Six Fundamental Requirements Of Stellar Evolution Theories

It is difficult to even think about outer space. You and I have never lived there. So we shall consider six primary aspects of matter and stellar evolutionary theories as occurring right here on earth. In doing so, we can see the utter foolishness of each of these requirements for outerspace evolutionary theory.

1. When nothing makes itself into something. Experiment One: Go into an empty room and clean it out well. Remove all the furniture and even the dust. Seal up the windows and lock the doors and leave. Come back periodically and check to see what happens. The air inside the room should change itself into different types of matter, such as birds, chemicals, grass, etc. Or take a vacuum bottle and extract as much air and gaseous material as possible. Seal it. The contents should change into something else. Conclusion: Nothing never makes itself into anything.

2. When gas begins twirling. Experiment Two: With all the doors and windows shut, and everything inside and outside the house evenly cold, the air in the house should begin rotating and then push itself into a solid. Conclu sion: Gas left alone in a cold place will not do anything.

3. When gas gravitates into a solid. Experiment Three: Gas is supposed to push itself into solids. We will help it along, by starting with the high-pressure propane tank in your backyard. Fill it as full as possible, thus helping to push the gas together. Wait and check it periodically. The contents should change themselves into a solid. Then open the valve to see how the situation is proceeding: All the contents will rush out. Conclusion: "Nature may abhor a vacuum, " but gas abhors being pushed together!

4. When hydrogen changes itself into the heavier atoms. Experiment Four: As a rule, hydrogen in stars only changes into helium. But when a large-enough star explodes, sizeable amounts of the hydrogen are said to change into heavier elements (elements above helium). Admittedly, we cannot equal this experiment on earth, since the explosion of a large star is required. But we have evidence from outer space on this point. The A.D. 1054 explosion of a star produced the Crab nebula. Analysis of the gas from that nebula revealed few, very few heavier elements. Conclusion: Supernova explosions, which are infrequent, could not have produced the present amounts of heavier elements.

5. When stars get together. Experiment Five: There are hundreds of millions of multiple star systems, in which several stars are close to one another and mutually orbit each other. Simulate this by taking three or four circular magnets (you will find one on the back of every TV set in the junkyard). Place them close together and, by hand, have them orbit one another. They are never to come together, but only to circle one another. Scientists know that the gravitational ("magnetic-like") attraction of an average star is about 5 light-years. They also know that multiple stars are far closer to each other than 5 light-years! So, like magnets, they ought to rush together if not properly kept apart by exacting orbits. Conclusion: You cannot put magnets close together without them coming to gether, no matter how carefully you try to keep them from doing so. It is impossible for stars to randomly arrange themselves into short- or long-term orbits with anything. Try dropping one magnet past another repeatedly, and see if it will accidentally go into orbit!

6. When randomness organizes itself. Experiment Six: Go to your local junkyard and ask that it be locked up and closed off for a year. Return from time to time and watch how it cleans itself up and then arranges itself into an orderly collection of materials. Conclusion: Randomness never organizes itself. Incoherent matter in outer space could never arrange itself into orbiting stars, galaxies, and planetary systems.

0 0

Post a comment