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Theories Of The Origin Of The Moon

Essay, Research Paper


The Moon is the only natural satellite of Earth. The distance from Earth


is about


384,400km with a diameter of 3476km and a mass of 7.35*1022kg. Through


history it has had many names: Called Luna by the Romans, Selene and


Artemis


by the Greeks. And of course, has been known through prehistoric times.


It is


the second brightest object in the sky after the Sun. Due to its size and


composition, the Moon is sometimes classified as a terrestrial "planet"


along with


Mercury, Venus, Earth and Mars.


Origin of the Moon


Before the modern age of space exploration, scientists had three major


theories for the origin of the moon: fission from the earth; formation in


earth


orbit; and formation far from earth. Then, in 1975, having studied moon


rocks


and close-up pictures of the moon, scientists proposed what has come to be


regarded as the most probable of the theories of formation, planetesimal


impact


or giant impact theory.


Formation by Fission from the Earth


The modern version of this theory proposes that the moon was spun off from


the earth when the earth was young and rotating rapidly on its axis. This


idea


gained support partly because the density of the moon is the same as that


of


the rocks just below the crust, or upper mantle, of the earth. A major


difficulty


with this theory is that the angular momentum of the earth, in order to


achieve


rotational instability, would have to have been much greater than the


angular


momentum of the present earth-moon system.


Formation in Orbit Near the Earth


This theory proposes that the earth and moon, and all other bodies of the


solar


system, condensed independently out of the huge cloud of cold gases and


solid


particles that constituted the primordial solar nebula. Much of this


material


finally collected at the center to form the sun.


Formation Far from Earth


According to this theory, independent formation of the earth and moon, as


in


the above theory, is assumed; but the moon is supposed to have formed at a


different place in the solar system, far from earth. The orbits of the


earth and


moon then, it is surmised, carried them near each other so that the moon


was


pulled into permanent orbit about the earth.


Planetesimal Impact


First published in 1975, this theory proposes that early in the earth’s


history,


well over 4 billion years ago, the earth was struck by a large body called


a


planetesimal, about the size of Mars. The catastrophic impact blasted


portions


of the earth and the planetesimal into earth orbit, where debris from the


impact


eventually coalesced to form the moon. This theory, after years of research


on


moon rocks in the 1970s and 1980s, has become the most widely accepted


one for the moon’s origin. The major problem with the theory is that it


would


seem to require that the earth melted throughout, following the impact,


whereas


the earth’s geochemistry does not indicate such a radical melting.


Planetesimal Impact Theory (Giant Impact Theory)


As the Apollo project progressed, it became noteworthy that few scientists


working on the project were changing their minds about which of these three


theories they believed was most likely correct, and each of the theories


had its


vocal advocates. In the years immediately following the Apollo project,


this


division of opinion continued to exist. One observer of the scene, a


psychologist,


concluded that the scientists studying the Moon were extremely dogmatic and


largely immune to persuasion by scientific evidence. But the facts were


that the


scientific evidence did not single out any one of these theories. Each one


of them


had several grave difficulties as well as one or more points in its favor.


In the mid-1970s, other ideas began to emerge. William K. Hartmann and D.R.


Davis (Planetary Sciences Institute in Tucson AZ) pointed out that the


Earth, in


the course of its accumulation, would undergo some major collisions with


other


bodies that have a substantial fraction of its mass and that these


collision would


produce large vapor clouds that they believe might play a role in the


formation of


the Moon. A.G.W. Cameron and William R. Ward (Harvard University,


Cambridge MA) pointed out that a collision with a body having at least the


mass


of Mars would be needed to give the Earth the present angular momentum of


the


Earth-Moon system, and they also pointed out that such a collision would


produce a large vapor cloud that would leave a substantial amount of


material in


orbit about the Earth, the dissipation of which could be expected to form


the


Moon. The Giant Impact Theory of the origin of the Moon has emerged from


these suggestions.


These ideas attracted relatively little comment in the scientific community


during


the next few years. However, in 1984, when a scientific conference on the


origin


of the Moon was organized in Kona, Hawaii, a surprising number of papers


were


submitted that discussed various aspects of the giant impact theory. At the


same


meeting, the three classical theories of formation of the Moon were


discussed in


depth, and it was clear that all continued to present grave difficulties.


The giant


impact theory emerged as the "fashionable" theory, but everyone agreed that


it


was relatively untested and that it would be appropriate to reserve


judgement on


it until a lot of testing has been conducted. The next step clearly called


for


numerical simulations on supercomputers.


?The author in collaboration with Willy Benz (Harvard), Wayne L.Slattery at


(Los


Alamos National Laboratory, Los Alamos NM), and H. Jay Melosh (University


of


Arizona, Tucson, AZ) undertook such simulations. They have used an


unconventional technique called smooth particle hydrodynamics to simulate


the


planetary collision in three dimensions. With this technique, we have


followed a


simulated collision (with some set of initial conditions) for many hours of


real


time, determining the amount of mass that would escape from the Earth-Moon


system, the amount of mass that would be left in orbit, as well as the


relative


amounts of rock and iron that would be in each of these different mass


fractions.


We have carried out simulations for a variety of different initial


conditions and


have shown that a "successful" simulation was possible if the impacting


body had


a mass not very different from 1.2 Mars masses, that the collision occurred


with


approximately the present angular momentum of the Earth-Moon system, and


that the impacting body was initially in an orbit not very different from


that of the


Earth.


?The Moon is a compositionally unique body, having not more than 4% of its


mass in the form of an iron core (more likely only 2% of its mass in this


form).


This contrasts with the Earth, a typical terrestrial planet in bulk


composition,


which has about one-third of its mass in the form of the iron core. Thus, a


simulation could not be regarded as ?successful? unless the material left


in orbit


was iron free or nearly so and was substantially in excess of the mass of


the


Moon. This uniqueness highly constrains the conditions that must be imposed


on


the planetary collision scenario. If the Moon had a composition typical of


other


terrestrial planets, it would be far more difficult to determine the


conditions that


led to its formation.


The early part of this work was done using Los Alamos Cray X-MP computers.


This work established that the giant impact theory was indeed promising and


that


a collision of slightly more than a Mars mass with the Earth, with the


Earth-Moon


angular momentum in the collision, would put almost 2 Moon masses of rock


into


orbit, forming a disk of material that is a necessary precursor to the


formation of


the Moon from much of this rock. Further development of the hydrodynamics


code made it possible to do the calculations on fast small computers that


are


dedicated to them.


Subsequent calculations have been done at Harvard. The first set of


calculations


was intended to determine whether the revised hydrodynamics code reproduced


previous results (and it did). Subsequent calculations have been directed


toward


determining whether "successful" outcomes are possible with a wider range


of


initial conditions than were first used. The results indicate that the


impactor must


approach the Earth with a velocity (at large distances) of not more than


about 5


kilometers. This restricts the orbit of the impactor to lie near that of


the Earth. It


has also been found that collisions involving larger impactors with more


than the


Earth-Moon angular momentum can give "successful" outcomes. This initial


condition is reasonable because it is known that the Earth-Moon system has


lost


angular momentum due to solar tides, but the amount is uncertain. These


calculations are still in progress and will probably take 1 or 2 years more


to


complete


Bibliography


GIANT IMPACT THEORY OF THE ORIGIN OF THE MOON, A.G.W. Cameron,


Harvard-Smithsonian Center for Astrophysics, Cambridge MA 02138,


PLANETARY GEOSCIENCES-1988, NASA SP-498


EARTH’S ROTATION RATE MAY BE DUE TO EARLY COLLISIONS, Paula


Cleggett-Haleim, Michael Mewhinney, Ames Research Center, Mountain View,


Calif. RELEASE: 93-012


Hartmann, W. K. 1969. ?Terrestrial, Lunar, and Interplanetary Rock


Fragmentation.?


Hartmann, W. K. 1977. ?Large Planetesimals in the Early Solar System.?


1 "Landmarks of the Moon," Microsoft® Encarta® 96 Encyclopedia.


© 1993-1995 Microsoft Corporation. All rights reserved.


2 "Characteristics of the Moon," Microsoft® Encarta® 96


Encyclopedia. © 1993-1995 Microsoft Corporation. All rights


reserved.

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