Difference between revisions of "Plasma"

From NSV13
Jump to navigationJump to search
imported>Kosmos
m (Added The Identity of Plasma by Pybro)
imported>Kosmos
m (→‎Analysis: The Identity of Plasma: Added spaces, made stuff a little easier to read.)
Line 34: Line 34:
 
From here on in, a CANISTER refers to to the large, colored gas containers that you fill TANKS in. A CANISTER needs to be pulled, a TANK can be held in your hand.
 
From here on in, a CANISTER refers to to the large, colored gas containers that you fill TANKS in. A CANISTER needs to be pulled, a TANK can be held in your hand.
  
A full canister of plasma has an internal pressure of 4559.6kPa. Said full canister of plasma was released in a 6x6 room, built in space. This room was entirely devoid of air, and had a temperature of 0 Celsius (270 Kelvin). A gas analyzer was used to measure the pressure in this 6x6 room. It was 20.4kPa, and the temperature was 19C (289K). NOW, HERE IS THE VARIABLE PART: In ooc, it was agreed upon that a tile had a volume of 1.6m<sup>3</sup>. HOWEVER. In the code, it says that a gas cell is 2.5m<sup>3</sup>. Ultimately, using the 2.5m³ tile messes things up, getting us into a situation where we end up with half a carbon, and, yeah. For the sake of completion, I'll post the math for both.
+
A full canister of plasma has an internal pressure of 4559.6 kPa. Said full canister of plasma was released in a 6x6 room, built in space. This room was entirely devoid of air, and had a temperature of 0 Celsius (270 Kelvin). A gas analyzer was used to measure the pressure in this 6x6 room. It was 20.4 kPa, and the temperature was 19C (289K). NOW, HERE IS THE VARIABLE PART: In ooc, it was agreed upon that a tile had a volume of 1.6 m<sup>3</sup>. HOWEVER. In the code, it says that a gas cell is 2.5m<sup>3</sup>. Ultimately, using the 2.5 m³ tile messes things up, getting us into a situation where we end up with half a carbon, and, yeah. For the sake of completion, I'll post the math for both.
  
First, the 1.6m³
+
First, the 1.6 m³
  
 
Using the Ideal Gas Formula (PV=nrt), we can calculate the number of moles of plasma in our room, via some algebra fandangling. PV=nrt/rt = (PV)/(rt)=n. Pressure times volume DIVIDED BY gas constant times temperature equals moles.  
 
Using the Ideal Gas Formula (PV=nrt), we can calculate the number of moles of plasma in our room, via some algebra fandangling. PV=nrt/rt = (PV)/(rt)=n. Pressure times volume DIVIDED BY gas constant times temperature equals moles.  
  
1.6m³ = 4.096.    6x6 = 36.    4.096x36 = 147.456.  1m³ = 1000L.  147.456x1000 = 147,456L.
+
1.6 m³ = 4.096.    6x6 = 36.    4.096 x 36 = 147.456.  1 m³ = 1000 l.  147.456 x 1000 = 147,456 l.
  
(20.4kPa)(147,456L)/(8.314kPa/L/K/mol)(292K) = 3008102.4/2402.746 = '''1251.95mol plasma.'''
+
(20.4 kPa)(147,456 l) / (8.314 kPa/l/K/mol)(292 K) = 3008102.4 / 2402.746 = '''1251.95 mol plasma.'''
  
NOW FOR THE 2.5m³
+
NOW FOR THE 2.5 m³
  
2.5³ = 15.625x 36 = 562.5x1000 = 562,500L
+
2.5³ = 15.625 x 36 = 562.5 x 1000 = 562,500 l
  
Plugging the 562,500L into the equation and replacing the 147,456L with it gives us '''4726.8mol of plasma.'''
+
Plugging the 562,500 l into the equation and replacing the 147,456 l with it gives us '''4726.8 mol of plasma.'''
  
 
This is quite a difference.  
 
This is quite a difference.  
Line 55: Line 55:
  
 
===NOW ONTO THE PART THAT INVOLVES FIRE===
 
===NOW ONTO THE PART THAT INVOLVES FIRE===
A full tank of plasma, which contains either 4774.80mol or 1251.95mol of plasma at 4559.6kPa, was pumped into the incinerator burn chamber. An excess of oxygen was then pumped in, and the whole mix was ignited. After it cooled, our brave atmos tech scientist entered. Some time was taken to let the mixture spread throughout the 10 tile area. The area was then scanned.
+
A full tank of plasma, which contains either 4774.80mol or 1251.95mol of plasma at 4559.6 kPa, was pumped into the incinerator burn chamber. An excess of oxygen was then pumped in, and the whole mix was ignited. After it cooled, our brave atmos tech scientist entered. Some time was taken to let the mixture spread throughout the 10 tile area. The area was then scanned.
  
375.35kPa, at 97.4C (370.4K). THIS WAS DONE ON ASTEROID STATION HOWEVER, and on Asteroid, the incinerator burn chamber is not empty! CO<sub>2</sub> 53%, O<sub>2</sub> 36%, N2 9%.
+
375.35 kPa, at 97.4 °C (370.4K). THIS WAS DONE ON ASTEROIDSTATION HOWEVER, and on Asteroid, the incinerator burn chamber is not empty! CO<sub>2</sub> 53 %, O<sub>2</sub> 36 %, N2 9 %.
  
375.35x.53 = 198.935kPa.
+
375.35 x 0.53 = 198.935 kPa.
  
 
===Go CO<sub>2</sub> woohooo===
 
===Go CO<sub>2</sub> woohooo===
Now let's see how much CO<sub>2</sub> a single canister of plasma can make. 156,250L for the volume of the 2.5m³.
+
Now let's see how much CO<sub>2</sub> a single canister of plasma can make. 156,250 l for the volume of the 2.5 m³.
  
10x4.096x1000 = 40,960L.
+
10 x 4.096 x 1000 = 40,960 l
  
10x15.625x1000 = 156,250L.
+
10 x 15.625 x 1000 = 156,250 l
  
(198.935)(40,960L)/(8.314)(370.4) = 2,646mol CO<sub>2</sub>.
+
(198.935)(40,960 l) / (8.314)(370.4) = 2,646 mol CO<sub>2</sub>.
  
(198.935)(156,250L)/(8.314)(370.4) = 10,093.696mol CO<sub>2</sub>.
+
(198.935)(156,250 l) / (8.314)(370.4) = 10,093.696 mol CO<sub>2</sub>.
  
 
EVERYTHING IN ITALICS IS CORRECT AS FAR AS PROCEDURE AND METHOD GOES, BUT THE ACTUAL NUMBERS ARE INCORRECT. I'M ONLY KEEPING IT AS AN EXPLANATION OF CONVERTING MOLES OF CO<sub>2</sub> TO MOLES OF CARBON.
 
EVERYTHING IN ITALICS IS CORRECT AS FAR AS PROCEDURE AND METHOD GOES, BUT THE ACTUAL NUMBERS ARE INCORRECT. I'M ONLY KEEPING IT AS AN EXPLANATION OF CONVERTING MOLES OF CO<sub>2</sub> TO MOLES OF CARBON.
Line 76: Line 76:
 
''Now then, because moles are hilarious little units, if we have 591.17mol of CO<sub>2</sub>, we also have 591.17mole of C.
 
''Now then, because moles are hilarious little units, if we have 591.17mol of CO<sub>2</sub>, we also have 591.17mole of C.
  
591.13mol/(1molC/1molCO<sub>2</sub>) = 591.13. Don't believe me? 591.13mol/1molCO<sub>2</sub>*46 = 27,192g.   The molecular weights of Carbon and CO<sub>2</sub> are 14 and 46 respectively. The percent by mass of carbon in CO<sub>2</sub> is 14/46 = 0.3043x100 = 30.43%.    27,192x0.3043 = 8274.52g carbon.   8274.52g carbon/14gCx1molC = 591.13molC. Fucking math, how does it work. The same applies for the 2.5m³ one. So it's 2232mol Carbon if a tile is 2.5m³.''
+
591.13 mol / (1 molC / 1 molCO<sub>2</sub>) = 591.13. Don't believe me? 591.13 mol / 1 molCO<sub>2</sub> x 46 = 27,192 g. The molecular weights of Carbon and CO<sub>2</sub> are 14 and 46 respectively. The percent by mass of carbon in CO<sub>2</sub> is 14 / 46 = 0.3043 x 100 = 30.43 %.    27,192 x 0.3043 = 8274.52 g carbon. 8274.52 g carbon / 14 gC x 1molC = 591.13 molC. Fucking math, how does it work. The same applies for the 2.5 m³ one. So it's 2232 mol Carbon if a tile is 2.5 m³.''
  
More CO<sub>2</sub>
+
===More CO<sub>2</sub>===
  
Now, That means that 1251.94molPlasma + ???molO<sub>2</sub> ----> ???molH<sub>2</sub>O + 2,656molCO<sub>2</sub>. But because we did the above, we can basically summarize that there are 2,646mol of carbon in 1251.94mol  of Plasma.  
+
Now, That means that 1251.94 molPlasma + ??? molO<sub>2</sub> ----> ??? molH<sub>2</sub>O + 2,656 molCO<sub>2</sub>. But because we did the above, we can basically summarize that there are 2,646 mol of carbon in 1251.94 mol of Plasma.  
  
Pure hydrocarbon chains exhibit a funny property. By taking the amount of CO<sub>2</sub> produced (and thus, carbon), and dividing it by the moles of hydrocarbon you burnt to get said CO<sub>2</sub> (and assuming you have 100% total combustion, no carbon monoxide produced), you can find out how many carbons are in a single mole of the Hydrocarbon!
+
Pure hydrocarbon chains exhibit a funny property. By taking the amount of CO<sub>2</sub> produced (and thus, carbon), and dividing it by the moles of hydrocarbon you burnt to get said CO<sub>2</sub> (and assuming you have 100 % total combustion, no carbon monoxide produced), you can find out how many carbons are in a single mole of the Hydrocarbon!
  
 
Thus, the burning of Hexane is:
 
Thus, the burning of Hexane is:
  
C6H14 + (19/2)O<sub>2</sub> ---> 6CO<sub>2</sub> + 7H<sub>2</sub>0
+
C<sub>6</sub>H<sub>14</sub> + (19/2)O<sub>2</sub> ---> 6CO<sub>2</sub> + 7H<sub>2</sub>0
  
 
So:
 
So:
  
12C6H14 + blah --> 72CO<sub>2</sub> + blah
+
12C<sub>6</sub>H<sub>14</sub> + blah --> 72CO<sub>2</sub> + blah
  
72/12 = 6!
+
72 / 12 = 6 !
  
  
Line 98: Line 98:
  
  
2656/1251.95 If we divide the two, we get 2.11, meaning that for every 1 mole of plasma, we have 2.11 moles of carbon!
+
2656 / 1251.95 If we divide the two, we get 2.11, meaning that for every 1 mole of plasma, we have 2.11 moles of carbon!
  
And if we use the 2.5m³, we end up with 10,093/4995 = 2.02! Told you it didn't matter.
+
And if we use the 2.5 m³, we end up with 10,093 / 4995 = 2.02! Told you it didn't matter.
  
 
Now, this is all theoretical, and calculations, and I've rounded a lot of the decimals (I ain't working with 24.858849389200102299383838392929292 due to spessmens, 2.858 will suffice), we can thus say, that there are TWO CARBONS IN A PLASMA MOLECULE. Plus, y'know, you can't have .11, or .02, of a molecule. Shit just ain't possible.
 
Now, this is all theoretical, and calculations, and I've rounded a lot of the decimals (I ain't working with 24.858849389200102299383838392929292 due to spessmens, 2.858 will suffice), we can thus say, that there are TWO CARBONS IN A PLASMA MOLECULE. Plus, y'know, you can't have .11, or .02, of a molecule. Shit just ain't possible.
  
Which means that plasma has a structure that looks something like
+
Which means that plasma has a structure that looks something like:
 +
 
 +
'''C-C,,,,C=C, or C≡C'''
  
==='''C-C,,,,C=C, or C≡C'''===
 
 
With three, two, and one bonding site on each carbon, respectively.
 
With three, two, and one bonding site on each carbon, respectively.
  
A rant about isotopes
+
===A rant about isotopes===
  
 
But...Then plasma is just a regular derivative of ethane, ethene, or ethyne! "what the fuck pybro you're such a fucking faggot you waste my very precious ten minutes!". Hold up there! Yes, it's just regular ethene, ethane, '''IF''' YOU USE <sup>1</sup>H, AKA Protium, AKA "Normal hydrogen" AKA "A single proton with an electron buzzing around it". Atoms are composed of protons (positive), electrons (negative), and neutrons (neutral). Isotopes are atoms that have a "deviant" number of neutrons. This messes shit up, and gives isotopes different properties than the "normal" element. Generally (although there are exceptions!), the "normal" isotope has as many neutrons as it does protons. Protium AKA "normal" hydrogen, is one such exception.
 
But...Then plasma is just a regular derivative of ethane, ethene, or ethyne! "what the fuck pybro you're such a fucking faggot you waste my very precious ten minutes!". Hold up there! Yes, it's just regular ethene, ethane, '''IF''' YOU USE <sup>1</sup>H, AKA Protium, AKA "Normal hydrogen" AKA "A single proton with an electron buzzing around it". Atoms are composed of protons (positive), electrons (negative), and neutrons (neutral). Isotopes are atoms that have a "deviant" number of neutrons. This messes shit up, and gives isotopes different properties than the "normal" element. Generally (although there are exceptions!), the "normal" isotope has as many neutrons as it does protons. Protium AKA "normal" hydrogen, is one such exception.
 
   
 
   
Hyrogen has two isotopes. One, Deuterium, which is stable, and forms Deuterium Oxide (D2O), AKA "Heavy Water" (Heavy water icecubes don't float on top of liquid water or heavy water, fun fact). Deuterium is a proton, a neutron, and an electron. There is also, TRITIUM, which is two neutrons, a proton, an electron. Tritium is also radioactive. On earth, Tritium is rare. In spess however, it's rather common (the source of tritium on earth is normal hydrogen getting hit by COSMIC RAYS). Tritium is also very toxic.  
+
Hyrogen has two isotopes. One, Deuterium, which is stable, and forms Deuterium Oxide (D<sub>2</sub>O), AKA "Heavy Water" (heavy water icecubes don't float on top of liquid water or heavy water, fun fact). Deuterium is a proton, a neutron, and an electron. There is also, TRITIUM, which is two neutrons, a proton, an electron. Tritium is also radioactive. On earth, Tritium is rare. In spess however, it's rather common (the source of tritium on earth is normal hydrogen getting hit by COSMIC RAYS). Tritium is also very toxic.  
  
 
Hydrogens isotopes are very special, in that they get their own letters! Protium is H, Deuterium is D, and Tritium is T.  
 
Hydrogens isotopes are very special, in that they get their own letters! Protium is H, Deuterium is D, and Tritium is T.  
Line 141: Line 142:
 
Three, Tritium has a rather large half life, and even then is rather weak as far as radioactivity goes (you still don't want it in you, however). You can dunk yourself in tritium oxide (T<sub>2</sub>O), and so long as you don't get any IN YOU, your guts will be fine, you only risk skin cancer.  
 
Three, Tritium has a rather large half life, and even then is rather weak as far as radioactivity goes (you still don't want it in you, however). You can dunk yourself in tritium oxide (T<sub>2</sub>O), and so long as you don't get any IN YOU, your guts will be fine, you only risk skin cancer.  
  
Four, given that burning plasma only produces CO<sub>2</sub> (and water, which is actually Tritium Oxide, aka super-heavy water, aka radio-fucking-active water), it can ONLY have Hydrogen (or isotopes of), Carbon, and oxygen in it. Tritium is necessary to get the weight up into the range where it can be a liquid at standard temperature and pressure AT ALL, while at the same time giving it the necessary toxicity. Plasma gives you TOXIN damage, it does NOT give you oxyloss damage, so it doesn't just suffocate you, it actively attacks your body in SOME way. Ethane (C2H6) does not do this, and is pretty much completely non-toxic. Hell, the only real dangers of ethane are asphyxiation (oxyloss) and igniting it (burn/bomb).
+
Four, given that burning plasma only produces CO<sub>2</sub> (and water, which is actually Tritium Oxide, aka super-heavy water, aka radio-fucking-active water), it can ONLY have Hydrogen (or isotopes of), Carbon, and oxygen in it. Tritium is necessary to get the weight up into the range where it can be a liquid at standard temperature and pressure AT ALL, while at the same time giving it the necessary toxicity. Plasma gives you TOXIN damage, it does NOT give you oxyloss damage, so it doesn't just suffocate you, it actively attacks your body in SOME way. Ethane (C<sub>2</sub>H<sub>6</sub>) does not do this, and is pretty much completely non-toxic. Hell, the only real dangers of ethane are asphyxiation (oxyloss) and igniting it (burn/bomb).
  
 
Five, the OH (or OT, as it were) is necessary to also bump up the weight into the range where it can be a liquid/solid at room temperature. It also gives it enough intermolecular forces (the hydrogen/tritium bonding) to aid it being a liquid.
 
Five, the OH (or OT, as it were) is necessary to also bump up the weight into the range where it can be a liquid/solid at room temperature. It also gives it enough intermolecular forces (the hydrogen/tritium bonding) to aid it being a liquid.

Revision as of 05:46, 30 January 2015

A miracle substance, this is one of the things SS13 mines and researches.

The States of Plasma

Plasma has a number of different states.

Most Common Uses


Analysis: The Identity of Plasma

So, for several years, NT has been doing this "plasma research" shit. However, apparently, NT only hired pyromaniacs and terrorists to work with plasma. As such, the identity of plasma is a mystery, other than that it's purple and floaty n' shit.

So, I figured, hey, it's winter break! I might as well sperg out, right?

Now, when a hydrocarbon burns, it produces CO2, and H2O. Burning Plasma produces ONLY CO2. Thus, Plasma is a hydrocarbon. It is composed ONLY of Hydrogen, and Carbon. Now, it MAY also contain oxygen, but that is variable. Given that we don't actually have water as a gas in SS13, you can just ignore the part about the water. One thing about hydrocarbons, is that they are usually gases, then around hexane, turn to volatile liquids. Plasma, is very fucking volatile (Ever spill a beaker of it? Take my advice: Don't.)

Now, for the number crunching and data.

From here on in, a CANISTER refers to to the large, colored gas containers that you fill TANKS in. A CANISTER needs to be pulled, a TANK can be held in your hand.

A full canister of plasma has an internal pressure of 4559.6 kPa. Said full canister of plasma was released in a 6x6 room, built in space. This room was entirely devoid of air, and had a temperature of 0 Celsius (270 Kelvin). A gas analyzer was used to measure the pressure in this 6x6 room. It was 20.4 kPa, and the temperature was 19C (289K). NOW, HERE IS THE VARIABLE PART: In ooc, it was agreed upon that a tile had a volume of 1.6 m3. HOWEVER. In the code, it says that a gas cell is 2.5m3. Ultimately, using the 2.5 m³ tile messes things up, getting us into a situation where we end up with half a carbon, and, yeah. For the sake of completion, I'll post the math for both.

First, the 1.6 m³

Using the Ideal Gas Formula (PV=nrt), we can calculate the number of moles of plasma in our room, via some algebra fandangling. PV=nrt/rt = (PV)/(rt)=n. Pressure times volume DIVIDED BY gas constant times temperature equals moles.

1.6 m³ = 4.096. 6x6 = 36. 4.096 x 36 = 147.456. 1 m³ = 1000 l. 147.456 x 1000 = 147,456 l.

(20.4 kPa)(147,456 l) / (8.314 kPa/l/K/mol)(292 K) = 3008102.4 / 2402.746 = 1251.95 mol plasma.

NOW FOR THE 2.5 m³

2.5³ = 15.625 x 36 = 562.5 x 1000 = 562,500 l

Plugging the 562,500 l into the equation and replacing the 147,456 l with it gives us 4726.8 mol of plasma.

This is quite a difference.

((((I also did this for oxygen, but ultimately that data is not needed for this, so yeah)))))

NOW ONTO THE PART THAT INVOLVES FIRE

A full tank of plasma, which contains either 4774.80mol or 1251.95mol of plasma at 4559.6 kPa, was pumped into the incinerator burn chamber. An excess of oxygen was then pumped in, and the whole mix was ignited. After it cooled, our brave atmos tech scientist entered. Some time was taken to let the mixture spread throughout the 10 tile area. The area was then scanned.

375.35 kPa, at 97.4 °C (370.4K). THIS WAS DONE ON ASTEROIDSTATION HOWEVER, and on Asteroid, the incinerator burn chamber is not empty! CO2 53 %, O2 36 %, N2 9 %.

375.35 x 0.53 = 198.935 kPa.

Go CO2 woohooo

Now let's see how much CO2 a single canister of plasma can make. 156,250 l for the volume of the 2.5 m³.

10 x 4.096 x 1000 = 40,960 l

10 x 15.625 x 1000 = 156,250 l

(198.935)(40,960 l) / (8.314)(370.4) = 2,646 mol CO2.

(198.935)(156,250 l) / (8.314)(370.4) = 10,093.696 mol CO2.

EVERYTHING IN ITALICS IS CORRECT AS FAR AS PROCEDURE AND METHOD GOES, BUT THE ACTUAL NUMBERS ARE INCORRECT. I'M ONLY KEEPING IT AS AN EXPLANATION OF CONVERTING MOLES OF CO2 TO MOLES OF CARBON.

Now then, because moles are hilarious little units, if we have 591.17mol of CO2, we also have 591.17mole of C.

591.13 mol / (1 molC / 1 molCO2) = 591.13. Don't believe me? 591.13 mol / 1 molCO2 x 46 = 27,192 g. The molecular weights of Carbon and CO2 are 14 and 46 respectively. The percent by mass of carbon in CO2 is 14 / 46 = 0.3043 x 100 = 30.43 %. 27,192 x 0.3043 = 8274.52 g carbon. 8274.52 g carbon / 14 gC x 1molC = 591.13 molC. Fucking math, how does it work. The same applies for the 2.5 m³ one. So it's 2232 mol Carbon if a tile is 2.5 m³.

More CO2

Now, That means that 1251.94 molPlasma + ??? molO2 ----> ??? molH2O + 2,656 molCO2. But because we did the above, we can basically summarize that there are 2,646 mol of carbon in 1251.94 mol of Plasma.

Pure hydrocarbon chains exhibit a funny property. By taking the amount of CO2 produced (and thus, carbon), and dividing it by the moles of hydrocarbon you burnt to get said CO2 (and assuming you have 100 % total combustion, no carbon monoxide produced), you can find out how many carbons are in a single mole of the Hydrocarbon!

Thus, the burning of Hexane is:

C6H14 + (19/2)O2 ---> 6CO2 + 7H20

So:

12C6H14 + blah --> 72CO2 + blah

72 / 12 = 6 !


THUUUUUUUS!


2656 / 1251.95 If we divide the two, we get 2.11, meaning that for every 1 mole of plasma, we have 2.11 moles of carbon!

And if we use the 2.5 m³, we end up with 10,093 / 4995 = 2.02! Told you it didn't matter.

Now, this is all theoretical, and calculations, and I've rounded a lot of the decimals (I ain't working with 24.858849389200102299383838392929292 due to spessmens, 2.858 will suffice), we can thus say, that there are TWO CARBONS IN A PLASMA MOLECULE. Plus, y'know, you can't have .11, or .02, of a molecule. Shit just ain't possible.

Which means that plasma has a structure that looks something like:

C-C,,,,C=C, or C≡C

With three, two, and one bonding site on each carbon, respectively.

A rant about isotopes

But...Then plasma is just a regular derivative of ethane, ethene, or ethyne! "what the fuck pybro you're such a fucking faggot you waste my very precious ten minutes!". Hold up there! Yes, it's just regular ethene, ethane, IF YOU USE 1H, AKA Protium, AKA "Normal hydrogen" AKA "A single proton with an electron buzzing around it". Atoms are composed of protons (positive), electrons (negative), and neutrons (neutral). Isotopes are atoms that have a "deviant" number of neutrons. This messes shit up, and gives isotopes different properties than the "normal" element. Generally (although there are exceptions!), the "normal" isotope has as many neutrons as it does protons. Protium AKA "normal" hydrogen, is one such exception.

Hyrogen has two isotopes. One, Deuterium, which is stable, and forms Deuterium Oxide (D2O), AKA "Heavy Water" (heavy water icecubes don't float on top of liquid water or heavy water, fun fact). Deuterium is a proton, a neutron, and an electron. There is also, TRITIUM, which is two neutrons, a proton, an electron. Tritium is also radioactive. On earth, Tritium is rare. In spess however, it's rather common (the source of tritium on earth is normal hydrogen getting hit by COSMIC RAYS). Tritium is also very toxic.

Hydrogens isotopes are very special, in that they get their own letters! Protium is H, Deuterium is D, and Tritium is T.

I propose that the hydrogens in plasma are actually Tritium. This raises the molecular mass up to the point where you could have a beaker of it as a liquid, but upon spilling it, get a gas. Tritium is toxic, but only when you actually get it in you, despite the fact that it's radioactive, the radiation from it is not strong enough to break your skin, although it might give you skin cancer, but your guts will be fine.

Thus, we know the following:

  • Plasma is a two carbon compound, and the only two other elements that are/could be in it are hydrogen and oxygen.
  • Plasma is a volatile liquid.
  • Plasma can be a liquid, gas, and solid at room temperature.
  • Plasma is highly toxic when inhaled, drank, and injected, but is fairly harmless (in the short term) when your skin touches it. Unless, y'know, you get set on fire.
  • Plasma burns readily in the presence of oxygen, both when a liquid and a gas.
  • When mixed with nitrogen and hydrogen, it produces lexorin, which basically shuts down cellular respiration. While not as potent as raw cyanide, lexorin is most certainly a brand name of some nitrile compound that NanoTrasen has a trademark on and sells as a paint thinner or something. BUT! Cyanide/Nitrile is basically a carbon and a nitrogen triple bonded together, and lexorin is made by adding plasma, nitrogen, and hydrogen.

Thus, I propose that Plasma looks something like this:

Plasma molecule.png

Essentially, Tritiated Ethanol. It's volatile, burns very easily, the Alcohol group at the right (Tritahol?) provides it with enough mass and hydrogen bonding (tritium bonding?) to keep it stable as a liquid, yet is still volatile, and is incredibly bad to drink.

This also answers several questions.

One, plasma is a radioactive compound, yes, but the halflife of Tritium is 12.3 YEARS. It is very fucking toxic, and is a great catalyst/solvent. It's not very toxic ON CONTACT, for short periods. But upon ingestion, it basically fucks your whole body up. The biochemistry of this is that your body uses the tritium/tritium oxide to replace your normal protium. Now, Deuterium in large quantities fucks you up because it's heavier than protium, and as such, has interesting effects on your body (and by interesting I mean "bad/deadly"). Now let's make it even heavier, and radioactive. Yeah.

Two, plasma would be rare on Earth, but in a gas giant that's composed mainly of this shit, it'd be produced easily. Even more so if the Plasma-Gas-Giant doesn't have an atmosphere that could block out the cosmic rays.

Three, Tritium has a rather large half life, and even then is rather weak as far as radioactivity goes (you still don't want it in you, however). You can dunk yourself in tritium oxide (T2O), and so long as you don't get any IN YOU, your guts will be fine, you only risk skin cancer.

Four, given that burning plasma only produces CO2 (and water, which is actually Tritium Oxide, aka super-heavy water, aka radio-fucking-active water), it can ONLY have Hydrogen (or isotopes of), Carbon, and oxygen in it. Tritium is necessary to get the weight up into the range where it can be a liquid at standard temperature and pressure AT ALL, while at the same time giving it the necessary toxicity. Plasma gives you TOXIN damage, it does NOT give you oxyloss damage, so it doesn't just suffocate you, it actively attacks your body in SOME way. Ethane (C2H6) does not do this, and is pretty much completely non-toxic. Hell, the only real dangers of ethane are asphyxiation (oxyloss) and igniting it (burn/bomb).

Five, the OH (or OT, as it were) is necessary to also bump up the weight into the range where it can be a liquid/solid at room temperature. It also gives it enough intermolecular forces (the hydrogen/tritium bonding) to aid it being a liquid.

Six, Solid plasma is plasma put under intense pressure for a quick moment, allowing it to crystallize. When left alone, it will eventually melt, and evaporate.

Seven, NOWHERE IS THE EXPLICIT MASS OF PLASMA ACTUALLY STATED.

Eight, the combustion equation for plasma would be:

C2T5OT + 3O2 ---> 2CO2 + 3T2O


Theory by Pybro