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15:5.1 The bulk of the [[mass]] contained in the suns and [[planets]] of a [[superuniverse]] originates in the nebular wheels; very little of superuniverse mass is organized by the direct [[action]] of the [http://nordan.daynal.org/wiki/index.php?title=Paper_29 power directors] (as in the construction of [http://nordan.daynal.org/wiki/index.php?title=Paper_15#15:7._THE_ARCHITECTURAL_SPHERES architectural spheres]), although a constantly varying [[quantity]] of [[matter]] originates in open space.

15:5.1 The bulk of the [[mass]] contained in the suns and [[planets]] of a [[superuniverse]] originates in the nebular wheels; very little of superuniverse mass is organized by the direct [[action]] of the [https://nordan.daynal.org/wiki/index.php?title=Paper_29 power directors] (as in the construction of [https://nordan.daynal.org/wiki/index.php?title=Paper_15#15:7._THE_ARCHITECTURAL_SPHERES architectural spheres]), although a constantly varying [[quantity]] of [[matter]] originates in open space.

15:5.2 As to [[origin]], the majority of the suns, planets, and other [[spheres]] can be classified in one of the following ten groups:

15:5.2 As to [[origin]], the majority of the suns, planets, and other [[spheres]] can be classified in one of the following ten groups:

*1. 15:5.3 1. ''Concentric Contraction Rings''. Not all nebulae are spiral. Many an immense nebula, instead of splitting into a [http://www.wikipedia.org/wiki/Double_Star double star] system or evolving as a spiral, undergoes condensation by multiple-ring formation. For long periods such a nebula appears as an enormous central sun surrounded by numerous gigantic clouds of encircling, ring-appearing formations of matter.

*1. 15:5.3 1. ''Concentric Contraction Rings''. Not all nebulae are spiral. Many an immense nebula, instead of splitting into a [https://www.wikipedia.org/wiki/Double_Star double star] system or evolving as a spiral, undergoes condensation by multiple-ring formation. For long periods such a nebula appears as an enormous central sun surrounded by numerous gigantic clouds of encircling, ring-appearing formations of matter.

*2. 15:5.4 2. ''The Whirled Stars'' [[embrace]] those suns which are thrown off the great mother wheels of highly heated gases. They are not thrown off as rings but in right- and left-handed [[processions]]. Whirled stars are also of origin in other-than-spiral nebulae.

*2. 15:5.4 2. ''The Whirled Stars'' [[embrace]] those suns which are thrown off the great mother wheels of highly heated gases. They are not thrown off as rings but in right- and left-handed [[processions]]. Whirled stars are also of origin in other-than-spiral nebulae.

*3. 15:5.5 3. ''Gravity-explosion Planets''. When a sun is born of a spiral or of a [http://www.wikipedia.org/wiki/Barred_Nebula barred nebula], not infrequently it is thrown out a considerable distance. Such a sun is highly gaseous, and subsequently, after it has somewhat cooled and condensed, it may [[chance]] to swing near some enormous mass of matter, a gigantic sun or a dark island of space. Such an approach may not be near enough to result in collision but still near enough to allow the [[gravity]] pull of the greater body to start tidal convulsions in the lesser, thus initiating a series of tidal upheavals which occur [[simultaneously]] on opposite sides of the convulsed sun. At their height these explosive eruptions produce a series of varying-sized aggregations of matter which may be projected beyond the gravity-reclamation zone of the erupting sun, thus becoming [[stabilized]] in orbits of their own around one of the two bodies concerned in this [[episode]]. Later on the larger collections of matter unite and gradually [http://en.wikipedia.org/wiki/Accretion_disc draw the smaller bodies to themselves]. In this way many of the solid [[planets]] of the lesser systems are brought into [[existence]]. Your [http://www.classzone.com/books/earth_science/terc/content/visualizations/es0401/es0401page01.cfm own solar system] had just such an [[origin]].

*3. 15:5.5 3. ''Gravity-explosion Planets''. When a sun is born of a spiral or of a [https://www.wikipedia.org/wiki/Barred_Nebula barred nebula], not infrequently it is thrown out a considerable distance. Such a sun is highly gaseous, and subsequently, after it has somewhat cooled and condensed, it may [[chance]] to swing near some enormous mass of matter, a gigantic sun or a dark island of space. Such an approach may not be near enough to result in collision but still near enough to allow the [[gravity]] pull of the greater body to start tidal convulsions in the lesser, thus initiating a series of tidal upheavals which occur [[simultaneously]] on opposite sides of the convulsed sun. At their height these explosive eruptions produce a series of varying-sized aggregations of matter which may be projected beyond the gravity-reclamation zone of the erupting sun, thus becoming [[stabilized]] in orbits of their own around one of the two bodies concerned in this [[episode]]. Later on the larger collections of matter unite and gradually [https://en.wikipedia.org/wiki/Accretion_disc draw the smaller bodies to themselves]. In this way many of the solid [[planets]] of the lesser systems are brought into [[existence]]. Your [https://www.classzone.com/books/earth_science/terc/content/visualizations/es0401/es0401page01.cfm own solar system] had just such an [[origin]].

*4. 15:5.6 4. ''Centrifugal Planetary Daughters''. Enormous suns, when in certain stages of [[development]], and if their revolutionary rate greatly accelerates, begin to throw off large quantities of matter which may subsequently be assembled to form small worlds that continue to encircle the parent sun.

*4. 15:5.6 4. ''Centrifugal Planetary Daughters''. Enormous suns, when in certain stages of [[development]], and if their revolutionary rate greatly accelerates, begin to throw off large quantities of matter which may subsequently be assembled to form small worlds that continue to encircle the parent sun.

*5. 15:5.7 5. ''Gravity-deficiency Spheres''. There is a critical limit to the size of individual stars. When a sun reaches this limit, unless it slows down in revolutionary rate, it is doomed to split; sun [http://www.wikipedia.org/wiki/Nuclear_fission fission] occurs, and a new [http://www.wikipedia.org/wiki/Double_Star double star] of this variety is born. Numerous small planets may be subsequently formed as a by-product of this gigantic disruption.

*5. 15:5.7 5. ''Gravity-deficiency Spheres''. There is a critical limit to the size of individual stars. When a sun reaches this limit, unless it slows down in revolutionary rate, it is doomed to split; sun [https://www.wikipedia.org/wiki/Nuclear_fission fission] occurs, and a new [https://www.wikipedia.org/wiki/Double_Star double star] of this variety is born. Numerous small planets may be subsequently formed as a by-product of this gigantic disruption.

*6. 15:5.8 6. ''Contractural Stars''. In the smaller systems the largest outer planet sometimes draws to itself its neighboring worlds, while those planets near the sun begin their terminal plunge. With your solar system, such an end would mean that the four inner planets would be claimed by the sun, while the major planet, [http://www.wikipedia.org/wiki/Jupiter Jupiter], would be greatly enlarged by capturing the remaining worlds. Such an end of a [[solar system]] would result in the production of two adjacent but unequal suns, one type of [[http://www.wikipedia.org/wiki/Double_Star double star] formation. Such [[catastrophes]] are infrequent except out on the fringe of the superuniverse starry aggregations.

*6. 15:5.8 6. ''Contractural Stars''. In the smaller systems the largest outer planet sometimes draws to itself its neighboring worlds, while those planets near the sun begin their terminal plunge. With your solar system, such an end would mean that the four inner planets would be claimed by the sun, while the major planet, [https://www.wikipedia.org/wiki/Jupiter Jupiter], would be greatly enlarged by capturing the remaining worlds. Such an end of a [[solar system]] would result in the production of two adjacent but unequal suns, one type of [[https://www.wikipedia.org/wiki/Double_Star double star] formation. Such [[catastrophes]] are infrequent except out on the fringe of the superuniverse starry aggregations.

*7. 15:5.9 7. ''Cumulative Spheres''. From the vast [[quantity]] of matter circulating in [[space]], small planets may slowly accumulate. They grow by [http://www.google.com/url?sa=t&source=web&ct=res&cd=1&ved=0CAoQFjAA&url=http%3A%2F%2Fwww.nature.com%2Fnature%2Fjournal%2Fv132%2Fn3346%2Fabs%2F132934b0.html&ei=G1h8S_jRAsuVtgeL__W6BQ&usg=AFQjCNHQOPRp5K3Mmq0d4I-OmM1pSbHWvQ&sig2=uaNqQ_9r_Xp8ZjnZ1u_OHw meteoric accretion] and by minor collisions. In certain sectors of space, conditions favor such forms of [[planetary]] [[birth]]. Many an [http://nordan.daynal.org/wiki/index.php?title=Paper_49 inhabited world] has had such an [http://nordan.daynal.org/wiki/index.php?title=Paper_41#41:10._ORIGIN_OF_INHABITED_WORLDS origin].

*7. 15:5.9 7. ''Cumulative Spheres''. From the vast [[quantity]] of matter circulating in [[space]], small planets may slowly accumulate. They grow by [https://www.google.com/url?sa=t&source=web&ct=res&cd=1&ved=0CAoQFjAA&url=http%3A%2F%2Fwww.nature.com%2Fnature%2Fjournal%2Fv132%2Fn3346%2Fabs%2F132934b0.html&ei=G1h8S_jRAsuVtgeL__W6BQ&usg=AFQjCNHQOPRp5K3Mmq0d4I-OmM1pSbHWvQ&sig2=uaNqQ_9r_Xp8ZjnZ1u_OHw meteoric accretion] and by minor collisions. In certain sectors of space, conditions favor such forms of [[planetary]] [[birth]]. Many an [https://nordan.daynal.org/wiki/index.php?title=Paper_49 inhabited world] has had such an [https://nordan.daynal.org/wiki/index.php?title=Paper_41#41:10._ORIGIN_OF_INHABITED_WORLDS origin].

15:5.10 Some of the dense dark islands are the direct result of the [[accretion]]s of transmuting [[energy]] in space. Another [[group]] of these dark islands have come into being by the accumulation of enormous quantities of [http://en.wikipedia.org/wiki/Cold_dark_matter cold matter], mere fragments and meteors, circulating through space. Such aggregations of matter have never been hot and, except for [[density]], are in composition very similar to [[Urantia]].

15:5.10 Some of the dense dark islands are the direct result of the [[accretion]]s of transmuting [[energy]] in space. Another [[group]] of these dark islands have come into being by the accumulation of enormous quantities of [https://en.wikipedia.org/wiki/Cold_dark_matter cold matter], mere fragments and meteors, circulating through space. Such aggregations of matter have never been hot and, except for [[density]], are in composition very similar to [[Urantia]].

*8. 15:5.11 8. ''Burned-out Suns''. Some of the dark islands of space are burned-out isolated suns, all available [http://nordan.daynal.org/wiki/index.php?title=Paper_42#5._WAVE-ENERGY_MANIFESTATIONS space-energy] having been emitted. The organized units of matter approximate full condensation, virtual complete consolidation; and it requires ages upon ages for such enormous masses of highly [http://en.wikipedia.org/wiki/Condensed_matter_physics condensed matter] to be recharged in the [[circuits]] of space and thus to be prepared for new [[cycles]] of universe [[function]] following a collision or some equally revivifying [[cosmic]] [[Event|happening]].

*8. 15:5.11 8. ''Burned-out Suns''. Some of the dark islands of space are burned-out isolated suns, all available [https://nordan.daynal.org/wiki/index.php?title=Paper_42#5._WAVE-ENERGY_MANIFESTATIONS space-energy] having been emitted. The organized units of matter approximate full condensation, virtual complete consolidation; and it requires ages upon ages for such enormous masses of highly [https://en.wikipedia.org/wiki/Condensed_matter_physics condensed matter] to be recharged in the [[circuits]] of space and thus to be prepared for new [[cycles]] of universe [[function]] following a collision or some equally revivifying [[cosmic]] [[Event|happening]].

*9. 15:5.12 9. ''Collisional Spheres''. In those regions of thicker clustering, collisions are not uncommon. Such an astronomic readjustment is accompanied by tremendous [[energy]] [[change]]s and [[matter]] [[transmutation]]s. Collisions involving dead suns are peculiarly [[influential]] in creating widespread energy fluctuations. Collisional debris often constitutes the material [[nucleus]]es for the subsequent formation of planetary bodies adapted to [[mortal]] [http://nordan.daynal.org/wiki/index.php?title=Paper_49 habitation].

*9. 15:5.12 9. ''Collisional Spheres''. In those regions of thicker clustering, collisions are not uncommon. Such an astronomic readjustment is accompanied by tremendous [[energy]] [[change]]s and [[matter]] [[transmutation]]s. Collisions involving dead suns are peculiarly [[influential]] in creating widespread energy fluctuations. Collisional debris often constitutes the material [[nucleus]]es for the subsequent formation of planetary bodies adapted to [[mortal]] [https://nordan.daynal.org/wiki/index.php?title=Paper_49 habitation].

*10. 15:5.13 10. ''Architectural Worlds''. These are the worlds which are built according to plans and specifications for some special [[purpose]], such as [[Salvington]], the headquarters of your [[local universe]], and [[Uversa]], the seat of [[government]] of our [[superuniverse]].

*10. 15:5.13 10. ''Architectural Worlds''. These are the worlds which are built according to plans and specifications for some special [[purpose]], such as [[Salvington]], the headquarters of your [[local universe]], and [[Uversa]], the seat of [[government]] of our [[superuniverse]].

15:5.14 There are numerous other [[techniques]] for evolving suns and segregating planets, but the foregoing procedures suggest the [[methods]] whereby the vast majority of [[Solar System|stellar systems]] and planetary families are brought into [[existence]]. To undertake to describe all the various techniques involved in stellar [[metamorphosis]] and planetary evolution would require the [[narration]] of almost one hundred different modes of sun formation and planetary origin. As your star students scan the [[heavens]], they will observe [[phenomena]] indicative of all these modes of stellar evolution, but they will seldom detect [[evidence]] of the formation of those small, [http://en.wikipedia.org/wiki/Extra-solar_planets nonluminous collections] of matter which serve as [http://nordan.daynal.org/wiki/index.php?title=Paper_49 inhabited planets], the most important of the vast material creations.

15:5.14 There are numerous other [[techniques]] for evolving suns and segregating planets, but the foregoing procedures suggest the [[methods]] whereby the vast majority of [[Solar System|stellar systems]] and planetary families are brought into [[existence]]. To undertake to describe all the various techniques involved in stellar [[metamorphosis]] and planetary evolution would require the [[narration]] of almost one hundred different modes of sun formation and planetary origin. As your star students scan the [[heavens]], they will observe [[phenomena]] indicative of all these modes of stellar evolution, but they will seldom detect [[evidence]] of the formation of those small, [https://en.wikipedia.org/wiki/Extra-solar_planets nonluminous collections] of matter which serve as [https://nordan.daynal.org/wiki/index.php?title=Paper_49 inhabited planets], the most important of the vast material creations.

<center>[http://nordan.daynal.org/wiki/index.php?title=Paper_15 Go to Paper 15]</center>

<center>[https://nordan.daynal.org/wiki/index.php?title=Paper_15 Go to Paper 15]</center>

<center>[http://nordan.daynal.org/wiki/index.php?title=The_Urantia_Text_-_Contents Go to Table of Contents]</center>

<center>[https://nordan.daynal.org/wiki/index.php?title=The_Urantia_Text_-_Contents Go to Table of Contents]</center>

[[Category:Paper 15 - The Seven Superuniverses]]

[[Category:Paper 15 - The Seven Superuniverses]]

[[Category: Astronomy/TeaM]]

[[Category: Astronomy/TeaM]]

[[Category: Physics/TeaM]]

[[Category: Physics/TeaM]]