outer part of the asteroid belt. Lighter-colored, S-type asteroids are generally in the inner part of the belt. Darker asteroids (which both absorb and radiate heat more efficiently) have both hotter hot sides and colder cold sides. [See Figure 182.] Those greater temperature differences produced greater thrust, which moved C-type asteroids farther from the Sun.

15. The size, shape, and inclination of a body’s orbital path around the Sun is described by three numbers:

     a (the semimajor axis or size of the orbit),

     e (the eccentricity or shape of the orbit), and

     i (the inclination or tilt of the orbital plane with respect to Earth’s orbital plane).

In other words, in a special three-dimensional coordinate system (a, e, and i), each of a thousand scattered points represented an asteroid starting out on a different orbit from some point on Earth’s orbit.

The forces that acted on asteroids were gravity, drag, and thrust. (Today, drag and thrust are zero.) Although gravity is easy to model, it is virtually impossible to determine what the drag and thrust were and how they diminished in the years after the flood, because experimentally determined relationships are involved. Also, the amount of water vapor placed in orbit may never be known—even approximately. However, drag and thrust can be described with just a few simplifying parameters. (For example, drag is equal to some parameter times velocity squared. That parameter depends on several unknowns, including the density of water vapor which diminishes over time according to a second parameter.)

By fine tuning the parameters for drag and thrust and then simulating the changing orbits as time progressed, I could watch on a computer monitor all those scattered points simultaneously migrate toward the single point (a = 2.8 AU, e = 0, i = 0) representing today’s asteroid belt.

While these functional relationships for drag and thrust are not derivable, they are consistent with the way drag and thrust generally act. It was remarkable that with only a few parameters, nearly an infinite number of points could be “mapped” almost into one point: (a = 2.8 AU, e = 0, i = 0). In physical terms, almost all simulated asteroids, regardless of their initial orbit somewhere in the inner solar system, slowly migrated into the asteroid belt.

16. For simplified explanations, see

v Philip Gibbs, “How Does a Light Mill Work?” 1996 at
http://johanw.home.xs4all.nl/PhysFAQ/General/
LightMill/light-mill.html

v Arthur E. Woodruff, “The Radiometer and How it Does Not Work,” The Physics Teacher, October 1968, pp. 358–363.

17. “In particular, nanotechnology [many small hot edges] could permit for an enhancement of the [radiometer] force by a factor of 10⁷ ....” Marco Scandurra, “Enhanced Radiometric Forces,” 2 February 2008, http://arxiv.org/pdf/physics/0402011.pdf., p. 8.

18. “[‘Goosebumps’] are seen on very steep slopes and on exposed cliff faces, but their formation mechanism is yet to be explained.” ESA/Rosetta/MPS for OSIRIS Team MPS/UPD/LAM/IAA/SSO/INTA/UPM/DASP/IDA

u “The images [taken of comet 67P] revealed ... boulders measuring up to tens of meters, and outlines of near-circular objects about which little is clearly understood.” ESA/Rosetta/NavCam, 19 February 2015.

u “The boulder-like structures that Rosetta has revealed in many places on the surface of 67P/C-G are one of the comet’s most striking and mysterious features.” Jet Propulsion Laboratory, Press Release, 19 February 2015.

19. “Five of the numbered periodic comets are in fact also listed alternatively as numbered minor planets.” Brian G. Marsden and Gareth V. Williams, Catalogue of Cometary Orbits, 17th edition (Cambridge, Massachusetts: Minor Planet Center, 2008), p. 6.

u “Since 2006, however, nine bodies orbiting within the main asteroid belt have been found with physical characteristics similar to comets;” Kristen Mueller and Jake Yeston, “Impulsive Activity,” Science, Vol. 338, 14 December 2012, p. 1397.

20. O. Richard Norton, The Cambridge Encyclopedia of Meteorites (Cambridge, United Kingdom: Cambridge University Press, 2002), p. 186.

21. This may seem counterintuitive, since the pull of gravity on an asteroid is so much less than that of Earth. A particle will slip or roll on any inclined surface if the pushing force exceeds the resisting force holding the particle in place. Both forces are proportional to the local gravity, so the “angle of repose,” even on an asteroid, is still about 30 degrees.

22. Sunlight would quickly break down a free water molecule into hydroxyl (OH) and atomic hydrogen (H). Other gases would also be present.

23. As explained in Figure 179 on page 344, asteroids typically have earthlike spin rates. The hottest “time of day” on a spinning asteroid was not “high noon,” but “several hours after noon,” as it is on Earth. Therefore, the thrust acting on asteroids had a tangential component as well as a radial component. The tangential component steadily added angular momentum to each asteroid’s orbit, allowing it to spiral outward.

24. Consider two gravitational forces acting on a mass, m, at the Earth’s surface. The first, F_E, is caused by the Earth’s mass, M_E, acting, in effect, from the Earth’s center—a distance D_E (4,000 miles) away. The second gravitational force, F_S, is caused by the Sun’s mass, M_S, acting from a distance of D_S (93,000,000 miles). Letting G be the gravitational constant, these forces are:

     

The Sun is 332,900 times more massive than Earth. Dividing the left equation by the right gives:

     

This means that a steady, 1-pound force could lift and accelerate a rock away from the Sun if the rock weighed 1,600 pounds on Earth and the rock were more than 93,000,000 miles above the Sun and far from Earth.

25. Temperatures probably reached 3,000°F (1,650°C). [See "Chondrules" on page 420.] If so, as temperatures steadily rose, quartz would have been the first major mineral in granite to melt. Much of it would have dissolved in the hot, subterranean water.

26. Claims are sometimes made that radioactive decay generated the heat, but standard calculations that would support those speculations are never shown.

27. “... we lack compelling scenarios leading to the origin of iron meteorites ... Early solar system collisions have been called upon to excavate this iron [from the cores of the largest asteroids], although numerical impact models have found this task difficult to achieve, particularly when it is required to occur many dozens of times, yet not a single time for asteroid Vesta.”  Erik Asphaug et al., “Tides Versus Collisions in the Primordial Main Belt,” October 2000, www.aas.org/publications/baas/v32n3/dps2000/545.htm.

28. “[NASA’s model] predicts a dust concentration in the asteroid belt about an order of magnitude higher than the dust density near earth.” J. S. Dohnanyi, “Sources of Interplanetary Dust: Asteroids,” Interplanetary Dust and Zodiacal Light, editors H. Elsässer and H. Fechtig (New York: Springer-Verlag, 1976), p. 189.

29. J. M. Alvarez, “The Cosmic Dust Environment at Earth, Jupiter and Interplanetary Space: Results from Langley Experiments on MTS, Pioneer 10 and 11,” Ibid., p. 181.

u “It can be seen, Fig. 2, that the number density of interplanetary dust inferred from the penetration data is a slowly decreasing function with heliocentric distance [R] ... a distribution that varies as R^-1 [for 1 AU < R < 4 AU].” Dohnanyi, p. 190.

30. Kazushige Tomeoka, “Phyllosilicate Veins in a CI Meteorite: Evidence for Aqueous Alteration on the Parent Body,” Nature, Vol. 345, 10 May 1990, pp. 138–140.

31. “Eros, indeed, has no detectable magnetic field. That’s puzzling because meteorites, which are believed to be fragments of asteroids, possess magnetic fields. How could a chip of an asteroid be magnetic if the parent asteroid isn’t?” Ron Cowen, “Asteroid Eros Poses a Magnetic Puzzle,” Science News, Vol. 159, 2 June 2001, p. 341.

32. Olivine is a class of minerals that includes perhaps half the minerals in the Earth’s crust and upper mantle. Olivine consists of tiny tetrahedra (three-sided pyramids), each composed of a silicon atom surrounded by four oxygen atoms at the pyramid’s corners. The pyramids are tightly stacked together and further strengthened by iron and/or magnesium atoms that fit snugly between the pyramids. In pallasites, the olivine is strictly the magnesium variety, a mineral called forsterite.

At atmospheric pressure, forsterite melts at almost 1900°F., one of the highest melting temperatures of all minerals. The iron variety of olivine, called fayalite, melts at about 1200°F. An iron-nickel mixture melts at about 1300°F. Deep in the Earth, pressures are greater, so melting temperatures are somewhat higher, depending on depth.

The fluttering hydroplates and pounding pillars crushed rock and generated frictional heat along the sliding surfaces. Near those surfaces, minerals that had low melting temperatures, including minerals containing iron and nickel, melted quickly. The dense iron and nickel drained down cracks and displaced upward melted material that was less dense. Even after the large rocks were launched and cooling had begun on their outside surfaces, the extremely hot molten material deep inside the rocks continued to melt other minerals. Before forsterite could melt, the molten iron-nickel steadily froze while forsterite crystals were suspended in a weightless environment within the melt. Pallasites formed.

Notice in Figure 184 that the forsterite crystals are of similar size and uniformly distributed. This is because each microscopic pyramid, drifting weightlessly in the iron-nickel “soup,” had unbalanced electrical charges which pulled nearby pyramids together into a crystalline arrangement.

33. Why could almost no one have imagined this energy source? They visualized phenomena by reasoning only from effects we see today back to possible causes. Had they also reasoned from cause to effect—from water in a subterranean chamber to its consequences (such as tidal pumping producing supercritical water)—they might have realized that large rocks would have been launched from Earth during the flood.

34. “These three different techniques show the MG [main group] pallasites cooled below 975 K at significantly diverse rates. Since samples from the core-mantle boundary should have indistinguishable cooling rates, MG pallasites could not have cooled at this location.” Jijin Yang et al., “Main-Group Pallasites: Thermal History, Relationship to IIIAB Irons, and Origin,” Geochimica et Cosmochimica Acta, Vol. 74, 2010, p. 4471.

35. “These pallasites record substantial magnetic fields, with intensities ranging up to nearly twice that of Earth today.” Benjamin P. Weiss, “A Vitrage of Asteroid Magnetism,” Science, Vol. 338, 16 November 2012, p. 898.

u James F. J. Bryson et al., “Long-Lived Magnetism from Solidification-Driven Convection on the Pallasite Parent Body,” Nature, Vol. 517, 22 January 2015, pp. 472–475.

36. Alan E. Rubin, “What Heated the Asteroids,” Scientific American, Vol. 292, May 2005, pp. 80–87.

37. The following concerns Vesta, the second-most-massive asteroid, whose mean diameter is 326 miles (525 kilometers).

“Spectroscopic observations of Vesta’s surface indicate that it is covered with volcanic basalt, leading researchers to conclude that Vesta’s interior once melted. The cause of the heating cannot be long-lived radioisotopes; given the primordial concentrations of the isotopes and the expected rate of heat loss, calculations show that the radioactive decay could not have melted Vesta or any other asteroid. Another heating mechanism must therefore be responsible, but what is it? This question has dogged planetary scientists for decades.” Alan E. Rubin, “What Heated the Asteroids,” Scientific American, Vol. 292, May 2005, p. 82.

“It is thus clear that many asteroids were once quite hot. But what mechanism could have raised the temperatures of the asteroids to this extent if the rocky bodies were too small to retain the heat from long-lived radioisotopes?”  Ibid., p. 84.

38. “However, up until recently, the general paradigm has been that asteroids are ‘rocky,’ inner-solar system objects and comets are ‘icy’ outer-solar system objects. A number of recent observations and models have significantly muddied the waters (so to speak). While ice is not found at the surface of Ceres [the largest of all asteroids], there is evidence [the low density of Ceres] that a large ice ocean is present in its subsurface ... .” A. S. Rivkin and J. P. Emery, “Water Ice on 24 Themis?” 2008. www.lpi.usra.edu/meetings/acm2008/pdf/8099.pdf

39. “We conclude that [asteroid] 65 Cybele is covered by fine anhydrous silicate grains, with a small amount of water-ice and complex organic solids.” Zoe Landsman et al., “Asteroid 65 Cybele: Detection of Small Silicate Grains, Water-Ice and Organics,” Bulletin of the American Astronomical Society, Vol. 42, 2010, p. 1035.

u Humberto Campins et al., “Water Ice and Organics on the Surface of the Asteroid 24 Themis,” Nature, Vol. 464, 29 April 2010, pp. 1320–1321.

u Andrew S. Rivkin and Joshua P. Emery, “Detection of Ice and Organics on an Asteroidal Surface,” Nature, Vol. 464, 29 April 2010, pp. 1322–1323.

40. “The surprise is the wide extent of ice on the surface of Themis. The average temperature of asteroids (about 150–200 kelvin) [-100°F to -190°F] at this distance from the Sun should cause surface ice to sublimate away in a matter of a few years or less, which is inconsistent with the billions of years that Themis is thought to have spent at its current location.” Henry H. Hsieh, “A Frosty Finding,” Nature, Vol. 464, 29 April 2010, p. 1286.

41. “Meteorites and probably all meteoroids contain the same materials as those contained in the earth itself.” Franklyn M. Branley, Comets, Meteoroids, and Asteroids: Mavericks of the Solar System (New York: Thomas Y. Crowell, 1974), p. 38.

u “Modern mass spectrometry techniques had revealed that the isotopic compositions of many of the more refractory elements in meteorites, including a primitive class of meteorite called chondrites, are, within error, identical to those found on Earth itself.” Alex N. Halliday, “Inside the Cosmic Blender,” Nature, Vol. 425, 11 September 2003, p. 137.

u “The thousands of meteorites that strike the earth each year are generally believed to be either fragments of a disrupted planet (or planets) that originally resembled the earth, or bits of cosmic “dust” such as originally were gathered together to form the earth.” Gordon A. Macdonald et al., Volcanoes in the Sea, 2nd edition (Honolulu: University of Hawaii Press, 1983), p. 325.

42. W. J. Merline et al., “Discovery of a Moon Orbiting the Asteroid 45 Eugenia,” Nature, Vol. 401, 7 October 1999, pp. 565–568.

43. Some have claimed that mining asteroids could be profitable. [See John S. Lewis, Mining the Sky: Untold Riches from the Asteroids, Comets, and Planets (Reading, Massachusetts: Addison-Wesley, 1997).]

44. Besides iron meteorites, which were once 1,300°F, chondrules were once about 3,000°F. [See page 420 and Figure 183 on page 349.] Also, the matrix material encasing chondrules shows thermal metamorphism requiring temperatures of at least 750°F.  [See O. Richard Norton, The Cambridge Encyclopedia of Meteorites (Cambridge, England: Cambridge University Press, 2002), p. 92.]

45. “The water content (by weight) of the meteorites is about 11 percent for type 1 chondrites, about 9 percent for type 2, and 2 percent or less for type 3.”  Ibid., p. 83.

46. “... every metamorphosed ordinary chondrite has been shocked and subsequently heated, some of them multiple times.”  Ibid., p. 86.

47. “First, a single impact cannot raise the global temperature of an asteroid-size body by more than a few degrees. Second, the high surface-to-volume ratios of such bodies promote heat loss, so they cool quickly between successive impacts. Third, a typical impact generates minuscule amounts of melted rock relative to the volume of the impact-generated debris. And last, the low escape velocities of asteroids allow much of the most strongly heated material to escape.”  Ibid., p. 86.

48. “Diamonds were first found in this meteorite type [ureilites].” Norton, p. 347.

u Farhang Nabiei, “Diamonds from a Lost Planet.” Nature, Vol. 556, 26 April 2018, p. 411.

While Farhang Nabiei correctly concludes that this diamond-containing meteorite must have come from deep inside a “shattered” planet-size body near Earth, he cannot imagine where that planet is today. Therefore, he writes that it has “vanished” and the meteorite must have been launched “during the first million years of the Solar System’s history.”

49. Tristan Ferroir et al., “Carbon Polymorphism in Shocked Meteorites: Evidence for New Natural Ultrahard Phases,” Earth and Planetary Science Letters, Vol. 290, 15 February 2010, pp. 150–154.

50. The following prediction was made on page 222 of the 7th edition of In the Beginning.

Ceres, the largest asteroid, will be found to have a very earthlike spin.

It is now known that Ceres rotates once every 9.075 hours but its spin axis deviates only 3° from being perpendicular to the Earth’s orbital plane. I expected 0°. [See P. C. Thomas et al., p. 224.] The Earth rotates once every 23.93 hours. This prediction missed the mark more than I expected.

I selected Ceres because it is the most massive asteroid, having about 1.28% of the mass of the Moon. Therefore, Ceres is least likely to have its spin rate and spin axis altered much by the inevitable impacts within the asteroid belt.

51. Most astronomers mistakenly visualize moons of asteroids forming from an impact. Small “chips” might be expelled, but only in extremely rare circumstances would they be placed in orbit around the asteroid by the gravitational attraction of other debris.  For example:

What was particularly surprising was that it [asteroid Hermes] was binary with equal components. Jean-Luc Margot, as quoted by K. Ramsayer, “Out of Hiding,” Science News, Vol. 164, 1 November 2003, p. 277.

52. “I’m stunned and astonished [at seeing a double asteroid].” Planetary physicist Jay Melosh, as quoted by Richard A. Kerr, “Double Asteroid Puzzles Astronomers,” ScienceNOW, 21 September 2000.“...Occtor Crater—in which nestle bright patches of salt deposits.” Phillip Campbell, Closer Look at Ceres,” Nature, Vol. 558, 7 June 2018, p. 10.

53. A. Nathues et al., “Sublimation in Bright Spots on (1) Ceres,” Nature, Vol. 528, 10 December 2015, pp. 237–240.

54. R. P. Binzel and T. C. Van Flandern, “Binary Asteroids: Evidence for Their Existence from Lightcurves,” Science, Vol. 203, 2 March 1979, pp. 903–905.

55. “The most primitive meteorites, the carbonaceous chondrites, are primarily mixtures of many distinct materials that reflect a variety of solar nebular environments as well as planetary processing.”  Qingzhu Yin et al., “Diverse Supernova Sources of Pre-Solar Material Inferred from Molybdenum Isotopes in Meteorites,” Nature, Vol. 415, 21 February 2002, p. 881.

Why do they say “a variety of solar nebular environments”? Had the solar system and the molybdenum isotopes found in meteorites come from the debris of one exploded star and millions of years of mixing, these different isotopes should be spread somewhat uniformly in meteorites. They are not. Therefore, many exploding stars are needed. Furthermore, evolutionists must maintain that molybdenum isotopes avoided mixing for millions of years. Every statistician knows that with enough variables (in this case, enough stars exploding in different ways for millions of years), many untestable explanations can be proposed.

56. The smaller, asteroid-size moons of the giant planets tend to have irregular orbits. [See Table 21.] For example, Jupiter has at least 31 irregular moons, the largest, Himalia, is 150 kilometers (93 miles) in diameter. Their orbits generally have high inclinations and large eccentricities. Astronomers don’t understand why so many are retrograde.

“Irregular satellites of planets in the outer Solar System are the only population of objects dominated by retrograde motion relative to the parent body, but their origin is not clear.” Paul A. Wiegert et al., “A Retrograde Co-Orbital Asteroid of Jupiter,” Nature, Vol. 543, 30 March 2017, p. 687.

These characteristics show they were captured. To capture an asteroid, much of its orbital energy must be removed (or dissipated), so the planet’s gravity can hold onto the asteroid. Captures rarely result from chance gravitational encounters with other large bodies. An easy way to dissipate an asteroid’s energy is by aerobraking: friction with an atmosphere—the planet’s, the asteroid’s, or both. Based on the hydroplate theory, bloated atmospheres existed for a few centuries after the flood, so the key evidence for these captures is absent today. However, dozens of other evidences are now available, all pointing to the fountains of the great deep.

u Enceladus Sea,” Science, Vol. 344, 4 April 2014, p. 17.

57. “[German scientists] reported the clear detection of sodium in [Saturn’s] E ring’s ice particles. Six percent of the particles are rich in sodium and contain salts such as sodium chloride and sodium bicarbonate, along with smaller amounts of potassium. Cassini has traced the ice grains to a towering plume rising from Enceladus’s south pole. ... The salts—resembling terrestrial [Earth] sea salt ...” Richard A. Kerr, “Tang Hints of a Watery Interior for Enceladus,” Science, Vol. 323, 23 January 2009, pp. 458–459.

u “... although all the [ice] grains are dominated by water ice, about 6% of them are quite salty, containing roughly 1.5% of a mixture of sodium chloride, sodium carbonate and sodium bicarbonate.” John Spencer, “Enceladus with a Grain of Salt,” Nature, Vol. 459, 25 June 2009, p. 1067.

u Frank Postberg et al., “Sodium Salts in E-Ring Ice Grains from an Ocean below the Surface of Enceladus,” Nature, Vol. 459, 25 June 2009, p. 1098–1101.

u Frank Postberg et al., “A Salt-Water Reservoir as the Source of a Compositionally Stratified Plume on Enceladus,” Nature, Vol. 474, 30 June 2011, pp. 620–622.

58. M. M. Hedman et al., “An Observed Correlation between Plume Activity and Tidal Stresses on Enceladus,” Nature, Vol. 500, 8 August 2013, pp. 182–189.]

u Richard A. Kerr, “Cassini Plumbs the Depths of the Margaret Galland Kivelson, “Does Enceladus Govern Magnetospheric Dynamics at Saturn?” Science, Vol. 311, 10 March 2006, pp. 1391–1392.

u The temperature in Enceladus’ subglacial ocean is greater than 194°F (>90°C). [See Hsiang-Wen Hsu et al., “Ongoing Hydrothermal Activities within Enceladus,” Nature, Vol. 519, 12 March 2015, pp. 207–210.]

u “...this icy moon’s sizzling innards are not easily explained. Enceladus is roughly the diameter of England—relatively runty for a moon and far too small to hold onto the primordial heat left over from its formation.” Postberg, Frank, et al., “Under the Sea of Enceladus,” Scientific American, Vol. 315, October 2016, p. 40.

u “Scientists do not yet know exactly how the tiny moon generates enough heat to sustain this large ocean.” Ibid., p. 43.

u “...the geysers [on Enceladus] spurt out 200 kilograms of salty, organic-laced material every second.” Alexandra Witze, “13 Years of Cassini,” Nature, Vol. 548, 31 August 2017, p. 513.

59. Paul Schenk and the Cassini Imaging Team, http://apod.nasa.gov/apod/ap080331.html, 31 March 2008.

60. “Beneath an icy crust, Saturn’s moon Enceladus has an ocean that covers its entire globe. Peter Thomas, “Global Ocean on Enceladus,” Nature, Vol. 525, 24 September 2015, p. 428.

u The plume escaping from Enceladus contains methane (CH₄) and a smattering of other organics, such as propane (C₃H₈), ethane (C₂H₆), benzene (C₆H₆), and formaldehyde (CH₂O). [See Porco, p. 58.] To understand their likely origin, see pages 116–175.

61. “At present it is practically impossible for Jupiter to capture satellites permanently because no efficient dissipation mechanism exists.” Scott S. Sheppard and David C. Jewitt, “An Abundant Population of Small Irregular Satellites Around Jupiter,” Nature, Vol. 423, 15 May 2003, p. 261.

62. Joanne Baker, “Tiger, Tiger, Burning Bright,” Science, Vol. 311, 10 March 2006, p. 1388.

63. Frank Postberg, et. al., “Macromolecular Organic Compounds From the Depths of Enceladus,” Nature, Vol. 558, 28 June, 2018, p. 564.

64. “Finding such active geology on such a tiny moon is a big surprise. ... tiny Enceladus produces a plume large enough to drench the whole Saturn system. The origin of Enceladus’ internal heating is also still a major puzzle.” Baker, p. 1388.

u “Enceladus has been found to be one of the most geologically dynamic objects in the solar system. Among the surprises are a watery, gaseous plume; a south polar hot spot; and a surface marked by deep canyons and thick flows.” Jeffrey S. Kargel, Enceladus: Cosmic Gymnast, Volatile Miniworld,” Science, Vol. 311, 10 March 2006, p. 1389.

u Ten other papers in the 10 March 2006 issue of Science, pages 1391–1428, report on these observations from the Cassini spacecraft.

65. “... the amount of tidal energy being injected into [Enceladus today] falls short of the energy coming out of Enceladus’ south pole by a factor of five.” Carolyn Porco, “The Restless Worlds of Enceladus,” Scientific American, Vol. 299, December 2008, p. 60.

66. “Global -ocean models have fallen out of favour for Enceladus, because it is difficult to keep a global ocean from freezing, and a regional south polar ocean is now considered more likely.” John Spencer, “Saturn’s Tides Control Enceladus’ Plume,” Nature, Vol. 500, 8 August 2013, p. 156.

67. “Ocean on Another of Saturn’s Moons,” Nature, Vol. 538, 13 October 2016, p. 143.

68. “The interior of Mars’ moon Phobos could be as much as 30 percent empty space, new observations suggest.” Sid Perkins, “Martian Moon Is Probably Porous,” Science News, Vol. 177, 5 June 2010, p. 11.

69. “The surface of Phobos shows some spectral similarities to those of various asteroid types.” T. P. Andert et al., “Precise Mass Determination and the Nature of Phobos,” Geophysical Research Letters, Vol. 37, 7 May 2010, p. L09202–3.

70. “It’s also unlikely Phobos is made solely of Mars’ crust blasted into space by an impact and then reassembled, because the spectral features of the moon’s rocks don’t match those of the Red Planet.” Perkins, p. 11.

71. “Although none of the present models is fully satisfactory, neutral gas emission through water loss by Deimos at a rate of about 10²³ molecules per second, combined with a charged dust coma, is favored.” K. Sauer et al., “Deimos: An Obstacle to the Solar Wind,” Science, Vol. 269, 25 August 1995, p. 1075.

u “Such events were detected, for example, at the crossing points of the spacecraft with the orbit of the martian moon Phobos.” Ibid.

72. An orbit is a perfect circle if its eccentricity is 0.000. Earth’s orbital eccentricity about the Sun is 0.017 and Earth’s moon has an orbital eccentricity of 0.054. Having a moon’s orbit lie in its planet’s equatorial plane (which Earth’s moon does not) also demands a physical explanation for how that happened. Table 21 contains a listing of 40 moons whose orbits lie within two degrees of its planets equatorial plane and are remarkably circular. Therefore, those moons are probably asteroids captured shortly after the flood. [The Astronomical Almanac for the Year 2012 (Washington, D.C.: U.S. Government Printing Office, 2011), pp. F2, F4.]

73. For a given atmospheric mass, the lower its density, but thicker it is, the more its energy and momentum a potential moon will lose as it enters that atmosphere. Gas molecules within 360 Mars’ radii of Mars are more gravitationally attracted to Mars than the Sun. During the flood, an ocean of gas molecules were distributed throughout the inner solar system, so Mars’ atmosphere, as a first approximation, was about 360 Mars’ radii thick. Phobos currently orbits 2.77 Mars’ radii from Mars’ center of mass, well inside what was once a thick atmosphere.

74. David Jewitt, “The Active Asteroids,” The Astronomical Journal, Vol. 143, March 2012, p. 66–79.

75. “Could the MBCs [Main Belt Comets; comets in the asteroid belt] be comets from the Kuiper Belt or Oort Cloud that have become trapped in asteroid-like orbits? Published dynamical simulations suggest not, having failed to reproduce the transfer of comets to main-belt orbits.” Henry H. Hsieh and David C. Jewitt, “A Population of Comets in the Main Asteroid Belt, Science, Vol. 312, 28 April 2006, p. 562.

76. “[Based on the numbers of larger asteroids] ... current theories can’t adequately explain why so many of these small bodies should follow such circular routes.” D. L. Rabinowitz, as quoted by Ron Cowen, “Rocky Relics,” Science News, Vol. 145, 5 February 1994, p. 88.

77. “... there is an excess of Earth-approaching asteroids with diameters less than 50 m, relative to the population inferred from the distribution of larger objects.”  D. L. Rabinowitz et al., “Evidence for a Near-Earth Asteroid Belt,” Nature, Vol. 363, 24 June 1993, p. 704.

78. “We find that these asteroids can also undergo solar collisions, through several dynamical routes involving orbital resonances with the giant planets, on timescales of the order of 10⁶ years.”  Paolo Farinella et al., “Asteroids Falling into the Sun,” Nature, Vol. 371, 22 September 1994, p. 315.

79. “Separately, over two-thirds of comet nuclei that have been imaged at high resolution show bilobate shapes, including the nucleus of comet 67P/Churyumov-Gerasimenko (67P), visited by the Rosetta spacecraft. Analysis of the Rosetta observations suggest that 67P’s components were brought together at low speed after their separate formation.” Masatoshi Hirabayashi, et al. “Fission and Reconfiguration of Bilobate Comets as Revealed by 67P/Churyumov-Gerasimenko,” Nature, Vol. 534, 16 June 2016, p. 352.

80. S. C. Lowry et al., “The Internal Structure of Asteroid (25143) Itokawa as Revealed by Detection of YORP Spin-Up,” Astronomy and Astrophysics, Vol. 562, 5 February 2014, pp. 1–9.

81. Craig Covault, “Historic Japanese Asteroid Data Amaze Researchers,” Aviation Week & Space Technology, 20 March 2006, p. 28.

82. “Therefore comet 67P/Churyumov-Gerasimenko is an accreted body of two distinct objects with ‘onion-like’ stratifications, which formed before they merged. ... the strata of the two lobes are clearly independent of each other.” Matteo Massironi et al., “Two Independent and Primitive Envelopes of the Bilobate Nucleus of Comet 67P,” Nature, Vol. 526, 15 October, p. 402.

u “Since the Rosetta spacecraft’s arrival last August [2014], researchers have debated whether 67P is a comet that lost some weight around its waistline or two comets that got a little too attached to one another. Layers and terraces on cliffs gave away 67P’s coupling. Mismatched layers between the comet’s head and body imply that the two lobes formed independently and later fused together. ... The strata in the head are slightly askew to those in the body.” Christopher Crockett, “Rocky Layers Reveal Recipe for Comet 67P,” Science News, Vol. 188, 31 October 2015, p. 17.

83. Alexander N. Krot, “Bringing Part of an Asteroid Back Home,” Science, Vol. 333, 26 August 2011, pp. 1098–1099.

u Tomoki Nakamura et al., “Itokawa Dust Particles: A Direct Link Between S-Type Asteroids and Ordinary Chondrites,” Science, Vol. 333, 26 August 2011, pp. 1113–1116.

84. David C. Jewitt, “NASA’s Hubble Sees Asteroid Sprout Six Comet-Like Tails,” NASA News Release, 7 November 2013.

85. David C. Jewitt et al., “The Extraordinary Multi-Tailed Main-Belt Comet P/2013 P5,” The Astrophysical Journal Letters, Vol. 778, 7 November 2013, pp. 2, 5.

Jewitt acknowledged that this object’s orbital parameters clearly show that it is an asteroid.

86. Tony Phillips, “Corkscrew Asteroid,” http://science.nasa.gov/ headlines/y2006/09jun_moonlets.htm.

87. Paul A. Wiegert et al., “An Asteroidal Companion to the Earth,” Nature, Vol. 387, 12 June 1997, pp. 685–686.

88. Steven J. Ostro et al., “Radar Detection of Asteroid 2002 AA29,” Icarus, Vol. 166, 2003, pp. 271–275.Ron Cowen, “Hidden Companion,” Science News, Vol. 152, 12 July 1997, p. 29.

89. “Curiously, there are many more [asteroids] in the leading Lagrange point (L4) than in the trailing one (L5).”  Bill Arnett, “Asteroids,” www.seds.org/nineplanets/nineplanets/asteroids.html.

u Data provided by the Harvard-Smithsonian Center for Astrophysics on 17 February 2005.  See
http://cfa-www.harvard.edu/iau/lists/JupiterTrojans.html.

90. Paul Voosen, “NASA Missions Aim at Asteroid Oddballs,” Science, Vol. 355, 13 January 2017, p. 117.

91. Franck Marchis et al., “A Low Density of 0.8 g cm^-3 for the Trojan Binary Asteroid 617 Patroclus,” Nature, Vol. 439, 2 February 2006, pp. 565–567.

u Ker Than, “Asteroids Near Jupiter Are Really Comets,” Science & Space, 1 February 2006, www.cnn.com/2006/ TECH/space/02/01/jupiter.comets/index.html.

92. “The particularly long lifetime of 2015BZ₅₀₉ on its retrograde orbit, in the same region of space as the largest planet in the Solar System, makes it arguably the most intriguing small body in this region. Further studies are needed to confirm how this mysterious object arrived at its present configuration.” Helena Morais and Fathi Namouni, “Reckless Orbiting in the Solar System,” Nature, Vol. 543, 30 March 2017, p. 636.

93. Michael E. Zolensky et al., “Asteroidal Water within Fluid Inclusion-Bearing Halite in an H5 Chondrite, Monahans (1998),”Science, Vol. 285, 27 August 1999, pp. 1377–1379.

94. “... crystals of sylvite (KCl) are present within the [meteorite’s] halite crystals, similar to their occurrence in terrestrial evaporites [salt deposits on Earth].”  Ibid., p. 1378.

95. George Cooper et al., “Carbonaceous Meteorites As a Source of Sugar-Related Organic Compounds for the Early Earth,” Nature, Vol. 414, 20/27 December 2001, pp. 879–883.

The sugars in these meteorites (Murchison and Murray) were rich in heavy hydrogen, another indicator that they came from the subterranean chambers. [See page 323.]

96. James Whitby et al., “Extinct ¹²⁹I in Halite from a Primitive Meteorite,” Science, Vol. 288, 9 June 2000, p. 1821.

u Ulrich Ott, “Salty Old Rocks,” Science, Vol. 288, 9 June 2000, pp. 1761–1762.

u “An H3–6 chondrite called Zag fell in the Moroccan Sahara desert five months [after the Monahans meteorite] that also had halite crystals with water inclusions.”  Norton, p. 91.

u John L. Berkley et al., “Fluorescent Accessory Phases in the Carbonaceous Matrix of Ureilites,” Geophysical Research Letters,” Vol. 5, December 1978, pp. 1075–1078.

u D. J. Barber, “Matrix Phyllosilicates and Associated Minerals in C2M Carbonaceous Chondrites,” Geochimica et Cosmochimica Acta, Vol. 45, June 1981, pp. 945–970.

97. Fred Hoyle and Chandra Wickramasinghe, Lifecloud (New York: Harper & Row, Publishers, 1978), p. 112.

98. Magnus Endress et al., “Early Aqueous Activity on Primitive Meteorite Parent Bodies,” Nature, Vol. 379, 22 February 1996, pp. 701–703.

99. “The exact mechanism of terrestrial amino acid incorporation and retention by meteorites is not known.” Jeffrey L. Bada et al., “A Search for Endogenous Amino Acids in Martian Meteorite ALH84001,” Science, Vol. 279, 16 January 1998, p. 365.

u A. J. T. Jull et al., “Isotopic Evidence for a Terrestrial Source of Organic Compounds Found in Martian Meteorites Allan Hills 84001 and Elephant Moraine 79001,” Science, Vol. 279, 16 January 1998, pp. 366–369.

u M. H. Engel and S. A. Macko, “Isotopic Evidence for Extraterrestrial Non-Racemic Amino Acids in the Murchison Meteorite,” Nature, Vol. 389, 18 September 1997, pp. 265–267.

u Daniel P. Glavin et al., “The Effects of Parent Body Processes on Amino Acids in Carbonaceous Chondrites,” Meteoritics & Planetary Sciences, Vol. 45, 15 December 2011, pp. 1948–1972.

100. Richard B. Hoover, “Fossils of Cyanobacteria in CI-1 Carbonaceous Meteorites,” The Journal of Cosmology, Vol. 13, March 2011, pp. 3811–3848.

101. Michael Callahan, “NASA Researchers: DNA Building Blocks Can Be Made in Space,” NASA press release, 8 August 2011 at:
www.nasa.gov/topics/solarsystem/features/dna-meteorites.html

Various tests on these meteorites ruled out contamination.

102. Ian D. Hutcheon, “Signs of an Early Spring,” Nature, Vol. 379, 22 February 1996, pp. 676–677.

u “The salts we found mimic the salts in Earth’s ocean fairly closely.”  Carleton Moore as reported at www.cnn.com on 23 June 2000. For details, see Douglas J. Sawyer et al., “Water Soluble Ions in the Nakhla Martian Meteorite,” Meteoritics & Planetary Science, Vol. 35, July 2000, pp. 743–747.

u “... a variety of minerals in three nakhlite meteorites, including a fragment of the Nakhla meteorite collected within days of its fall, seem to have precipitated from a brine.” Richard A. Kerr, “A Wetter, Younger Mars Emerging,” Science, Vol. 289, 4 August 2000, p. 715.

103. E. Deloule et al., “Deuterium-Rich Water in Meteorites,” Meteoritics, Vol. 30, September 1995, p. 502.

u Ron Cowen, “Martian Leaks: Hints of Present-Day Water,” Science News, Vol. 158, 1 July 2000, p. 15.

u Laurie Leshin Watson et al., “Water on Mars: Clues from Deuterium/Hydrogen and Water Contents of Hydrous Phases in SNC Meteorites,” Science, Vol. 265, 1 July 1994, pp. 86–90.

Although Cowen and Watson believe that these meteorites came from Mars, page 362 explains why this is unlikely.

104. “Some different microbial species, derived from samples of [two] meteorites, have been cultured, cloned and classified by 16S rDNA typing and found to be not essentially different from present day organisms [here on Earth]; they also appear sensitive to growth inhibition by specific antibiotics.”  Giuseppe Geraci et al., “Microbes in Rocks and Meteorites,” Rendiconti Accademia Nazionale dei Lincei, Vol. 12, No. 9, 2001, p. 51.

These DNA studies also rule out contamination, because the bacteria recovered and cultured from the meteorites were sufficiently different from modern strains.

u “Bruno D’Argenio, a geologist working for the Italian National Research Council, and Giuseppi Geraci, professor of molecular biology at Naples University, identified and brought back to life extraterrestrial microorganisms lodged inside [a supposedly] 4.5 billion-year-old meteorite kept at Naples’ mineralogical museum.”  Rossella Lorenzi, “Scientists Claim to Revive Alien Bacteria,” Discovery News, www.discovery.com, 10 May 2001.

105. “The foregoing analysis, sketchy as it is, seems to strengthen the grounds of the old speculation—that meteorites are disrupted fragments of a planet of the terrestrial type.”  Reginald A. Daly, “Meteorites and an Earth-Model,” Bulletin of the Geological Society of America, Vol. 54, 1 March 1943, p. 425.

Because meteorites are so similar to the material inside Earth, many researchers believe that the Earth formed from infalling meteoroids. One should also consider whether the Earth produced meteoroids. Failure to consider both possibilities is the same logical fallacy described in Endnote 4, page 330.  Much evidence opposes the former.

106. Birger Schmitz et al., “Sediment-Dispersed Extraterrestrial Chromite Traces a Major Asteroid Disruption Event,” Science, Vol. 300, 9 May 2003, pp. 961-964.

107. Jonathan Gradie and Joseph Veverka, “The Composition of the Trojan Asteroids,” Nature, Vol. 283, 28 February 1980, pp. 840–842.

108. “Recent spacecraft studies of Comet 67P/Churyumov-Gerasimenko with Rosetta and of [asteroid] Ceres ... provide evidence that complex organic molecules and even amino acids are ubiquitous on small bodies in the solar system and that water ice is abundant in the asteroid belt.” Michael Kuppers, “Dwarf Planet Ceres and the Ingredients of Life,” Science, Vol. 355, 17 February 2017, p. 692.

109. Asphaug, “The Small Planets,” p. 46.

110. Joshua L. Bandfield et al., “Spectroscopic Identification of Carbonate Minerals in the Martian Dust,” Science, Vol. 301, 22 August 2003, pp. 1084–1087.

u “Two Phoenix [Mars Lander] experiments identified calcium carbonates and clays in soil samples scooped up by the crafts robotic arm. On Earth, both minerals are associated with the presence of liquid water.” Ron Cowen, “More Clues to Martian Chemistry,” Science News, Vol. 174, 25 October 2008, p. 13.

111. “[A sample of dirt from an asteroid] could finally explain why the most common type of asteroid looks different—spectroscopically more red—from the most common type of meteorite. Apparently, some sort of ‘space weathering’ is reddening the surface of S-type asteroids.” Richard A. Kerr, “Beaming to Itokawa,” Science, Vol. 309, 16 September 2005, p. 1797.

Yes, most asteroids were “weathered” (rusted) by oxygen gas in the inner solar system soon after the flood. Since then, that gas has dispersed.

112. “Unfortunately, Mars spent its youth in a bad neighborhood near the asteroid belt, and, being small, was especially susceptible [to asteroid impacts and the loss of its atmosphere]. Given the expected size distribution of impactors early in a solar system’s history, the planet should have been stripped of its entire atmosphere in less than 100 million years.” David C. Catling and Kevin J. Zahnle, “The Planetary Air Leak,” Scientific American, Vol. 300, May 2009, p. 42.

“For decades, scientists have pondered why Mars has such a thin atmosphere, but now we wonder: Why does it have any atmosphere left at all?” Ibid., p. 36.

113. Alfred S. McEwen, “Mars in Motion,” Scientific American, Vol. 308, May 2013, p. 60.

114. “[Mars] was cold and dry from the beginning, punctuated at most by short bursts of wetness.” Eric Hand, “Dreams of Water on Mars Evaporate,” Nature, Vol. 484, 12 April 2012, p. 153.

u “Even for a multiple-bar CO₂ atmosphere, conditions are too cold to allow long-term surface liquid water [on Mars].” R. Wordsworth et al., “Global Modelling of the Early Martian Climate under a Denser CO₂ Atmosphere,” Icarus, Vol. 222, 2013, p. 1.

115. Alfred S. McEwen, as quoted by Corey S. Powell, “Weirdlands of Mars,” Discover, June 2014, p. 60.

u “Among other things, Mars researchers have found it increasingly hard to explain how the planet might have stayed warm and wet in its early history.” Alexandra Witze, “Mars Slow to Yield Its Secrets,” Science, Vol. 511, 24 July 2014, p. 396.

116. “The D/H [deuterium-to-hydrogen] value [for water locked in Martian clays] is 3.0 (± 0.2) times the ratio in standard mean ocean water.” P. R. Mahaffy et al., “The Imprint of Atmospheric Evolution in the D/H of Hesperian Clay Minerals on Mars,” Science, Vol. 347, 22 January 2015, p. 412.

117. Pure liquid water cannot exist for long at temperatures below 32°F or at pressures below 6 mbar (0.0888 psia). This pressure-temperature combination, called the triple point, allows water to exist simultaneously in three states: solid, liquid, and gas. Because the average surface temperature of Mars is colder than -80°F and the atmospheric pressure is 6–10 mbar, liquid water would quickly freeze on Mars.

Actually, the water on Mars is saltwater, which can remain liquid far below water’s so-called freezing point. One must ask, “Where did the liquid water come from that dissolved the salts?” Answer: the subterranean water chamber on the preflood Earth.

118. Michael C. Malin et al., “Present-Day Impact Cratering Rate and Contemporary Gully Activity on Mars,” Science, Vol. 314, 8 December 2006, pp. 1573–1577.

u S. W. Squyres et al., “Ancient Impact and Aqueous Processes at Endeavour Crater, Mars,” Science, Vol. 336, 4 May 2012, pp. 570–575.

119. “The presence of brines [in these groundwater discharges] is the most realistic scenario for Mars, requiring modest quantities of water and no geothermal heat. Furthermore, the brine model exhibits a dependence of discharge on season and favors equator-facing slopes in the middle to high latitudes ...” Alfred S. McEwen et al., “Seasonal Flows on Warm Martian Slopes,” Science, Vol. 333, 5 August 2011, p. 742.

120. “The evidence disturbed the scientists in more than one respect. First, conditions on Mars are such that any water reaching the surface supposedly would not remain liquid for very long but would boil, freeze, or poof into vapor. Second, from the absence of craters, sand dunes, or anything else on top of the [eroded] gullies, they appeared to have formed very recently, possibly as recently as yesterday. ... Most of the evidence was found, strikingly, in some of the coldest places on the surface—on shadowed slopes facing the poles, in clusters scattered around latitudes higher than 30 degrees—rather than at the warmer equatorial latitudes. ... And proposals for other substances that might behave as liquids on the martian surface raised so many other questions that they failed to solve the problem.” Kathy Sawyer, “A Mars Never Dreamed Of,” National Geographic, Vol. 199, February 2001, p. 37.

121. “The surface of Mars is so cold—on average -70° to -100°C [-94°F to -148°F]—that any water within 2 or 3 kilometers of the surface, never mind a meter or two, should be permanently frozen, they noted.”  Kerr, “Rethinking Water on Mars and the Origin of Life,” Science, Vol. 292, 6 April 2001, p. 39.

u Many Mars researchers cling to the belief that Mars once had oceans or considerable subsurface water. Why? If Mars once had liquid water, they argue, life might have evolved, because life (as we know it) requires liquid water. Notice their faulty logic.

Instead, if A (life) requires B (water), the presence of B does not demand the presence of A. (Water is a necessary but not sufficient requirement for life.) Ignored is life’s extreme complexity. [Pages 15 – 26 explain why life is so complex that it could not have evolved anywhere in trillions upon trillions of years.] When scientists hold out hope of discovering life on Mars, funding for their research is more likely. Also, an excited media will sensationalize and publicize that research, raising hopes that life may be found on Mars.

Most scientific researchers are in a perpetual hunt for money to fund their work and pay their salaries. If asteroids and comets placed water on Mars recently, few evolutionists would expect that life evolved on Mars. Therefore, a major reason for funding the exploration of Mars disappears.

122. “Carving them, researchers calculated, would take water gushing at 10 million to 1 billion cubic meters per second.” Richard A. Kerr, “An ‘Outrageous Hypothesis’ for Mars: Episodic Oceans,” Science, Vol. 259, 12 February 1993, p. 910.

123. See Endnote 41 on page 333.

124. “Such streams typically originate in steep-walled amphitheaters rather than in ever smaller tributaries.” Arden L. Albee, p. 50.

125. “But the limited amount of erosion suggests that it wasn’t the result of a ‘warm and wet’ early Mars.” Richard A. Kerr, “Running Water Eroded a Frigid Early Mars,” Science, Vol. 300, 6 June 2003, p. 1497.

126. Christopher D. K. Herd et al., “Origin and Evolution of Prebiotic Organic Matter as Inferred from the Tagish Lake Meteorite,” Science, Vol. 332, 10 June 2011, p. 1304.

127. “The complex suite of organic materials in carbonaceous chondrite meteorites probably originally formed in the interstellar medium and/or the solar protoplanetary disk, but were subsequently modified in the meteorites’ asteroidal parent bodies. The mechanisms of formation and modification are still very poorly understood.” Ibid., p. 1304.

128. Ibid.

129. Ibid., p. 1305.

u “The conditions of hydrothermal alteration inferred by analogy with experiments, especially temperature, are at odds with the [observed] mineralogy and preservation of volatile organic compounds.” Ibid., p. 1307.

130. “Amino acid concentrations and enantiomeric excesses in the Tagish Lake specimens provide further evidence of the influence of parent body aqueous alterations on SOM [soluble organic matter].” Ibid., p. 1306. [Note: enantiomers are mirror images of each other.]

131. “Sub-micrometer scale carbonaceous globules that are often substantially enriched in ¹⁵N and D [hydrogen-2] and are thought to have formed in the interstellar medium ... .” Herd et al., p. 1304.

132. “Most of the tens of thousands of gullies identified to date occur on slopes in craters, pits, and other depressions at latitudes > 30°;” Malin et al., p. 1575.

133. “On the other hand, Edgett has noted a central peak of an impact crater replete with gullies. Where would the water come from to feed a seep high on a central peak, he wondered.” Kerr, “Rethinking Water” p. 39.

A crater-producing impact often creates a peak in the center of the crater floor. Gravity from nearby terrain applies upward pressure under the new crater floor, causing it to suddenly buckle upward at its weakest point—its center—creating a peak. This is similar to the mechanism that formed the Mid-Oceanic Ridges.

134. Shane Byrne et al., “Distribution of Mid-Latitude Ground Ice on Mars from New Impact Craters,” Science, Vol. 325, 25 September 2009, pp. 1674–1676.

135. “... near the poles, Mars Odyssey [spacecraft] has shown, as much as 50 percent of the upper meter of soil may be [water] ice.” Arden L. Albee, “The Unearthly Landscapes of Mars,” Scientific American, Vol. 288, June 2003, p. 46.

136. Richard A. Kerr, “Minerals Cooked Up in the Laboratory Call Ancient Microfossils into Question,” Science, Vol. 302, 14 November 2003, p. 1134.

137. R. O. Pepin, “Evidence of Martian Origins,” Nature, Vol. 317, 10 October 1985, pp. 473–475.

138. “... martian meteorites are not representative of the planet’s crust.” Stella Hurtley, “Mars Matters,” Science, Vol. 324, 8 May 2009, p. 687.

u “It has become apparent that Martian meteorites have different chemical compositions from rocks analysed on the planet’s surface.” Harry V. McSween, “A Chunk of Ancient Mars,” Nature, Vol. 503, 28 November 2013, p. 475.

u Richard L. S. Taylor and David W. Mittlefehldt, “Missing Martian Meteorites,” Science, Vol. 290, 13 October 2000, pp. 273–275.

139. “... parts of ALH84001 show signs of having melted and reformed ...” Lisa Grossman, “Martian Meteorite’s Age Reduced,” Science News, Vol. 177, 8 May 2010, p. 10.

u Indeed, “one Mars meteorite, Nakhla, shows evidence it was immersed in an ancient brine.” Peter H. Smith, “Digging Mars,” Scientific American, Vol. 305, November 2011, p. 55.

What is the more likely source of the glass nodules, melted rocks, and brine? Supercold Mars or in the superhot subterranean chamber?

140. “... we estimate that the probability of finding on Earth a fragment ejected from Mars is about 10^-6 to 10^-7.” James N. Head et al., “Martian Meteorite Launch: High-Speed Ejecta from Small Craters,” Science, Vol. 298, 29 November 2002, p. 1753.

141. “... there remains the question of whether we should not be up to our necks in lunar meteorites—that is, what would be the expected relative fluxes of objects from the Moon and Mars and why have we seen so few from the Moon?”  Pepin, p. 474.

142. Joseph L. Kirschvink et al., “Paleomagnetic Evidence of a Low-Temperature Origin of Carbonate in the Martian Meteorite ALH84001,” Science, Vol. 275, 14 March 1997, p. 1629.

143. “About 20% of the ejecta are rock vapors; most of the rest is melt.” Segura et al., p. 1977.

144. On 9 July 2000, after the 30 June 2000 (Volume 288) issue appeared containing pictures of erosion channels on Mars, I wrote the following letter to Science magazine. My letter was titled “Comets Carved the Mars’ Gullies.”

Dear Editor:

Why aren’t comets considered as the source of the water that carved Mars’ erosion features? Impact energy would convert a comet’s ice to liquid water. A typical comet, perhaps 10¹⁶ grams and 85% H₂O, could easily provide the volume of water estimated in Endnote 35 on page 2335.

Assume that large rocks are in the center of comets (a point I will not try to justify here). Those rocks, decelerating less than the surrounding ice as the comet passes through Mars’ thin atmosphere, strike the ground an instant earlier than the ice and create the crater. The ice, suddenly converted to liquid and splattered onto the crater walls, carves the gullies.

The typical ground temperatures of -70°C (or colder) in the gully regions is fatal to claims that large volumes of liquid water suddenly “seeped” from several hundred meters below Mars’ surface. Straining to overcome this fact by imagining saline solutions, unusually high heat flow on Mars, exotic liquids, lower than expected thermal conductivities, and Mars tipped on its axis is speculation on top of speculation. Why not consider the simple possibilities first?

If the water could not come from below, maybe it came from above.

Science magazine did not print this letter.

Today (2008), after the Deep Impact space mission to comet Tempel 1, the best estimate for the amount of water on a comet is 38% by mass.

145. Richard A. Kerr, “Signs of Ancient Rain May Stretch Mars’ Balmy Past,” Science, Vol. 305, 2 July 2004, p. 26.

u “... episodes of scalding rains followed by flash floods.” Teresa L. Segura et al., “Environmental Effects of Large Impacts on Mars,” Science, Vol. 298, 6 December 2002, p. 1979.

u “... great craters appear to have been filled to overflowing by rain on early Mars.”  Richard A. Kerr, “A Smashing Source of Early Martian Water,” Science, Vol. 298, 6 December 2002, p. 1866.

146. “... if summer temperatures are warm enough to melt briny ice, then the ice should disappear over time.” McEwen, p. 65.

Yes, frozen ice below Mars’ surface is disappearing. But since so much saltwater was deposited so recently (soon after Earth’s global flood about 5,000 years ago), some still remains.

147. “Water ice should not be stable equatorward of ±30° .” Jack T. Wilson et. al, “Equatorial Locations of Water on Mars,” Icarus, Vol. 299, August 2018, p. 148.

148. Lorenzo Iorio, “Dynamical Determination of the Mass of the Kuiper Belt from Motions of the Inner Planets of the Solar System,” Monthly Notices of the Royal Astronomical Society, Vol. 375, 11 March 2007, p. 1311.

149. This estimate of the total mass of TNOs is based on two studies that used completely different techniques, each with their strengths and limitations. The first, referenced in Endnote 148 above, arrived at 0.04 Earth masses; the second concluded that the TNO region contained 0.02 Earth masses. [See Cesar I. Fuentes and Matthew J. Holman, “A Subaru Archival Search for Faint Trans-Neptunian Objects,” The Astronomical Journal, Vol. 136, July 2008, pp. 83–97.]

150. “[Phoebe] presumably originated from the same primordial population shared by the dynamically excited Kuiper Belt Objects [KBOs which] received high-resolution spectral imaging during the Cassini flyby. .... The range of Phoebe’s water -ice absorption spans the same range exhibited by dynamically excited KBOs.” Wesley C. Fraser and Michael E. Brown, “Phoebe: A Surface Dominated by Water,” The Astronomical Journal, Vol. 156, July 2018, p. 23.

151. “Quaoar, a large body in the Kuiper Belt, has crystalline water ice on its surface, yet conditions there should favour amorphous ice.” David J. Stevenson, “Volcanoes on Quaoar?” Nature, Vol. 432 9 September 2004, p. 681.

No volcanoes have ever been reported on a TNO.

u “We calculate the rate at which crystalline water ice is amorphized by solar UV/visible radiation [on Charon], finding that at the depths probed by H and K observations (0.35 mm), the e-folding time to amorphize ice is (3–5) × 10⁴ yr.” Jason C. Cook and Steven J. Desch, “Near-Infrared Spectroscopy of Charon: Possible Evidence for Cryovolcanism on Kuiper Belt Objects.” The Astrophysical Journal, Vol. 663, 10 July 2007, p. 1406.

The authors favor some heating mechanism inside Charon to warm water enough for it to erupt and produce crystalline ice. But unlike the heat produced inside Saturn’s Enceladus or Jupiter’s Io, there is no giant planet near enough to produce the tidal stresses necessary. Instead, the heating mechanism was probably the collapse of Charon’s swarm.

152. “... crystalline water ice [on Quaoar] should be destroyed by energetic particle irradiation on a time scale of about 10⁷ yr.” David C. Jewitt and Jane Luu, “Crystalline Water Ice on the Kuiper Belt Object (50000) Quaoar,” Nature, Vol. 432 9 September 2004, p. 731.

153. Ron Cowen, “Outer Limits,” Science News, Vol. 169, 14 January 2006, p. 27.] [Also see Endnote 1 on page 373.]

154. “But planetary scientists do not have a plausible explanation for how a moon might have appeared there to begin with, [Marc] Buie says.” Alexandra Witze, “Pluto Mission Hunts for Hazards,” Nature, Vol. 521, 7 May 2015, p. 15.

155. “Based on our sample and the literature, up to ~50% of the small Plutinos are potential contact binaries." Audrey Thiroulin, “The Plutino Population: An Abundance of Contact Binaries,” https://arxiv.org/pdf/1804.09695.pdf, p. 1.

156. Amanda A. Sickafoose, “Ring Detected around a Dwarf Planet,’ Nature, Vol. 550, 12 October 2017, pp. 197–198.

u J. L. Ortiz, et al., “The Size, Shape, Density and Ring of the Dwarf Planet Haumea from a Settler Occultation,” Nature, Vol. 550, 12 October 2017, pp. 219–223.

157. “Saturn’s are the most studied of all rings, and yet they remain enigmatic. ... the formation mechanisms responsible for other rings remain uncertain.”

158. F. Braga-Ribas et al., “Tiny Chariklo Has Rings of Its Own,” Nature, Vol. 507, 27 March 2014, p. 433.

159. “But a dirty secret of planetary rings should be exposed: following exhaustive searches since 2004 using the Cassini spacecraft, it is almost certain that none of the numerous gaps in Saturn’s C ring and in its Cassini Division (low density band between Saturn’s main A and B rings) harbour any shepherds of the requisite size.” Joseph A. Burns, “Ring in the New,” Nature, Vol. 508, 3 April 2014, p. 49.

Why is this significant? Without the gravity of nearby bodies (called shepherds) to hold rings in place, they rapidly dissipate.

Moreover, an unperturbed ring several kilometers in width and of thickness h [meters] should spread, owing to interparticle collisions, in 10⁴/h years or a few thousand years, assuming [an] h of a few metres ... Thus the rings are either very young or actively confined [by a shepherd]. [See F. Braga-Rigas et al., “A Ring System Detected around the Centaur (10199) Chariklo,” Nature, Vol. 508, 3 April 2014, p. 74.]

Chariklo’s two rings are about 7 and 3 kilometers wide. The gap between them could be explained if Chariklo had shepherding moons, but so far, none have been found. (Even if they could be found, would they be massive enough to perform their shepherding duties?) Saturn “almost certainly” does not have shepherds that can account for its gaps. Therefore, Saturn’s rings are “almost certainly” a few thousand years young, and Chariklo’s gap, so far, appears equally young.

160. J. Horner et al., “Simulations of the Population of Centaurs I: The Bulk Statistics,” Monthly Notices of the Royal Astronomical Society, Vol. 354, 2 February 2008, pp. 798-810.

161. F. Braga-Ribas et al., “Tiny Chariklo Has Rings of Its Own,” Nature, Vol. 507, 27 March 2014, p. 433.

162. David C. Jewitt, as quoted by Christopher Crockett, “Icy Rings Found Around Tiny Space Rock,” Science News, Vol. 185, 3 May 2014, p. 10.

163. “Starting in April [2017], the spacecraft began threading the gap between Saturn and its rings once a week, and approach thought to be too dangerous earlier in the mission. At first. Cassini wielded its large radio antenna as a shield to protect itself from stray ring particles. The precaution was unnecessary; the gap was almost empty.” Paul Voosen, “A Fiery Finish to Cassini’s Long Run at Saturn,” Science, Vol. 357, 22September 2017, pp. 1219-1220.

164. “We find that the colors of [TNOs with low angles of inclination are] primarily red ... .” Amanda A. S. Gulbis et al., “The Color of the Kuiper Belt Core,” Icarus, Vol. 183, 1 July 2006, p. 168.

Why would TNOs with low angles of inclination be red? Much of the water launched by the fountains of the great deep would have vaporized and slowly formed a thin disk of water vapor aligned with the ecliptic and eventually extending beyond Neptune. Therefore, iron in the surface rocks of TNOs with low orbital inclinations (those not perturbed into the scattered disk as they spiraled outward) would experience considerable oxidation (rusting).

165. “Giant icy mountains in Pluto’s southern hemisphere tower more than 3,500 meters [actually 15,000 feet or 2.8 miles] high in the first high-resolution images that New Horizons sent back. The peaks’ sheer height signals that they are made of water ice, the only material that could buttress such huge ridges at Pluto’s frigid temperatures of less than -223°C, just 50 °C, above absolute zero.” Alexandra Witze, “Vibrant Pluto Seen in Historic Fly-By,” Nature, Vol. 523, 23 July 2015, p. 389.

166. Dwayne Brown and Laurie Cantillo, New Horizons, http://pluto.jhuapl.edu/News-Center/News-Article.php? page=20150715

u “Pluto’s diverse surface geology and long-term activity also raise fundamental questions about how it has remained active many billions of years after its formation.” S. Alan Stern et al., “The Pluto System: Initial Results from its Exploration by New Horizons,” Science, Vol. 350, 16 October 2015, p. 292.

167. Scott J. Kenyon, “Pluto Leads the Way in Planet Formation,” Nature, Vol. 522, 4 June 2015, p. 40.

168. Mark Showalter as quoted by Christopher Crockett, “Pluto’s Smaller Moons Pose Mysteries,” Science News, Vol. 188, 28 November 2015, p. 14.

169. “This observation is surprising, as it is difficult to imagine how to bind two small bodies that never come closer to each other than a distance of 85,000 km [53,000 miles].” Jean-Marc Pettit et al., “The Extreme Kuiper Belt Binary 2001 QW₃₂₂,” Science, Vol. 322, 17 October 2008, p. 433.

170. “Jean-Luc Margot, “Worlds of Mutual Motion,” Nature, Vol. 416, 18 April 2002, pp. 694–695.

171. John Travis, “A Double Target for a Distant Probe?” Science, Vol. 357, 11 August 2017, p. 532.

172. “But particles can’t stick unless they collide gently. Careening rocks and ice chunks in elongated, high-inclination orbits—like many of those in the Kuiper Belt today—would hit with high velocity, which would break them [the flying rock piles] apart instead of building them up. Only objects in more circular orbits have low enough relative velocities to coalesce.
     That means that the belt’s biggest bodies ... would never have formed unless they originally followed more circular, low-inclination orbits. In addition, the belt must have been much more crowded and thousands of times heavier than it is today. Like a ghostly highway with only a few cars, the belt nowadays has such a low density of objects that any collision—whether a high-speed crack-up or a low speed merger—is improbable.” Ron Cowen, “On the Fringe,” Science News, Vol. 177, 16 January 2010, p. 17.

173. Michael C. Lemonick, “Pluto and Beyond,” Scientific American, Vol. 311, November 2014, p. 52.

174. Before moons were discovered around asteroids, asteroid mass could be estimated only by multiplying an asteroid’s volume by its assumed density. Such assumptions produced considerable error, because from Earth each asteroid looked like a big, solid rock, not a flying rock pile containing ice and voids. Now that moons can be observed orbiting many asteroids, their masses and extremely low densities can be calculated directly. Using their average density, the total mass of all asteroids in the inner solar system can be more accurately estimated. While not all asteroids have been identified, the volumes of the largest thousand or so have been measured. Statistically, their size distribution shows that the smallest asteroids, although numerous, contribute relatively little to the total mass of all asteroids.

The Cassini mission to Saturn flew near Saturn’s irregular moon, Hyperion, a captured asteroid, as explained earlier. (Its density is 0.544 gm/cm³, light enough to float high in water if it were placed in a very large bathtub.) Hyperion also contains organic matter. What do you suppose was its origin? A good guess would be that the organic matter came from Earth—the only place where we know life exists. [See P. C. Thomas et al., “Hyperion’s Sponge-Like Appearance,” Nature, Vol. 448, 5 July 2007, pp. 50–53.]

The low densities of comets, asteroids, and TNOs are not surprising when one understands how they formed. Consider that:

v “[Comet Tempel 1 is] the size of a mountain held together with the strength of the meringue in a lemon meringue pie.” Carey M. Lisse, as quoted by Ron Cowen, “Deep Impact,” Science News, Vol. 168, 10 September 2005, p. 169.

v “[The comet’s] structure is more fragile than that of a soufflé ....”   Jay Melosh, as quoted by Ron Cowen, Ibid., p. 168.

175. Chadwick A. Trujillo and Scott S. Sheppard, “A Sedna-Like Body with a Perihelion of 80 Astronomical Units,” Nature, Vol. 507, 27 March 2014, pp. 471–473.

176. Andrew J. Dombard and Sean O’Hara, “Pluto’s Polygons Explained, Nature, Vol. 534, 2 June 2016, p. 40.

177. “But neither [study] satisfactorily addresses how so much of the nitrogen budget could have collected there [on Pluto]. ... Clearly, this localization of nitrogen was a major event in Pluto’s evolution that needs to be explored.” Ibid., p. 41.

178. “Internal heat could send molten blobs of material to the surface, driving geysers or even watery volcanoes that could spew fresh ices onto the surface. That scenario gained support when an early close-up picture revealed mountains, some 3500 meters high, composed of water ice. At Pluto’s temperatures, water ice is the bedrock: too solid to flow or sublime. So the presence of ice mountains implies that deep forces pushed them up. At the same time, surrounding plains of ice were remarkably crater-free—suggesting that another process had paved them over.” Eric Hand, “Scientists Ponder an Improbably Active Pluto,” Science, Vol. 349, 24 July 2015, p. 353.

179. John Travis, “Ice Volcanoes on Pluto’s Surface,” Science, Vol. 350, 13 November 2015, p. 722.

180. A. J. Trowbridge et al., “Vigorous Convection as the Explanation for Pluto’s Polygonal Terrain,” Science, Vol. 534, 2 June 2016, p. 79.

181. Megan E. Schwamb, “Stranded in No-Man’s-Land,” Nature, Vol. 507, 27 March 2014, p. 436.

182. Renu Malhotra, “Migrating Planets,” Scientific American, Vol. 281, September 1999, p. 59.

183. Mike Brown, as quoted by Ron Cowen, “Outer Limits,” pp. 26, 28.]

184. “But Sedna and other objects beyond the main Kuiper Belt probably weren’t born where they are today, because there simply wasn’t enough gas and dust available at those great distances to create sizeable worlds.” Alexandra Witze, “On the Hunt for a Mystery Planet,” Nature, Vol. 531, 17 March 2016, p. 291.

185. Scott S. Sheppard as quoted by Christopher Crockett, “Shadow Planet,” Science News, Vol. 186, 29 November 2014, p. 18.

186. R. B. Brown, personal communication on 21 May 2014.

187. A confidence level of 99.99% means that the statistical result could have been due to chance, but only 1 out of 10,000 times.

188. The efficiency of a Carnot engine is the temperature difference between the hot and cold sides divided by the hot side’s absolute temperature. At 1 AU, Pluto’s swarm would have had a temperature difference of about 510°F, similar to Earth’s moon. [See Figure 181 on page 347.] The average difference between Earth’s day and night temperatures is about 25°F. Therefore the ratio in efficiencies is about 15).

189. “You would expect the arguments of perihelion to have been randomized over the life of the solar system.” Scott Sheppard as quoted by Michael D. Lemonick, “The Search for Planet X,” Scientific American, Vol. 314, February 2016, p. 32.

u Two perturbing forces that caused this were:

i. thrusting described on page 363.

ii. gravitational forces of the Sun and planets acting on each TNO. (Because all orbiting bodies were not coplaner, these perturbation forces were not zero.)

For a good discussion of how perturbing forces change w over time, see Roger Bate et al., Fundamentals of Astrodynamics (New York: Dover Publishing, Inc., 1971), pp. 396–407. Notice on page 405 that the rate of change of w is extremely rapid when eccentricity is near zero, which is the case for objects spiraling outward from the Sun.

190. Christopher Crockett, “Shadow Planet,” Science News, Vol. 186, 29 November 2014, p. 19.

191. Carnot engines are the simplest of all thermodynamic engines. To understand Carnot engines, consult any introductory textbook on thermodynamics.

192. Alexandra Witze, “Flying on Sunshine,” Science News, Vol. 18, 10 September 2011, p. 19.

193. Gravity boosts by a giant planet can easily place a TNO in a highly inclined orbit. Xena and Buffy are two such TNOs. Their high angles of inclination have perplexed evolutionists.

Xena and Buffy stick out like sore thumbs. No theory, even one in which planets plow through the Kuiper Belt, can explain such high tilts, notes [Harold F.] Levison. He and other theorists are struggling to incorporate these new finds into their models. [See Cowen, “Outer Limits,” p. 28.]

Levison has it backwards. Rather than imagining a planet “plowing through the Kuiper Belt,” he should consider outward spiraling TNOs passing near any giant planet.

194. Sushil K. Atreya, “The Mystery of Methane on Mars & Titan: It might mean Life”; Scientific American, Vol. 296, May 2007, p. 42.

195. Schwamb, p. 435.

196. Konstantin Batygin and Michael E. Brown, “Evidence for a Distant Giant Planet in the Solar System,” The Astronomical Journal, Vol. 151, 20 January 2016, pp. 22–35.

u Eric Hand, “Number 9,” Science, Vol. 351, 22 January 2016, pp. 330–333.

197. Cowen, “On the Fring,” p. 17.]

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