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Chem - Blog Posts
Things that happened in chemistry today:
1. Teacher said this weekend was better than any weekend he'd ever had
Why? He took his baby to this gymnastics thingy (valid)
This was rated better than:
1. When he beat an American record in pole vaulting
2. When he played in Germany for American pole vaulting
3. His wedding
4. When he took said baby home for the first time
2. A mole went 'missing' for st.patricks day
3. Said mole is apparently named Moledo (Like waldo)
4. Teacher apparently lets Moledo go out at night to catch worms n shit
5. Moledo is dead. He was murdered.
Teacher said his goodbyes to Moledo
We couldn't hear him cause he was in the courtyard and we were in the halls
6. We were sent to investigate Moledos death
7. We were the only class to sprint (If we collected the evidence cards in under 7 min we got extra credit)
RIP Moledo
He will be missed 😔
The Chemical Structure of Redstone
So I was curious about what the chemical structure of Redstone looks like, and Minecraft Education Edition, albeit unintentionally, gives us a canon look into what Redstone is made of:
In Minecraft Education Edition, putting a Redstone Block into a Material Reducer shows that it's composed of 31 Carbon, 31 Uranium, and 38 Unobtanium, which we can assume to be measured in grams
Dividing the Redstone Block into Redstone Dust, each Redstone Dust is then composed of approximately 3.4 Carbon, 3.4 Uranium, and 4.2 Unobtanium
Again assuming that's measured in grams, that's 0.17 cm³ of Uranium, 1.496 cm³ of Carbon, and ???³ of Unobtanium per Redstone Dust
So what does this tell us about the chemical structure of Redstone? Basing this on Redstone Dust's composition, we can estimate that each Redstone molecule is composed of 3 Carbon atoms, 3 Uranium atoms, 4 Unobtanium atoms, a little under half of the time it binds to an extra Uranium and/or Carbon, and 20% of the time it binds to an extra Unobtanium
This also has some horrifying implications for how Redstone works:
Redstone would be extremely volatile as the radioactive decay from Unobtanium and Uranium would occasionally release Helium ions through alpha radiation, sometimes breaking apart Carbon into two Beryllium atoms (as it absorbs the extra proton and neutron from the Uranium) or merging into Oxygen
So Redstone should, in theory, be extremely flammable and potentially explosive, which implies that cave static, or the player mining Redstone with an Iron Pickaxe, could lead to a spark that causes an explosive cave-in
As Unobtanium is just a placeholder for unobtainable elements (hence the name), I'm going to estimate Unobtanium in this case as Unbinilium, the placeholder name for element 120
Why?
I'm estimating the Unobtanium as Redstone as being larger than the largest man-made element, Oganesson, which holds an impressive 118 protons
Each valence electron shell, from innermost to outermost, can bind with 2, 8, 18, 32, 32, 18, and 8 shells respectively, so I'd like Unobtanium to be an element we haven't discovered yet, and consequently I'd like to jump up to the next shell
While I could estimate with element 119's placeholder, Ununennium, it would have one electron in the next shell, so Unbinilium allows for easier chemical binding
So what does this molecule look like then? Well, horrifyingly...
It looks like this. As Redstone forms in crystal lattices, and only two Carbon atoms are free to bind, I can absolutely see why it's so brittle that it breaks into powder.
This makes the structure of Redstone:
C3U3Uno4 (55% of molecules) C4U3Uno4 (13% of molecules) C3U4Uno4 (13% of molecules) C4U4Uno4 (7% of molecules) C3U3Uno5 (5% of molecules) C4U3Uno5 (3% of molecules) C3U4Uno5 (3% of molecules) C4U4Uno5 (1% of molecules)
An extremely radioactive, flammable, and explosive compound.
![[A periodic table with regions labeled facetiously, such as hydrogen being labelled "slightly fancy protons", the platinums labelled "[dollar signs]", Lithium and Beryllium being labelled "weird dirt", and the Noble Gases being labelled "lawful neutral".]](https://64.media.tumblr.com/159f80f539ada5539cc0ac89f79900ac/6085bfdbabcf442c-c8/s500x750/70ef49fe13a92194a6db4fc1b8f3513900e05280.png)
Cesium-133, let it be. Cesium-134, let it be even more.
Periodic Table Regions [Explained]
Transcript
[A periodic table with regions labeled.]
[Hydrogen:] Slightly fancy protons [Lithium and Beryllium:] Weird dirt [Group 1 & 2 metals, Periods 3-4:] Regular dirt [Group 1 & 2 metals, Periods 5-7:] Ends in a number, let it slumber ends in a letter, not much better [Left side of the transition metals group:] Boring alloy metals Probably critical to the spark plug industry or something (but one of them is radioactive so stay on your toes) [Most of the top row of the transition metals + aluminum:] Regular metals [Below the rightmost "regular metals" - the "ordinary metals" and some transition metals:] Weird metals [The platinum group:] $$$$ [Boron:] Boron (fool's carbon) [Carbon, Nitrogen, Oxygen, and Phosphorus:] You are here [The Halogens:] Safety goggles required [Noble Gases:] Lawful neutral [Iodine and Radon:] Very specific health problems [Ordinary metals and metalloids - Arsenic, Antimony, Tellurium, Thallium, Lead, Bismuth, Polonium] Murder weapons [Astatine and Period 7 from Rutherfordium onwards:] Don't bother learning their names - they're not staying long [Lanthanides and Actinides:] Whoever figures out a better way to fit these up there gets the next Nobel Prize