Difference between revisions of "57:7 The Meteoric Era—The Volcanic Age-The Primitive Planetary Atmosphere"
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| − | 57:7.1 Throughout these early times the [[space]] regions of the [[solar system]] were swarming with small [[disruptive]] and [[condensation]] bodies, and in the [[absence]] of a protective [[combustion]] [[atmosphere]] such space bodies crashed directly on the [[surface]] of [[Urantia]]. These incessant impacts kept the [[surface]] of the planet more or less [[heated]], and this, [[together]] with the increased [[action]] of [[gravity]] as the [[sphere]] grew larger, began to set in operation those [[influences]] which [[gradually]] caused the heavier [[elements]], such as [ | + | 57:7.1 Throughout these early times the [[space]] regions of the [[solar system]] were swarming with small [[disruptive]] and [[condensation]] bodies, and in the [[absence]] of a protective [[combustion]] [[atmosphere]] such space bodies crashed directly on the [[surface]] of [[Urantia]]. These incessant impacts kept the [[surface]] of the planet more or less [[heated]], and this, [[together]] with the increased [[action]] of [[gravity]] as the [[sphere]] grew larger, began to set in operation those [[influences]] which [[gradually]] caused the heavier [[elements]], such as [https://en.wikipedia.org/wiki/Iron iron], to settle more and more toward the [[center]] of the [[planet]]. |
57:7.2 2,000,000,000 years ago the [[earth]] began decidedly to gain on the [[moon]]. Always had the [[planet]] been larger than its [[satellite]], but there was not so much [[difference]] in size until about this time, when enormous space bodies were captured by the [[earth]]. [[Urantia]] was then about one fifth its present size and had become large enough to hold the [[primitive]] [[atmosphere]] which had begun to appear as a result of the internal elemental [[Competition|contest]] between the heated interior and the cooling crust. | 57:7.2 2,000,000,000 years ago the [[earth]] began decidedly to gain on the [[moon]]. Always had the [[planet]] been larger than its [[satellite]], but there was not so much [[difference]] in size until about this time, when enormous space bodies were captured by the [[earth]]. [[Urantia]] was then about one fifth its present size and had become large enough to hold the [[primitive]] [[atmosphere]] which had begun to appear as a result of the internal elemental [[Competition|contest]] between the heated interior and the cooling crust. | ||
| − | 57:7.3 Definite [ | + | 57:7.3 Definite [https://en.wikipedia.org/wiki/Volcano volcanic] [[action]] dates from these times. The internal [[heat]] of the [[earth]] continued to be augmented by the deeper and deeper burial of the [https://en.wikipedia.org/wiki/Radioactive_decay radioactive] or heavier [[elements]] brought in from [[space]] by the [[meteors]]. The [[study]] of these [https://en.wikipedia.org/wiki/Radioactive_decay radioactive] [[elements]] will [[reveal]] that [[Urantia]] is more than one billion years old on its [[surface]].[https://nordan.daynal.org/wiki/index.php?title=Geologic_timescale] The [https://www.lateralscience.co.uk/radium/strutt.html radium clock (?)] is your most reliable timepiece for making [[scientific]] estimates of the age of the [[planet]], but all such estimates are too short because the [https://en.wikipedia.org/wiki/Radioactive_decay radioactive] [[materials]] open to your scrutiny are all derived from the [[earth]]'s [[surface]] and hence [[represent]] [[Urantia]]'s comparatively recent acquirements of these [[elements]]. |
57:7.4 1,500,000,000 years ago the [[earth]] was two thirds its present size, while the [[moon]] was nearing its present [[mass]]. [[Earth]]'s rapid gain over the [[moon]] in size enabled it to begin the slow robbery of the little [[atmosphere]] which its [[satellite]] originally had. | 57:7.4 1,500,000,000 years ago the [[earth]] was two thirds its present size, while the [[moon]] was nearing its present [[mass]]. [[Earth]]'s rapid gain over the [[moon]] in size enabled it to begin the slow robbery of the little [[atmosphere]] which its [[satellite]] originally had. | ||
| − | 57:7.5 [ | + | 57:7.5 [https://en.wikipedia.org/wiki/Volcano Volcanic] [[action]] is now at its height. The whole [[earth]] is a veritable fiery inferno, the [[surface]] resembling its earlier molten state before the heavier metals gravitated toward the [[center]]. This is the volcanic age. Nevertheless, a crust, consisting chiefly of the comparatively lighter [https://en.wikipedia.org/wiki/Granite granite], is [[gradually]] [[forming]]. The [[stage]] is being set for a [[planet]] which can someday [[support]] life. |
| − | 57:7.6 The [[primitive]] [[planetary]] [[atmosphere]] is slowly evolving, now containing some [[water]] vapor, [ | + | 57:7.6 The [[primitive]] [[planetary]] [[atmosphere]] is slowly evolving, now containing some [[water]] vapor, [https://en.wikipedia.org/wiki/Carbon_monoxide carbon monoxide], [https://en.wikipedia.org/wiki/Carbon_dioxide carbon dioxide], and [https://en.wikipedia.org/wiki/Hydrogen_chloride hydrogen chloride], but there is little or no free [https://en.wikipedia.org/wiki/Nitrogen nitrogen] or free [https://en.wikipedia.org/wiki/Oxygen oxygen]. The [[atmosphere]] of a world in the volcanic age presents a queer [[spectacle]]. In addition to the [[gases]] enumerated it is heavily charged with numerous volcanic gases and, as the [[air]] belt matures, with the [[combustion]] products of the heavy [[meteoric]] showers which are constantly hurtling in upon the [[planetary]] [[surface]]. Such [[meteoric]] combustion keeps the [[atmospheric]] [https://en.wikipedia.org/wiki/Oxygen oxygen] very nearly exhausted, and the [[rate]] of meteoric bombardment is still tremendous. |
| − | 57:7.7 Presently, the [[atmosphere]] became more settled and cooled sufficiently to start [[precipitation]] of rain on the hot rocky [[surface]] of the [[planet]]. For thousands of years [[Urantia]] was enveloped in one vast and continuous blanket of [ | + | 57:7.7 Presently, the [[atmosphere]] became more settled and cooled sufficiently to start [[precipitation]] of rain on the hot rocky [[surface]] of the [[planet]]. For thousands of years [[Urantia]] was enveloped in one vast and continuous blanket of [https://en.wikipedia.org/wiki/Steam steam]. And during these ages the [[sun]] never shone upon the [[earth]]'s [[surface]]. |
| − | 57:7.8 Much of the [ | + | 57:7.8 Much of the [https://en.wikipedia.org/wiki/Carbon carbon] of the [[atmosphere]] was abstracted to form the carbonates of the various metals which abounded in the superficial layers of the [[planet]]. Later on, much greater [[quantities]] of these carbon [[gases]] were consumed by the early and prolific [[plant]] life. |
| − | 57:7.9 Even in the later periods the continuing [ | + | 57:7.9 Even in the later periods the continuing [https://en.wikipedia.org/wiki/Lava lava] [[flows]] and the incoming [[meteors]] kept the [https://en.wikipedia.org/wiki/Oxygen oxygen] of the [[air]] almost completely used up. Even the early deposits of the soon appearing [[primitive]] [[ocean]] contain no colored stones or [https://en.wikipedia.org/wiki/Shale shales]. And for a long time after this [[ocean]] appeared, there was [[virtually]] no free oxygen in the [[atmosphere]]; and it did not appear in significant [[quantities]] until it was later generated by the [https://en.wikipedia.org/wiki/Seaweed seaweeds] and other forms of vegetable life. |
| − | 57:7.10 The [[primitive]] [[planetary]] [[atmosphere]] of the [ | + | 57:7.10 The [[primitive]] [[planetary]] [[atmosphere]] of the [https://en.wikipedia.org/wiki/Volcano volcanic] age affords little [[protection]] against the collisional impacts of the [[meteoric]] swarms. Millions upon millions of [[meteors]] are able to penetrate such an [[air]] belt to smash against the [[planetary]] crust as solid bodies. But as [[time]] passes, fewer and fewer prove large enough to [[resist]] the ever-stronger [[friction]] shield of the [https://en.wikipedia.org/wiki/Oxygen oxygen]-enriching [[atmosphere]] of the later eras. |
| − | <center>[ | + | <center>[https://nordan.daynal.org/wiki/index.php?title=Paper_57 Go to Paper 57]</center> |
| − | <center>[ | + | <center>[https://nordan.daynal.org/wiki/index.php?title=The_Urantia_Text_-_Contents Go to Table of Contents]</center> |
[[Category:Paper 57 - The Origin of Urantia]] | [[Category:Paper 57 - The Origin of Urantia]] | ||
Latest revision as of 23:37, 12 December 2020
57:7.1 Throughout these early times the space regions of the solar system were swarming with small disruptive and condensation bodies, and in the absence of a protective combustion atmosphere such space bodies crashed directly on the surface of Urantia. These incessant impacts kept the surface of the planet more or less heated, and this, together with the increased action of gravity as the sphere grew larger, began to set in operation those influences which gradually caused the heavier elements, such as iron, to settle more and more toward the center of the planet.
57:7.2 2,000,000,000 years ago the earth began decidedly to gain on the moon. Always had the planet been larger than its satellite, but there was not so much difference in size until about this time, when enormous space bodies were captured by the earth. Urantia was then about one fifth its present size and had become large enough to hold the primitive atmosphere which had begun to appear as a result of the internal elemental contest between the heated interior and the cooling crust.
57:7.3 Definite volcanic action dates from these times. The internal heat of the earth continued to be augmented by the deeper and deeper burial of the radioactive or heavier elements brought in from space by the meteors. The study of these radioactive elements will reveal that Urantia is more than one billion years old on its surface.[1] The radium clock (?) is your most reliable timepiece for making scientific estimates of the age of the planet, but all such estimates are too short because the radioactive materials open to your scrutiny are all derived from the earth's surface and hence represent Urantia's comparatively recent acquirements of these elements.
57:7.4 1,500,000,000 years ago the earth was two thirds its present size, while the moon was nearing its present mass. Earth's rapid gain over the moon in size enabled it to begin the slow robbery of the little atmosphere which its satellite originally had.
57:7.5 Volcanic action is now at its height. The whole earth is a veritable fiery inferno, the surface resembling its earlier molten state before the heavier metals gravitated toward the center. This is the volcanic age. Nevertheless, a crust, consisting chiefly of the comparatively lighter granite, is gradually forming. The stage is being set for a planet which can someday support life.
57:7.6 The primitive planetary atmosphere is slowly evolving, now containing some water vapor, carbon monoxide, carbon dioxide, and hydrogen chloride, but there is little or no free nitrogen or free oxygen. The atmosphere of a world in the volcanic age presents a queer spectacle. In addition to the gases enumerated it is heavily charged with numerous volcanic gases and, as the air belt matures, with the combustion products of the heavy meteoric showers which are constantly hurtling in upon the planetary surface. Such meteoric combustion keeps the atmospheric oxygen very nearly exhausted, and the rate of meteoric bombardment is still tremendous.
57:7.7 Presently, the atmosphere became more settled and cooled sufficiently to start precipitation of rain on the hot rocky surface of the planet. For thousands of years Urantia was enveloped in one vast and continuous blanket of steam. And during these ages the sun never shone upon the earth's surface.
57:7.8 Much of the carbon of the atmosphere was abstracted to form the carbonates of the various metals which abounded in the superficial layers of the planet. Later on, much greater quantities of these carbon gases were consumed by the early and prolific plant life.
57:7.9 Even in the later periods the continuing lava flows and the incoming meteors kept the oxygen of the air almost completely used up. Even the early deposits of the soon appearing primitive ocean contain no colored stones or shales. And for a long time after this ocean appeared, there was virtually no free oxygen in the atmosphere; and it did not appear in significant quantities until it was later generated by the seaweeds and other forms of vegetable life.
57:7.10 The primitive planetary atmosphere of the volcanic age affords little protection against the collisional impacts of the meteoric swarms. Millions upon millions of meteors are able to penetrate such an air belt to smash against the planetary crust as solid bodies. But as time passes, fewer and fewer prove large enough to resist the ever-stronger friction shield of the oxygen-enriching atmosphere of the later eras.
