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| <!--Please sign your posts with ~~~~ and don't delete this text. New comments should be added at the bottom.--> | | <!--Please sign your posts with ~~~~ and don't delete this text. New comments should be added at the bottom.--> |
| Omega Decay has a didtinctive Star Trek Voyager vibe, I believe... ;-) https://memory-alpha.fandom.com/wiki/Omega_molecule [[Special:Contributions/162.158.203.70|162.158.203.70]] 23:03, 27 November 2023 (UTC) | | Omega Decay has a didtinctive Star Trek Voyager vibe, I believe... ;-) https://memory-alpha.fandom.com/wiki/Omega_molecule [[Special:Contributions/162.158.203.70|162.158.203.70]] 23:03, 27 November 2023 (UTC) |
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− | :There are a few things Omega could relate to: Rick and Morty Omega Device https://rickandmorty.fandom.com/wiki/Omega_Device, Galaxy Quest Omega 13 Device https://galaxyquest.fandom.com/wiki/The_Omega_13_Device [[Special:Contributions/172.68.126.134|172.68.126.134]] 02:46, 28 November 2023 (UTC)
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− | :Omega voyager vibe? Nah, Voyager just used a cool sounding name. They share a root, but this isn't depending on ST:VOY [[Special:Contributions/172.69.195.47|172.69.195.47]] 09:09, 28 November 2023 (UTC)
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| There appears to be an issue- the ''fungal decay'' and ''sea peoples'' are missing. I don't remember what they were! Help! | | There appears to be an issue- the ''fungal decay'' and ''sea peoples'' are missing. I don't remember what they were! Help! |
| [[Special:Contributions/162.158.159.226|162.158.159.226]] 23:55, 27 November 2023 (UTC)[[Fizzgigg]] | | [[Special:Contributions/162.158.159.226|162.158.159.226]] 23:55, 27 November 2023 (UTC)[[Fizzgigg]] |
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− | "One big nucleon" looks a lot like a planet to me.[[User:Nitpicking|Nitpicking]] ([[User talk:Nitpicking|talk]]) 03:02, 28 November 2023 (UTC)
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− | I was rather hoping that [[1812: Onboarding|bismuth]] would appear as a product, even if entirely unintentional, but it's far too high up the chain to ever occur from "bronze decay"... [[Special:Contributions/172.70.85.147|172.70.85.147]] 14:01, 28 November 2023 (UTC)
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− | Protons shown in white, while the neutrons in black in the comic. Nothing wrong with this but if you visualize it the other way it makes this very confusing. {{unsigned ip|162.158.62.120|19:11, 28 November 2023}}
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− | The transcript might need some rearranging, because the labels are technically under the diagram? although that might make it confusing. or less confusing.--[[User:Mushrooms|Mushrooms]] ([[User talk:Mushrooms|talk]]) 18:01, 29 November 2023 (UTC)
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− | Part of the explanation for alpha decay seems a bit mixed up: "...proton-rich / neutron-deficient heavy nuclei, which normally have many more neutrons than protons." Surely 'proton-rich' means more protons and 'neutron-deficient' means fewer neutrons, so such a nucleus would have many more protons than neutrons, wouldn't it? I hesitate to change the explanation because I'm more of a language expert than particle physicist. [[Special:Contributions/172.68.64.226|172.68.64.226]] 00:26, 3 December 2023 (UTC)
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− | :Consider uranium 238, which has 92 protons and 146 neutrons. It decays by alpha radiation to thorium 234: 90 protons and 144 neutrons. In both cases, there are a lot more neutrons than protons, but the ratio of neutrons to protons is higher in the latter because if N > P, N/P < (N-2)/(P-2). Or polonium 210, with 84 protons and 126 neutrons, which decays by alpha (as the last step in the U-238 decay series) to stable lead 206, with 82 protons and 124 neutrons. With sufficient decrease in the number of protons and increase in the N/P ratio, the system becomes stable. All elements have multiple possible isotopes, and as the proton count increases, the number of neutrons needed for stability tends to increase a bit more quickly. If there aren't quite enough neutrons, a common decay mode is alpha, which decreases the proton count and "improves" the ratio. If the number of neutrons is a bit too high for stability, the most common decay mode is beta, increasing the number of protons and decreasing the number of neutrons, again "improving" the ratio. This is a gross oversimplification, of course. [[User:BunsenH|BunsenH]] ([[User talk:BunsenH|talk]]) 05:44, 3 December 2023 (UTC)
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− | :I read "...proton-rich / neutron-deficient heavy nuclei, which normally have many more neutrons than protons." as "This example has more protons and less neutrons than you'd expect for a nucleus of this weight. One with this many nucleons, in total, should consist of a greater proportion of neutrons"... But it does look a bit confusing. Definitely would be open to a rewrite (but not flipping the beginning, which'd only be rightly understood when wrongly comprehended, and vice-versa). [[Special:Contributions/172.70.85.163|172.70.85.163]] 13:41, 3 December 2023 (UTC)
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