THE EARTH
FORMS
ABOUT
1 SEPTEMBER; ABOUT 668,500 METERS UP THE LINE
Some 13.8 billion years ago, a
universe came into existence. Perhaps this was the product of sheer random
possibility. Perhaps it was another iteration of a physical reality that has
existed and will exist in perpetuity. That universe brought forth all the
tendencies, forces, laws, and basic particles by which physical reality as we
currently understand it came to be. Those tendencies, forces, laws, and
particles first constructed stars, and then regions where stars were created en masse, galaxies. Our galaxy came into
being between 11 billion and 12 billion years before the present, and grew to
be an immense, slowly rotating spiral with hundreds of billions of stars. Out
of that galaxy there emerged, about 4.567 billion years ago, a solar system
governed by an above-average sized but still largely unremarkable star, our
Sun. The nebular cloud out of which that Sun and the bodies that surrounded it
were formed had been enriched by multiple supernova events, which bestowed upon
it every naturally occurring element. In the process of forming the solar
system containing these elements, a particular region of the nebular cloud
brought together collections of “heavy” elements in significant quantities
through the process of accretion. The materials that were brought together in
this region became a planet heavy with iron, a small world insignificant in
size, but one which settled into orbit around the new star in a zone that was
drenched in that star’s energy, but not overwhelmed by it. That little world
was to become the only place we know with any certainty where life came to be,
for we are the inheritors of the first forms it took. We are the inhabitants of
that tiny planet, the Earth, which is the stage upon which the human experience
has occurred, and the place that gave rise to the consciousness that looks back
on its own origins, and attempts to piece together its own story.
Current Ideas About the Formation of the Earth
The formation of planets from
protoplanetary disks is an area of intense study. The consensus of scientific
opinion is that the Earth and the other planets formed through the accumulation
of what are known as planetesimals.
Planetesimals are small bodies that gradually come together to form larger
bodies, a complex process that is still being elucidated. In our solar nebula,
it is now thought by many researchers that minerals containing magnesium and
iron formed relatively close to the protosun, in the region we now call the
Inner Solar System. It is now thought that when the Sun ignited, and the
nuclear fusion process began, the ignition wiped away all the small particles
and residual gas that remained in the region that was to be the domain of the
inner planets. The only bodies that were unaffected were the planetesimals, which
continued to collide and combine until two of them developed significant
gravitational fields and dominated the region: Earth and Venus. 1
A reasonably good explanation of
planetesimal formation has emerged in recent years. Observations of nascent solar
systems have confirmed the essentials of nebular theory, and protoplanetary
disks 1 million to 10 million years of age are now studied with regularity. The
period of solar system development from 10 million to 100 million years has
been facilitated by the study of debris disks, the result of the collisions of
larger bodies. These larger bodies may be a system’s first planetesimals.
Astrophysicists have identified
three broad phases in the development of planetesimals. At the very smallest size
scales, with dust of less than one centimeter (and much of that dust
microscopic in size), the processes of chemical bonding and the weak electrical
attraction between molecules known as van der Waals forces act to bind them
together. A series of intermediate steps (see below) advances the process of
formation until objects larger than one kilometer have been formed, at which
time gravity takes over as the dominant factor in planetesimal formation.2
It would appear that planetesimals must form within the first few million years
of a solar system’s inception, before the great mass of hydrogen and helium in
it evaporates/dissipates.3
Within a protoplanetary disk,
there are many variations of gas pressure, and solids tend to drift toward the
areas with maximum gas pressure.4 If particles of solid matter
collide when they are moving slowly enough, if they dissipate enough energy
during the collision, and if they are small enough in size when they run into
each other, they stick together.5 At different phases in the process
of planetesimal formation, we see phenomena that promote the growth of such particles, and other
phenomena that promote the concentration of
these particles (prior to processes that will once again promote growth). On
the very smallest scales, with particles between 10-7 and 10-4
meter in size, the phenomenon of particle sticking, as noted above, promotes
growth. When these rudimentary structures reach about 10-4 meters in
size, they then become concentrated by settling into thin, vertical layers. Gravitational
instability assisted by drag forces (broadly understood as friction) first
helps pieces of matter grow to about a meter in size, and then the process of
streaming instability, basically the mutual drag forces between solids and gases,
helps concentrate these meter-sized objects. Turbulence helps these pieces
clump together, which causes the process of gravitational collapse to take
over, and objects of half a kilometer in size form. From that point onward,
gravitationally driven collisions smash pieces together into larger and larger
structures with multiple-kilometer sizes.6
It is thought for this process to
gain initial momentum that grains within regions of a protoplanetary disk must
exceed a density of greater than 1000 times the ambient gas density to become
gravitationally bound. Further, there must be a huge dust abundance spread out
widely in the disk. (The high gas pressures that can trap particles can be
created by turbulence.) The first generation building blocks of planetesimals
may be chondrules, melted pieces of
matter found in meteorites. These chondrules were apparently flash-heated at
the time of the solar system’s formation, but the manner in which this was done
is still unclear. And in the overall formation of planetesimals, the respective
roles of sticking and self-gravity are still being elucidated.7
The Place of the Earth in the Solar System
The Earth lies within what
astronomers and astrophysicists call the solar system’s snow line. When planets were emerging from our system’s
protoplanetary disk, this was the boundary between the region in which it was
possible for gases to condense to liquid water and the region in which the
temperatures were so low that condensation was not possible. In the region
beyond the snow line, any water present took the form of ice. Some researchers
have placed the snow line in the range of 1.6 to 1.8 AU, somewhere around 250
million kilometers from the Sun, or just beyond Mars’ orbit. Others postulate
that it must have been somewhat farther out, more in the range of 2.7 AU, about
400 million kilometers from our star. A snow line beyond 2.7 AU is considered
somewhat unlikely, given our assumptions about the rate at which accretion took
place and the amount of mass estimated to have been in the minimum mass solar
nebula.8 Scientists believe that the Earth’s position relative to
the Sun places it in the region of the solar system most favorable to the
development of advanced life forms. It is in a region where its temperatures
are somewhat moderate by solar system standards, and the processes by which it
formed made it large enough of a body to retain an atmosphere and areas of
liquid surface water.
Possible Origin of the Moon
The early solar system was a
place of tremendous chaos, characterized by frequent, violent collisions
between solid bodies. The best hypothesis we have concerning the origin of the
Moon is that while the Earth was still in a formative stage it was struck a
glancing blow by a Mars-sized planet. Most of the huge mass of material scoured
away by this collision was taken from the Earth’s mantle, naturally, and the
pieces of shattered material were confined by the Earth’s gravitational field
and eventually coalesced into the Moon. This hypothesis is the most widely accepted
one, but there are still unresolved problems with it.9 The Moon is
too small to retain any significant atmosphere, although it apparently harbors
water (perhaps bestowed upon it by some of the objects that struck it), and it
is thought to have been barren throughout its entire 4.5 billion year
existence. As planetary satellites go, it is unusually large. The Moon, as we
will see, has had and still has a significant influence on the Earth.
The Basic Composition and Structure of the Earth
In the 1970s, research based on
the study of meteorites indicated that the Earth is probably around 36% iron,
29% oxygen, 14% silicon, 13% magnesium, and 2% nickel. Of the remaining 6%,
calcium, aluminum, and sulphur are most prominent.10 By the late
1990s more refined methods of analysis changed the figures for the overall
composition of the Earth somewhat. More current research therefore puts the
Earth’s chemical composition at about 32% iron, 30% oxygen, 16% silicon, 15%
magnesium, and a little less than 2% nickel.11 However, this
distribution of elements is not uniform throughout the interior of the Earth,
and the outer crust—the home of our diminutive species—is overwhelmingly
composed of oxygen and silicon, with a significant amount of aluminum as well.12
The formation of the Earth into
layers, what is known as its differentiation,
was of enormous importance.13 In textbooks the stratification of the
Earth’s layers sometimes looks as if the Earth’s interior is subdivided into
neatly defined, perfectly spherical regions, but such representations are more
symbolic than realistic. The layers of the Earth are the crust, the upper mantle,
the lower mantle, the core. and the inner core. The outer and inner core together occupy about 15% of
the Earth’s volume. The inner core by itself comprises less than 1%. There is,
according to recent research, a distinct innermost region of the inner core, a
region which makes up a negligible 0.01% of the Earth’s volume.14 In
total, about 99% of the Earth’s volume is in the core and the mantle of the
planet. The mantle, as a whole, comprises about 84% of the Earth’s volume. Its
different regions have different chemical characteristics.15 In
fact, the different chemically distinct regions in the mantle follow no neat,
perfectly concentric scheme. The mantle appears to have internal boundaries at
about 650 kilometers, and there are indications of mantle regions
chemically-distinct from others at around 900 kilometers.16 The
crust, the layer of the Earth on which we live is, basically, the residual material
left over from the processes of melting and cooling that operated during the
Earth’s formative period. The crust, in effect, “floats” on the upper mantle,
although strictly speaking the upper mantle isn’t liquid. The thickness of the
crust varies somewhat from region to region. The great majority of the
continental crust in our era is between 30 and 45 kilometers in thickness, with
thicknesses of greater than 50 kilometers rare. The crust below the ocean floor
is much thinner, and densities of 10 kilometers are common.17
The Earth has a distinct magnetic
field, which appears to be generated by its iron core. This magnetic field has
shifted many times in the Earth’s history, as evidenced by changing patterns
within iron-bearing rocks. Recent evidence indicates the magnetic field has
shifted three hundred times just in the last 200 million years.18 It
is the Earth’s magnetic field that protects our planet from the potentially
destructive effects of the solar “wind”. It also holds the charged particles of
the Van Allen Radiation belts in
place.
Physical Conditions on the Early Earth
The earliest period of the
Earth’s geological history is known as the Hadean
Eon, the approximately 700 million year period between 4.5 billion and 3.8
billion years before the present. (Some researchers prefer to define the end of
the Hadean as having been around 4 billion ybp.) We are hindered in our study
of it by the fact that the very earliest rocks from that era have been
destroyed by natural processes, and only the most fragmentary mineral traces
remain. Geochemical analysis has been done on samples of crustal material and
zircon grains that have survived from the Hadean. Zircons, ZrSiO4,
are remarkably durable, and crystals of zircon sometimes have uranium and hafnium
in them, which permits their dating by radiometric methods. The very oldest
zircons that have been discovered are from the Jack Hills region of Western
Australia, and have been reliably dated at 4.4 billion years before the
present—only 150 million years after the formation of the solar system itself.
These zircons have given geologists intriguing evidence that Earth may have had
liquid water and possibly even oceans prior to 4 billion ybp, and that
continents might have begun forming in this period as well. Scientists are
cautious about these interpretations because such ancient zircons have only
been found in one place, and it is not certain whether the conditions they seem
to indicate were localized or generalized phenomena.19
In 2010, researchers presented
evidence that lavas found on Baffin Island, in Canada’s far north, and in
western Greenland are from a deep reservoir of mantle material that has
remained hidden since 4.5 billion ybp. This material has so far been analyzed
in three different ways, and the three tests taken together strongly suggest
that these lavas may be the oldest parts of the ancient Earth ever discovered.20
What they can tell us about the early Hadean awaits further investigation.
It took many millions of years of
planetesimal accretion for the Earth to gain its eventual size, although the
largest part of the process was probably finished within 10 million years. It
is now thought that the violent slamming together of large planetesimals in the
latter stages of the Earth’s accretion produced an early planet that was
intensely hot, seething with geothermal activity. Add to this the heat coming
from radioactive sources within the new planet itself, and a picture of a
molten world emerges.21 Indeed, the name Hadean conjures up images
from mythology, the early Earth as a “Hades-like” environment. This picture is
probably broadly correct, but our understanding of the duration of the hottest
and most chaotic period is limited. It appears now that this molten, hellish
phase may have lasted only a few million years, and that upon its waning the
Earth’s crust began to form.
In all likelihood the Earth
underwent very extensive bombardment by asteroids and comets during the Hadean
Eon, with asteroids making up the largest number of projectiles. Evidence of
the tremendous numbers of such objects in the early solar system can be seen in
the scarred surfaces of Mercury, the Moon, and Mars. The Sun during this early
period was probably much less luminous, but its output of ultraviolet rays, x-rays,
and solar wind was probably much greater.22 Stars gain luminosity as
they mature, and the fact that the Sun was less luminous in the days of the
early Earth may have had a significant impact on the planet’s development.
Earth scientists are of the opinion
that in this earliest phase of the Earth’s history there was nothing resembling
tectonic activity of the kind with which we are familiar, the shifting of
pieces of the Earth’s outer crust on the mantle. The processes and structures
involved in tectonic activity were not yet fully in place, and they would not
be for perhaps more than a billion years.23
Possible Origins of the Earth’s Bodies of Water
Although there is seemingly a
vast amount of water on this planet, in fact its total mass comprises a surprisingly
small percentage of the Earth’s overall mass. But it is the existence of this
water that distinguishes the Earth from all other planets in the solar system,
and the Earth’s water is thought to have been absolutely crucial in the origin
and evolution of life on this planet. Several plausible scenarios have been
presented over recent years to account for the presence of the world ocean on
the crust of our planet. It has been proposed that the planetesimals that
formed the Earth carried trace amounts of water themselves, and that during the
process of the cooling of the magma ocean on the early Earth’s surface, as
silicon-bearing minerals solidified, this water was extruded. It has been
further hypothesized that accompanying this process, and of even more crucial
importance in the formation of the ocean, was steam in the early Earth’s
atmosphere cooling and condensing into large quantities of liquid water.24
Other researchers contend that the nebular cloud out of which our solar
system was born gave the early Earth a hydrogen-rich atmosphere. In this
environment, it is thought, oxides present in the magma oxidized the
atmospheric hydrogen to produce liquid water.25 Still other
scientists argue that while we don’t yet have a definitive explanation for the origin of the Earth’s water, the
accretion of water-bearing chondrites in the period after the Earth’s core was
formed has the best supporting evidence.26 The role of
comets in depositing water on the early Earth has long been debated. Arguments
have often centered on the proportion of 2H, deuterium, in water
present in comets compared to terrestrial water. Comets have been discounted as
a source of the world’s ocean because comets originating in the Kuiper Belt
region or the Oort Cloud have a higher proportion of deuterium in them than
Earth’s ocean water. But in 2006 scientists from the University of Hawaii
presented evidence of comets originating not in the solar system’s more distant
regions but in the asteroid belt between Mars and Jupiter. Such objects are
known as main-belt comets (MBCs).
These comets may have—may have—very
well struck the primordial Earth in large numbers and deposited great
quantities of water. An analysis of their isotopic composition could revive the
case for comets as a major source of the Earth’s water.27
It is entirely possible that the
Earth’s water originated in several different ways, perhaps a combination of
outgassing (the release of gases from the interior of the Earth), extended,
torrential rainfall triggered by the early Earth’s atmospheric chemistry, and
water from comets, asteroids, and chondrites together. The question is still
open. But however it occurred, it is reasonably certain that there was a significant
amount of water on this planet by 4 billion ybp. Liquid water also probably
existed in significant quantities on Venus and Mars at one time as well, but it
only remains here. The Blue Planet is an anomaly in its home solar system.
Hypotheses About the Early Earth’s Atmosphere
It has been proposed that the Earth
has had three different atmospheres in succession, although there is not
consensus on this point. Given the extensive volcanism of the Hadean, it is
quite possible that the earliest atmosphere was the product of outgassing. At
one time it was speculated that the Earth’s early atmosphere may have been
highly reduced (that is, one without oxidizing agents, an atmosphere dominated
by methane and ammonia) but this is now considered unlikely.28
(There may have been, however, significant quantities of methane, even if not
overwhelming ones.) Many scientists are convinced that Earth’s original
atmosphere was simply hydrogen gas. It has been thought that this hydrogen
atmosphere was quickly lost through dissipation into space, but findings published
in 2005 cast doubt on this belief, presenting evidence that heavy
concentrations of hydrogen may have existed for perhaps a hundred times longer
than previously believed. And why was this significant? It may have helped
facilitate the production of chemical compounds conducive to the formation of
life:
Although early Earth's atmosphere might have
been dominated by CO2 immediately after
the heavy bombardment period, as continents formed on early Earth, the
atmospheric CO2 concentration
would decline because of weathering, and the H2/C ratio would
become suitable for efficient formation of prebiotic organic compounds through
electric discharge. Formation of prebiotic organic compounds by electric
discharge at this conservative rate in a hydrogen-rich early Earth's atmosphere
would have created an ocean with a steady-state amino acid concentration ∼10-6 mol/liter…which is
orders of magnitude greater than the amino acid concentration estimated for a
hydrogen-poor early Earth's atmosphere… This amino acid concentration is highly
uncertain because neither the production rate nor the destruction rate is well
known. In addition, organic films may have formed at the ocean surface, leading
to higher concentrations of organic compounds than in the bulk sea water.29
The
contention that hydrogen escaped into space much more slowly than believed has
its critics, however, and the question is still an open one. But it is an issue
of potentially very great significance.
There are researchers who contend
that the presence of certain isotopes of krypton and xenon in our current
atmosphere may indicate they were deposited by comets or gas clouds that
enveloped the early Earth. It is possible, according to these scientists, that
many other gases in our atmosphere are of extraterrestrial origin as well.30
Again, given the uncertain state of our knowledge about much of the early
Earth, it is possible that a number of different processes were influencing the
evolution of the atmosphere and contributing distinct features to it.
The oxygenation of the atmosphere
was largely the byproduct of oxygenic photosynthesis, which we will examine in
a later chapter. It is not probable that there was any significant atmospheric oxygen in the Hadean
environment.
Other Considerations
The end result of the process of
the Earth’s formation was a planet 12,742 kilometers in diameter (on average;
since the Earth is slightly flattened at the poles, its equatorial diameter is
greater than its polar diameter) and 40,075 kilometers in circumference, a
world of trifling size. The planet has an axial tilt of about 23.5 degrees from
perpendicular, a fact of exceeding significance for the characteristics of the
Earth’s seasons. The exact cause of the Earth’s tilt, by the way, has not been
determined, but it may be related to the violent collisions and bombardments
the Earth went through in its early period.31 Over the last 4.5
billion years the length of the day has gradually increased because of the
tidal forces exerted by the Moon (and to a lesser extent the Sun and other
bodies). In its earliest times the Earth’s day was perhaps no longer than a few
hours. Currently the exact length of the sidereal day is 23 hours, 56 minutes,
4.09054 seconds.32 Over historical time (for our purposes, the past
5,000 years) the day may have lengthened by about .0014 of a second per
century.33 The sidereal year
is 365.25636 days, or 365 days, 6 hours, 9 minutes, and 10 seconds.34
This deviation from an exact 365 day orbital time forced the solar calendar
makers in the earliest civilizations to make adjustments. As the length of the
year has been ascertained with greater accuracy over the centuries, more
adjustments, such as the insertion of leap seconds, have been made. The Sun
appears to “rise” in the east because of the counter-clockwise (as seen from
the North Pole) rotation of the planet, and the exact direction of the Sun’s
rise at a given latitude differs seasonally. And the rotation of the Earth is
undergoing a gyroscopic “wobble” known as the precession of the axis, analogous to what happens when the
uppermost part of a spinning top begins to gyrate in the shape of a circle. The
Earth’s axis goes through this process every 26,000 years.35
So what can we conclude from this
brief examination? I believe the most obvious point is that the Earth was—and
is—an environment of tremendous dynamism, even volatility. The Earth’s
energy-matter reconfigured itself again and again during the Hadean, and at the
surface of the Earth, its crust, the interplay between gases erupting from the planet’s
interior, the early atmosphere, the earliest bodies of water, the relatively
weak but still influential Sun, and objects from outer space crashing into the
planet must have produced a drama of unparalleled scope in the geological history
of this tiny little terrestrial world. In its first 500 million to 700 million
years, the Earth acquired its basic dimensions, its basic internal structure, a
relatively stable atmosphere, the first continental landmasses, and the first
true world ocean. Most significantly, it was already being differentiated into
a series of local environments, areas in which conditions varied, sometimes
very greatly, from other regions of the young planet. This phenomenon, while
seemingly obvious, is of great importance. It meant that once life became
established on this world that it faced a tremendously varied set of conditions
and consequently evolved in a very wide variety of ways, as we will see.
The Earth by around 4,000,000,000
years before the present had all the necessary prerequisites for the
establishment of life: a position in the solar system that allowed it to absorb
great amounts of energy from its local star while not being so close to it that
the planet was rendered uninhabitable, sufficient size to maintain an atmosphere,
a temperate climate over much of the planet, a variety of elements that formed
compounds readily, and widely available water. Most significantly, the
interaction of these physical variables produced a suitable chemical
environment for the development of metabolic processes and eventually a kind of
molecule that could use the energy gathered from such primitive metabolic
processes to aid in its own replication. These molecules included carbon atoms,
which bonded readily and in a variety of ways with other atoms. It was these
replicating molecules that established a sort of chemical template, one that
would ensconce itself firmly on the outer regions of our tempestuous planet: if
a piece of energy-matter gathered sufficient energy to maintain itself, it could
establish a self-reinforcing pattern that would allow it to proliferate. It
could, in other words, establish a reproductive synergy, and in replicating it
became subject to the processes of natural
selection, which we will examine in some detail in the next chapter.
The Earth was ready to bring
forth its first life forms, physical entities constructed out of some of the handiest and most common
materials the planet had to offer. Life
is simply one of the “tricks” energy-matter is capable of performing, and that
trick was about to be performed. This event has no doubt happened in many
places in the Universe, and in many different ways. But the fact that it
happened here, on this planet, meant that the rise of our kind of consciousness
became somewhat more probable. This rise was not inevitable, however, not by
any means. The life forms that were to evolve on this world would be shaped by
its structural, chemical, climatic, and astrophysical features at every
conceivable turn. The chemical evolution that swept over the planet’s surface
set the stage for the organic evolution that was to produce the stunning array
of viral, microbial, fungal, plant, and animal life that has spread to
virtually every corner of the Earth’s outer crust. The Earth was a suitable stage
for this epic, but it was also an indifferent one. It was not Mother Earth or
Mother Nature or any of the other names by which humans have tried to personify
it. It was simply a place in the Universe that just happened to have the right
circumstances to allow self-reproducing energy-matter to exist. It did not
celebrate life’s presence; it will not mourn its absence. And despite the
pretensions of the upright ape-like creatures who imagine themselves to be its
master, the truth is stark and simple: we live here and survive here only with
the Earth’s blind, mindless “permission”—permission that can be withdrawn at
any time.
1. Mathez, Edmond A., and Webster, James D., The Earth Machine: The Science of a Dynamic Planet, 5-7
2. Chiang, E., and A. N. Youdin “Forming Planetesimals in Solar and Extrasolar Nebulae” in Annual Review of Earth and Planetary Sciences, Volume 38, 2010, pp. 494-495
3. Chiang , 498
4. Chiang, 501
5. Chiang, 504
6. Chiang, 507
7. Chiang, 516-518
8. M. Lecar, M. Podolak, D. Sasselov, and E. Chiang, “On the Location of the Snow Line in a Protoplanetary Disk”, in Astrophysical Journal 1 April 2006
9. University College London, located at: http://www.es.ucl.ac.uk/research/planetary/undergraduate/bugiolacchi/moonf.htm
10. Bott, Martin H. P. The Interior of the Earth: its structure, constitution and evolution, pp. 21-22
11. William F McDonough, “The Composition of the Earth”, Harvard University
12. Bott, p. 73
13. Mathez, and Webster, p. 8
14. Anderson, Don. L. “The inner inner core of Earth” from Proceedings of the National Academy of Sciences of the United States of America (PNAS), 29 October 2002
15. Biju-Duval, Bernard, Sedimentary Geology: Sedimentary Basins, Depositional Environments, Petroleum Formation, pp. 17-18
16. Anderson
17. The Earth’s Crust, The United States Geological Service, located at: http://earthquake.usgs.gov/research/structure/crust/
18. Vogel, Shawna, Naked Earth: The New Geophysics, p. 96
19. K. Zahnle, N. Arndt, C. Cockell, A. Halliday, E. Nisbet, F. Selsis, N.H. Sleep, “Emergence of a Habitable Planet” in Geology and Habitability of Terrestrial Planets, Edited by Kathryn E. Fishbaugh,
Philippe Lognonné, François Raulin, David J. Des Marais, and Oleg Korablev, pp. 61-62
20. David Graham, “Relict mantle from Earth’s birth”, Nature, 12 August 2010
21. Zahnle, Kevin, Nick Arndt, Charles Cockell, Alex Halliday, Euan Nisbet , Franck Selsis, Norman H. Sleep. “Emergence of a Habitable Planet” in Space Science Review, 25 July 200737-46
22. Zahnle, et al, pp. 38-39
23. Kent Condie, “When Did Plate Tectonics Begin on Planet Earth”, 2 October 2008, located here: http://www.scitopics.com/When_Did_Plate_Tectonics_Begin_on_Planet_Earth.html
24. Linda T. Elkins-Tanton, “Formation of early water oceans on rocky planets” in Astrophysics and Space Science, (2011) 332: 359–364
25. Hidenori Genda and Masahiro Ikoma, “Origin of the Ocean on the Earth: Early Evolution
of Water D/H in a Hydrogen-rich Atmosphere” in Icarus (6 Sep 2007)
26. Jun Korenaga, “Plate tectonics, flood basalts and the evolution of Earth’s oceans” in Terra Nova, 20, 419-439, 2008
27. Henry H. Hsieh and David Jewitt, “A Population of Comets in the Main Asteroid Belt” in Science 28 April 2006: Vol. 312 no. 5773 pp. 561-563, DOI: 10.1126/science.1125150
28. James F. Kasting and M. Tazewell Howard, “Atmospheric composition and climate on the early Earth”, Philosophical Transactions of the Royal Society, B Biological Sciences, 2006 October 29; 361(1474): 1733–1742
29. Feng Tian, Owen B. Toon, Alexander A. Pavlov, H. De Sterck, “A Hydrogen-Rich Early Earth Atmosphere” in Science, 13 May 2005: Vol. 308 no. 5724 pp. 1014-1017 DOI: 10.1126/science.1106983
30. Science News, December 10, 2009
31. William F. Bottke, Richard J. Walker, James M. D. Day, David Nesvorny, Linda Elkins-Tanton,
“Stochastic Late Accretion to Earth, the Moon, and Mars” in Science 10 December 2010:
Vol. 330 no. 6010 pp. 1527-1530 DOI: 10.1126/science.1196874
32. “Day” http://www.sizes.com/time/day.htm
33. United States Naval Observatory, located at http://tycho.usno.navy.mil/leapsec.html
34. “Year” http://www.sizes.com/time/year.htm
35. NASA
1. Mathez, Edmond A., and Webster, James D., The Earth Machine: The Science of a Dynamic Planet, 5-7
2. Chiang, E., and A. N. Youdin “Forming Planetesimals in Solar and Extrasolar Nebulae” in Annual Review of Earth and Planetary Sciences, Volume 38, 2010, pp. 494-495
3. Chiang , 498
4. Chiang, 501
5. Chiang, 504
6. Chiang, 507
7. Chiang, 516-518
8. M. Lecar, M. Podolak, D. Sasselov, and E. Chiang, “On the Location of the Snow Line in a Protoplanetary Disk”, in Astrophysical Journal 1 April 2006
9. University College London, located at: http://www.es.ucl.ac.uk/research/planetary/undergraduate/bugiolacchi/moonf.htm
10. Bott, Martin H. P. The Interior of the Earth: its structure, constitution and evolution, pp. 21-22
11. William F McDonough, “The Composition of the Earth”, Harvard University
12. Bott, p. 73
13. Mathez, and Webster, p. 8
14. Anderson, Don. L. “The inner inner core of Earth” from Proceedings of the National Academy of Sciences of the United States of America (PNAS), 29 October 2002
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