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If what she said was to be taken literally it would suggests that in this reality not only do electrons have distinct bodies that orbit a nucleus, but also that atomic structure was known before the correct planetary one.
 
If what she said was to be taken literally it would suggests that in this reality not only do electrons have distinct bodies that orbit a nucleus, but also that atomic structure was known before the correct planetary one.
  
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In reality, the description of probabilistic orbitals is applied to the electrons in an atom; quantum uncertainty effects are not large enough to notice at the planetary scale{{Citation needed}}. However, such a concept has been prominently featured in the video game ''{{w|Outer Wilds}}'', with its Quantum Moon. {{w|Immanuel Velikovsky}} proposed that our solar system's planets could jump between orbits suddenly, quantum-mechanically, in the same way that electrons do around atomic nuclei. This proposal was not well received in academia.  Real astronomers do talk about probability distributions of orbiting bodies, especially in the context of collision calculations, but it's not because the position of a satellite or asteroid is in a quantum superposition of states; rather, it is our less than infinite accuracy of measurement and knowledge of those orbits, plus their evolution under the influence of less-predictable effects like space weather or other still unidentified additional factors, that makes long-term estimates progressively more uncertain.
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In reality, the description of probabilistic orbitals is applied to the electrons in an atom; quantum uncertainty effects are not large enough to notice at the planetary scale{{Citation needed}}. However, such a concept has been prominently featured in the video game ''{{w|Outer Wilds}}'', with its Quantum Moon. {{w|Immanuel Velikovsky}} proposed that our solar system's planets could jump between orbits suddenly, quantum-mechanically, in the same way that electrons do around atomic nuclei. This proposal was not well received in academia.  Real astronomers do talk about probability distributions of orbiting bodies, especially in the context of collision calculations, but it's not because the position of a satellite or asteroid is in a quantum superposition of states; rather, it is our measurement and knowledge of those orbits and their evolution under the influence of less-predictable effects like space weather that is uncertain.
  
 
The title text is Miss Lenhart trying to use the first joke to set up another that builds on the first. She says that the consequence of planets having probabilistic locations would mean that they would spend some time in the lower-probability locations closer to or further from the Sun. The Earth's real orbit is in a so called {{w|Circumstellar habitable zone|habitable zone}} where the temperature allows liquid water and thus allows  life as we know it to exist. A probabilistic Earth would spend most of its time in the habitable zone, which is why life exists, but then, in short periods when it is outside the zone, some life would die. The title text claims this is why life on Earth is mortal, thus indirectly implying that life only dies in the periods where Earth leaves the habitable zone, and that life staying in the habitable zone would be immortal.
 
The title text is Miss Lenhart trying to use the first joke to set up another that builds on the first. She says that the consequence of planets having probabilistic locations would mean that they would spend some time in the lower-probability locations closer to or further from the Sun. The Earth's real orbit is in a so called {{w|Circumstellar habitable zone|habitable zone}} where the temperature allows liquid water and thus allows  life as we know it to exist. A probabilistic Earth would spend most of its time in the habitable zone, which is why life exists, but then, in short periods when it is outside the zone, some life would die. The title text claims this is why life on Earth is mortal, thus indirectly implying that life only dies in the periods where Earth leaves the habitable zone, and that life staying in the habitable zone would be immortal.
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There was already an orbital model parody made in [[2100: Models of the Atom]], which featured the planetary one, but at that time it was solely for the humorous insertion of 'facts' into the subject of atomic theory.
 
  
 
==Transcript==
 
==Transcript==

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