The Truth About TidesThe same force that produces violent volcanism on Jupiter's moon Io causes the Earth's oceans to rise and fall. This tidal force is the product of the gravitational influence which one body imposes on another.
The influence of the Moon's gravity upon the Earth is the primary source of our ocean tides. Newton had found that the attractive force of an object is inversely proportional to the square of the distance between the objects. This is known as the inverse square law. The first to apply this law to the question of tides was the Marquis de Leplace (1749-1827).
Just as the attractive force imposed on a series of ball bearings radiating from a large and powerful magnet would decrease as distance increased, so too different points along a line from the Moon, passing straight through the Earth, would incur a decreasing attraction with distance. This means that some parts of the Earth are being pulled harder than others. The result is a pulling of the Earth "out of round" as it spins through that imaginary line of gravitational force radiating from the Moon.
Laplace realized that the effect of lunar gravity on the side of the Earth facing the Moon had to be greater than its effect on the center of the Earth (which is a greater distance from the Moon), and weakest of all on the side facing away from the Moon.
Thus our poor little planet is being continuously deformed and we experience two simultaneous high tides, one on the lunar-facing side as a result of the Earth swelling toward the Moon; and one on the opposite side as the Earth's crust, now closer to the Moon than the ocean above it, is drawn to the Moon while the waters above are allowed to bulge away. Two low tides are naturally experienced at the points 90° to each point of high tide.
The Lunar SurfaceTo best visualize the terrain, imagine that you are beginning a journey to the Moon. Even from an Earthbound vantage point the maria and terrae would be easily discernible. They are the contrasting areas which create the man-in-the-moon effect. Maria are the younger of the two features, and consist of low-lying plains of volcanic basalt partially filling older impact basins. They reflect somewhat less than the 7% lunar average of sunlight received, a characteristic known as albedo, and so appear darker than surrounding features. Terrae, also known as highlands, are elevated, often mountainous and heavily cratered regions covering about 84% of the Moon's surface.
As you get closer you begin to see more detail. Major impact craters, over 30,000 on the near side alone, gradually come into view. These range in size anywhere from a few hundred feet to over 200 miles across. Patterns of rays emanating from the great Tycho and Copernicus craters are actually streaks of ejecta sent flying by the force of powerful impacts.
Soon mountain ranges, formed not by the collisions of lithospheric plates as on Earth, but by the tremendous thrusting forces of giant meteor impacts, become visible around some of the maria. The Apennines, a 600 km range with peaks as high as 5,000 meters forming the eastern rim of Mare Imbrium, are now clearly visible.
Eventually, vein-like wrinkle-ridges and raised domes, convex features which are formed as the surface gives way to internal pressures, can be seen in and around the maria. Faults which resemble long, winding trenches known as rilles, or clefts, also scar the surface.
Billions of years of meteoritic bombardment have left the Moon with a fine, granular soil called the regolith. The crew of Apollo XV described it as being "like soft, powder snow". Analyses of lunar rocks reveals no water bound into their molecular structure.
The Moon's far side is more vulnerable to meteor, asteroid, and comet impacts because it doesn't have the Earth on its side; literally. An object heading in a straight line for the center of the Moon's near side would have to get through the Earth first. Much like a seaside village facing a hurricane, the far hemisphere of the Moon catches more grief than its partially protected side. It is therefore more rugged and cratered, with virtually none of the contrasting maria so abundant on the Earth-facing side.
The Phases of the MoonThe ratio of illuminated to non-illuminated portions of the lunar disk, as seen from Earth at any time during its monthly cycle, is known as its phase. Naturally, half of the Moon's surface is always illuminated by the Sun (except during a lunar eclipse); the change of appearance occurs because the Moon, the Sun, and the Earth are constantly changing position relative to one another.
Once a month the Earth is sandwiched between the Sun and the Moon. With the light source, observation platform, and object of interest lined up this way, we see the entire illuminated portion of the lunar disk - a full moon. Halfway through the month the Moon has reached a point in its orbit around the Earth where it is now sandwiched between the Earth and Sun. The illuminated portion of the Moon's surface is now facing away from the Earth, and we see a new moon.
EclipseWhen one body passes into the shadow of another body, an eclipse occurs. An eclipse may be partial, if the interloper sweeps only a portion of the eclipsed body; or total, if the disk of the interloper crosses squarely in front of the eclipsed body, masking its entire face.
When the Earth is between the Sun and Moon, and in such perfect alignment that it casts its shadow across the Moon, a lunar eclipse is in progress. To put it another way, when the Moon just happens to get in the path of the Earth's umbra, or projected cone of shadow, it will be eclipsed.
The Moon often appears reddish during a lunar eclipse. A small amount of light filters through the Earth's atmosphere, losing its blue hues for its trouble. Variations in shading are created as scattered cloud layers absorb some of the light.
When the Moon is between the Sun and the Earth and casts its shadow on the Earth, a solar eclipse takes place. Due to an uncanny coincidence, the Moon and Sun appear in our sky to be exactly the same size. Sure, the Moon is 400 times smaller than the Sun, but it also just happens to be exactly 400 times closer. Strange, but true. Thus it is possible for the lunar disk to precisely cover the Sun when the alignment is just right.
During a solar eclipse the retreating solar crescent and eerie, other-worldly shadows are followed by a rare opportunity to observe phenomena such as Baily Grains, beads of light that peek through the lunar mountain gaps just before the moment of totality. While total, the Sun's chromosphere and outer corona, obscured at all other times by the intensity of its own light, are visible for a few minutes.
Wait a minute. This all sounds a lot like the Moon phase story. What gives?
Although the Sun, Earth, and Moon would appear to be perfectly aligned during an average full moon if viewed from above, an edge-on view would reveal that the orbital planes of each body are a little different. They line up horizontally, you might say, but not vertically. All three bodies must be passing through the ecliptic plane at the same time in order to achieve eclipse, and that is predictably rare.
