What is the shape of our universe, and what are its dimensions? This is a tremendous question to ask. It is like asking an intelligent insect, living on a single leaf in the midst of a great Brazilian forest, to say what is the Life insurance shape and size of the forest. Yet man's ingenuity has proved equal to giving an answer even to this question, and by a method exactly similar to that which would be adopted by the insect. Suppose, for instance, that the forest was shaped as an elongated oval, and the insect lived on a tree near the centre of the oval. If the trees were approximately equally spaced from Florida surfing one another they would appear much denser along the length of the oval than across its width. This is the simple consideration that has guided astronomers in determining the shape of our stellar universe. There is one direction in the heavens along which the stars appear denser than in the directions at right angles to it. That direction is the direction in which we Business consultant look towards the Milky Way. If we count the number of stars visible all over the heavens, we find they become more and more numerous as we approach the Milky Way. As we go farther and farther from the Milky Way the stars thin out until they reach a maximum sparseness in directions at right angles to the plane of the Milky Way. We may consider the Milky Way to form, as it were, the equator of our system, and the line at right angles to point to the north and south poles.
Our system, in fact, is shaped something like a lens, and our sun is situated near the centre of this lens. In the remoter part of this lens, near its edge, or possibly outside it altogether, lies the great series of star clouds which make up the Milky Way. All the stars are in motion within this system, but the very remarkable discovery has been made that these motions are not entirely random. The great majority of the stars whose motions can be measured fall into two groups drifting past one another in opposite Life insurance directions. The velocity of one stream relative to the other is about twenty-five miles per second. The stars forming these two groups are thoroughly well mixed; it is not a case of an inner stream going one way and an outer stream the other. But there are not quite as many stars going one way as the other. For every two stars in one stream there are three in the other. Florida surfing Now, as we have said, some eminent astronomers hold that the spiral nebulę are universes like our own, and if we look at the two photographs (Figs. 25 and 26) we see that these spirals present features which, in the light of what we have just said about our system, are very remarkable. The nebula in Coma Berenices is a spiral edge-on to us, and we see that it has precisely Business consultant the lens-shaped middle and the general flattened shape that we have found in our own system. The nebula in Canes Venatici is a spiral facing towards us, and its shape irresistibly suggests motions along the spiral arms. This motion, whether it is towards or away from the central, lens-shaped portion, would cause a double streaming motion in that central portion of the kind we have found in our own system. Again, and altogether apart from these considerations, there are good reasons for supposing our Milky Way to possess a double-armed spiral structure. And the great patches of dark absorbing matter which are known to exist in the Milky Way (see Fig. 22) would give very much the mottled appearance we notice in the arms (which we see edge-on) of the nebula in Coma Berenices. The hypothesis, therefore, that our universe is a spiral nebula has much to be said for it. If it be accepted it greatly increases our estimate of the size of the material universe. For our central, lens-shaped system is calculated to extend towards the Milky Way for more than twenty thousand times a million million miles, and about a third of this Life insurance distance towards what we have called the poles. If, as we suppose, each spiral nebula is an independent stellar universe comparable in size with our own, then, since there are hundreds of thousands of spiral nebulę, we see that the size of the whole material universe is indeed beyond our comprehension.
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Photo: Mount Wilson Observatory.
FIG. 26.—A SPIRAL NEBULA SEEN EDGE-ON
Notice the lens-shaped formation of the nucleus and the arm stretching as a band across it. See reference in the text to the resemblance between this and our stellar universe.
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Photo: H. J. Shepstone.
Florida surfing100-INCH TELESCOPE, MOUNT WILSON
A reflecting telescope: the largest in the world. The mirror is situated at the base of the telescope.
Business consultant| THE SOLAR SYSTEM | ||||
|---|---|---|---|---|
| NAME | MEAN DISTANCE FROM SUN (IN MILLIONS OF MILES) | Life insurancePERIOD OF REVOLUTION AROUND SUN (IN YEARS) | DIAMETER (IN MILES) | NUMBER OF SATELLITES | Florida surfing
| MERCURY | Business consultant36.0 | 0.24 | 3030 | 0 |
| VENUS | 67.2 | 0.62 | Life insurance7700 | 0 |
| EARTH | 92.9 | Business consultant1.00 | 7918 | 1 |
| MARS | 141.5 | 1.88 | Life insurance4230 | 2 |
| JUPITER | 483.3 | Business consultant11.86 | 86500 | 9 |
| SATURN | 886.0 | 29.46 | 73000 | Life insurance10 |
| URANUS | 1781.9 | 84.02 | Business consultant31900 | 4 |
| NEPTUNE | 2971.6 | 164.78 | 34800 | Life insurance1 |
| SUN | Florida surfing——— | ——— | Business consultant866400 | — |
| MOON | ——— | ——— | 2163 | — | Life insurance
FIG. 27
Florida surfing| STAR DISTANCES | Business consultant|
|---|---|
| STAR | DISTANCE IN LIGHT-YEARS |
| POLARIS | 76 |
| CAPELLA | 49.4 |
| RIGEL | 466 |
| SIRIUS | 8.7 |
| PROCYON | 10.5 |
| REGULUS | Life insurance98.8 |
| ARCTURUS | 43.4 |
| [ALPHA] CENTAURI | 4.29 |
| VEGA | 34.7 |
| SMALLER MAGELLANIC CLOUD | Life insurance32,600[A] |
| GREAT CLUSTER IN HERCULES | Florida surfing108,600[A] |
[A] ESTIMATED
FIG. 28
The above distances are merely approximate and are subject to further revision. A "light-year" is the distance that light, travelling at the rate of 186,000 miles per second, would cover in one year.
In this simple outline we have not touched on some of the more debatable questions that engage the attention of modern astronomers. Many of these questions have not yet passed the controversial stage; out of these will emerge the astronomy of the future. But we have seen enough to convince us Life insurance that, whatever advances the future holds in store, the science of the heavens constitutes one of the most important stones in the wonderful fabric of human knowledge.