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.
   Click here to order the hardbound 8th edition (2008) and other
   material.

   [ The Fountains of the Great Deep > The Origin of Comets > Gravity:
   How and Why Most Things Move ]
   
Gravity: How and Why Most Things Move

   Gravity pulls us toward Earth's surface. This produces friction, a
   force affecting and slowing every movement we make. Since we were
   babies, we have assumed that everything behaves this way. Indeed, none
   of us could have taken our first steps without friction and the
   downward pull of gravity. Even liquids (such as water) and gases (such
   as air) create a type of friction called drag, because gravity also
   pulls liquids and gases toward Earth's solid surface.
   
   In space, things are different. If we were orbiting Earth, its gravity
   would still act on us, but we would not feel it. We might think we
   were "floating" when, in fact, we would be falling. In a circular
   orbit, our velocity would carry us away from Earth as fast as we fell.
   
   As another example, in 1965 astronaut James McDivitt tried to catch up
   (rendezvous) with an object orbiting far ahead of him. He
   instinctively increased his speed. However, this added speed moved his
   orbit higher and farther from Earth where gravity is weaker and
   orbital velocities are slower. Thus, he fell farther behind his
   target. Had he temporarily slowed down, he would have changed his
   orbit, lost altitude, sped up, and traveled a shorter route. Only by
   slowing down could he catch up--essentially taking a "shortcut."
   
   All particles attract each other gravitationally. The more massive and
   the closer any two particles are to each other, the greater their
   mutual attraction. To determine the gravitational pull of a large
   body, one must add the effects of all its tiniest components. This
   seems a daunting task. Fortunately, the gravitational pull of a
   distant body behaves almost as if all its mass were concentrated at
   its center of mass--as our intuition tells us.
   
   But what if we were inside a "body," such as the universe, a galaxy,
   or Earth? Intuition fails. For example, if Earth were hollow and we
   were inside, we would "float" ! The pull from the side of the
   spherical shell nearest us would be great because it is close, but
   more mass would pull us in the opposite direction. In 1687, Isaac
   Newton showed that these pulls always balance.^20
   
   Tides. A water droplet in an ocean tide feels a stronger gravitational
   pull from the Sun than from the Moon. This is because the Sun's huge
   mass (27 million times greater than that of the Moon) more than makes
   up for the Sun's greater distance. However, ocean tides are caused
   primarily by the Moon, not the Sun. This is because the Sun pulls the
   droplet and the center of the Earth toward itself almost equally,
   while the much closer Moon pulls relatively more on either the droplet
   or the center of the Earth (whichever is nearer). We best see this
   effect in tides, because the many ocean droplets slip and slide so
   easily over each other. (To learn more about what causes tides, see
   page 473.)
   
   Tidal effects act everywhere on everything: gases, liquids,
   solids--and comets. When a comet passes near a large planet or the
   Sun, the planet or Sun's gravity pulls the near side of the comet with
   a greater force than the far side. This difference in "pulls"
   stretches the comet and sometimes tears it apart. If a comet passes
   very near a large body, it can be pulled apart many times; that is,
   pieces of pieces of pieces of comets are torn apart as shown in
   Figure 148.
   
   comets-string_of_pearls_shoemaker_levy9.jpg Image Thumbnail
   
   Figure 148: Weak Comets. Tidal effects often tear comets apart,
   showing that comets have almost no strength. Two humans could pull
   apart a comet nucleus several miles in diameter. In comparison, the
   strength of an equally large snowball would be gigantic. In 1992,
   tidal forces dramatically tore comet Shoemaker-Levy 9 into 23 pieces
   as it passed near Jupiter. Two years later, the fragments, resembling
   a "flying string of pearls" strung over 180,000,000 miles, returned
   and collided with Jupiter.  A typical high-velocity piece released
   about 5,000 hydrogen bombs' worth of energy and became a dark spot,
   larger than Earth, visibly drifting for days in Jupiter's atmosphere.
   We will see that Jupiter, with its huge gravity and tidal effects, is
   a comet killer.
   
   Spheres of Influence.  The Apollo 13 astronauts, while traveling to
   the Moon, dumped waste material overboard. As the discarded material,
   traveling at nearly the same velocity as the spacecraft, moved slowly
   away, the spacecraft's gravity pulled the material back. To everyone's
   surprise, it orbited the spacecraft all the way to the Moon.^21 When
   the spacecraft was on Earth, Earth's gravity dominated things near the
   spacecraft. However, when the spacecraft was far from Earth, the
   spacecraft's gravity dominated things near it. The region around a
   spacecraft, or any other body in space, where gravity can hold an
   object in an orbit, is called that body's sphere of influence.
   
   An object's sphere of influence expands enormously as it moves farther
   from massive bodies. If, for many days, rocks and droplets of muddy
   water were expelled from Earth in a supersonic jet, the spheres of
   influence of the rocks and water would grow dramatically. The more the
   spheres of influence grew, the more mass they would capture, so the
   more they would grow, etc.^22
   
   A droplet engulfed in a growing sphere of influence of a rock or
   another droplet with a similar velocity might be captured by it.
   However, a droplet entering a body's fixed sphere of influence with
   even a small relative velocity would seldom be captured.^23 This is
   because it would gain enough speed as it fell toward that body to
   escape from the sphere of influence at about the same speed it
   entered.
   
   Earth's sphere of influence has a radius of about 600,000 miles. A
   rock inside that sphere is influenced more by Earth's gravity than the
   Sun's. A rock entering Earth's sphere of influence at only a few feet
   per second would accelerate toward Earth. It could reach a speed of
   almost 7 miles per second, depending on how close it came to Earth.
   Assuming no collision, gravity would whip the rock partway around
   Earth so fast it would exit Earth's sphere of influence about as fast
   as it entered--a few feet per second. It would then be influenced more
   by the Sun   and would enter a new orbit about the Sun.^24
   
   Exiting a sphere of influence is more difficult if it contains a gas,
   such as an atmosphere or water vapor. Any gas, especially a dense gas,
   slows an invading particle, perhaps enough to capture it. Atmospheres
   are often relied upon to slow and capture spacecraft. This technique,
   called aerobraking, generates much heat. However, if the "spacecraft"
   is a liquid droplet, evaporation cools the droplet, makes the
   atmosphere denser, and makes capture even easier.
   
   A swarm of mutually captured particles will orbit their common center
   of mass. If the swarm were moving away from Earth, the swarm's sphere
   of influence would grow, so fewer particles would escape by chance
   interactions with other particles. Particles in the swarm, colliding
   with gas molecules, would gently settle toward the swarm's center of
   mass. How gently? More softly than large snowflakes settling onto a
   windless, snow-covered field. More softly, because the swarm's gravity
   is much weaker than Earth's gravity. Eventually, most particles in
   this swarm would become a rotating clump of fluffy ice particles with
   almost no strength. The entire clump would stick together, resembling
   a comet's nucleus in strength, size, density, spin, composition,
   texture, and orbit. The pressure in the center of a comet nucleus 3
   miles in diameter is about what you would feel under a blanket here on
   Earth.
   
   In contrast, spheres of influence hardly change for particles in
   nearly circular orbits about a planet or the Sun. Even on rare
   occasions when particles pass very near each other, capture does not
   occur. This is because they seldom collide and stick together, their
   relative velocities almost always allow them to escape each other's
   sphere of influence, their spheres of influence rarely expand, and
   gases are not inside these spheres to assist in capture. Forming
   stars, planets, or moons by capturing^25 smaller orbiting bodies is
   far more difficult than most people realize.^26
   
     * Previous Page
     * Next Page

   This site is best viewed with a screen resolution of 1024 x 768 (XGA)
   or higher and a browser that supports cascading style sheets.
   We have tested the site in Internet Explorer (Win), Netscape (Win),
   Safari (Mac), and Firefox (Mac and Win).
   Please let us know if you have any suggestions or find any problems
   with the site.
   Updated on Saturday, May 28
   Copyright © 1995-2008
   Center for Scientific Creation
   http://www.creationscience.com
   (602) 955-7663