Space-Time Jitter Drive and Classical Temperature Augmented Christmas Tree Space Sails. Volume 11 |
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Author:
| Essig, James |
Series title: | Space-Time Jitter Drive and Classical Temperature Augmented Christmas Tree Space Sails Ser. |
ISBN: | 978-1-5084-8114-0 |
Publication Date: | Feb 2015 |
Publisher: | CreateSpace Independent Publishing Platform
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Book Format: | Paperback |
List Price: | USD $55.00 |
Book Description:
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This new series of books includes formulaic augmentations to the concepts addressed in Volumes 1 thru 93 of the series Christmas Tree Space Sails, Volumes 1 thru 23 of Superchromatic Beam Augmented Christmas Tree Space Sails, Volumes 1 thru 22 of Space-Time Real Energy Christmas Tree Space Sails, and Volumes 1 thru 22 Classical Temperature Drive Augmented Christmas Tree Space Sails.I have decided to present the concepts disclosed regarding the Christmas Tree Sails methods in bits and...
More DescriptionThis new series of books includes formulaic augmentations to the concepts addressed in Volumes 1 thru 93 of the series Christmas Tree Space Sails, Volumes 1 thru 23 of Superchromatic Beam Augmented Christmas Tree Space Sails, Volumes 1 thru 22 of Space-Time Real Energy Christmas Tree Space Sails, and Volumes 1 thru 22 Classical Temperature Drive Augmented Christmas Tree Space Sails.I have decided to present the concepts disclosed regarding the Christmas Tree Sails methods in bits and pieces and in several series of volumes due to the controversial nature of the exotic hybrid propulsion methods formulated in this new series and the precursor related series of books. I feel that even though the purchase price of the books will be higher for those wishing to reference the entire sequence of ideas presented herein, many readers will prefer the gradual introduction of the concepts disclosed amidst the abstract nature of the formulation presented herein.More specifically, the new material includes formulaic modifications to denote the possibility that random motion of the space-time units in the constituents of Christmas Tree Sails can be collated into forward jumps of the entire spacecraft in manners for which the spacecraft undergoes an according step-wise jump in position and thus in effective propulsion power.Space-time jitter temperature as an at least lexicographically plausible means to enhance a spacecraft effective power output.Space-time jitter is a theoretical quantum field theory construct for which the uncertainty in space-time at or near the Planck spatial and temporal scales results in an undulation and random roiling of space-time. Some modern theories of quantum gravity hold that the roiling, although theoretically present, is smoothed out more than in the case of the older quantum field theories.However, no quantum gravitational theories have ever been validated empirically so perhaps a case can be made that some unexpected modification to older versions can lead to a correct mindset but still preserve space-time roiling.Additional material present in the previous series of related books includes formulaic modifications to denote the possibility that random thermal motion of the particulate constituents of Christmas Tree Sails can be collated into forward jumps of the entire spacecraft in manners for which the spacecraft undergoes an according step-wise jump in position and thus in effective propulsion power.Such a spacecraft may be heated or cooled to enable the effect.Alternatively, a portion of the spacecraft may be heated to extreme temperatures for which the very hot portion undergoes a thermal jump to thus tow and/or push the remainder of the spacecraft forward. For cases where the heated portion is close in temperature to the that associated with nuclear reactions, relativistic scale velocity increases are plausible.The temperature of the heated portion of the spacecraft is theoretically limited to only the Planck Temperature thus enabling ultra-relativistic space-craft effective velocity and associated propulsive power jumps even in cases where the super-heated portion is a very small fraction of the spacecraft.