Deathunter88
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Using Phosphoric Acid To Make Glass Resistant to Hydrofluoric Acid?
I was just reading about phosphoric acid and its reaction with glass because I plan do do a distillation that involves it but was worried that it
would destroy my flasks. However, as I was reading about it I came across the following:
"Phosphoric acid attacks glass at temperatures of 200°C and above, at first etching the surface uniformly and producing a moderate increase in
strength. After longer treatment the glass becomes coated with a layer of silicon phosphate which renders it resistant to hydrofluoric acid, but its
mechanical strength is reduced because of crystalline inclusions in the surface."
From the website: http://www.sciencedirect.com/science/article/pii/00223093709...
Is this true? Has anyone had any experiences doing this so they could use hydrofluoric acid in a glass vessel?
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j_sum1
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I have no experience of this but am interested.
I am going to throw out a wild stab in the dark here and posit that the increased resistance would not be sufficient to make a person want to put HF
in glass. If it worked well, it would probably already be done. (The paper you cite is 45 years old.)
It might have some applications for those who want to prepare ampouled specimens of fluorine. The real destroyer of glass in this instance is the OH
radicals on the surface which the F2 grabs and converts to HF which then attacks the glass. A bit of passivation via phosphoric acid may make a
difference. I have read a report of reasonably successful ampouling using a single crystal quartz ampoule and some additional treatment. (See quote
below.) Hot H3PO4 might be a step in the right direction that is simpler and cheaper than a single crystal of quartz.
| Quote: | from http://theodoregray.com/periodictable/Elements/009/index.htm...
Now, respectfully, I must take up a little bit of a qualm with your claim in fluorine...You mention that "There is no transparent container that will
hold it." Granted that is true if you're talking a "forever" time scale, but I strongly believe on a "realistic" scale (a few decades) it can be
done...albeit with some difficulty and great time placed into it. The way best to do it is first to get yourself a pure, single-crystal quartz
tube...Now that means one with an extremely high amount of surface Si-O-Si bonds and VERY few Si-OH endcaps. The best way to do this is to take the
inside portion of the quartz tube and silylate it. Then anneal it at the highest possible temperature that your annealing oven can stand...This will
drive off essentially ALLLLLLL the Si-OH end caps. Because remember, the real killer in fluorine gas for Si-O's is not the fluorine, but the OH's and
their ability to start a chain reaction with small amounts of HF in the fluorine gas. So, the first thing you need to do is get rid of the Si-OH's
which that should take care of as best as possible. Now, being absolutely certain that your quartz tube is flamed and ultra-dry, there's another
step...There was a fluorocarbon grease that DuPont made many years ago that was ultra-high-purity completely fluorinated, medium-high mol.weight
fluorocarbon grease (like a lower-molecular weight Teflon)...Take that stuff and literally melt it into the tube...It's clear and translucent and
won't affect the optics after the next step...So then take a high temperature vacuum oven and turn the tube upside down and melt the grease back
out...What this does is leave a verrrrry thin, essentially invisible layer of fluorocarbon grease layer on the inside of the tube. This layer acts as
a secondary "buffer" layer to the quartz. So IF there are any Si-OH's left on your quartz, they are difficult to get at by the fluorine gas because
the fluorine gas has a difficult time penetrating the grease...This step will add years to your fluorine gas display. Then the more difficult thing to
do is to make sure the quartz tube has a high-purity Teflon screw-top stopper to it so that it can seal ultra-tightly. (again, pure fluorine gas
without any water/HF in it may "trade" fluorines with Teflon, but you still have Teflon; same goes for the grease, the grease may "trade" fluorines as
we've seen in some isotopic studies, but it remains a carbon-fluorine bond).
Then you should get a sacrificial vacuum line (kind of expensive, but it'll just be fogged up after you're done though it's best to throw it away
because the integrity will be damaged) and run your fluorine gas THROUGH A LIQUID NITROGEN FILLED TRAP into your evacuated quartz tube. This is the
most important AND DANGEROUS step. This step is the most important because ALLLLL commercial fluorine sources have either water or HF in them. The
water and HF are what will start the "chain reaction" of eating away at things. And all it takes are a few atoms of these to get it started...But the
N2(l) will definitely remove ALL of them...But the fluorine gas will still have a small amount of volatility to it so as to fill your quartz tube with
approximately a quarter-atmosphere of pure F2. Now if you do anything with fluorine and leave ANY HF or H2O in it, fuggetaboutit...You'll get your
stuff eaten away promptly. You won't get a full atmosphere of fluorine in your quartz sample tube like I said, but it will be enough to see under the
right light and circumstances. And 50 years from now those one or two atoms of HF and H2O that are left in there will eventually have done enough
damage to destroy your sample tube, but I don't plan on worrying about it 50 years from now.
Sorry if that bored you...But I do say it with utmost respect...I spent 10 years fiddling and trying to perfect the best way to get a fluorine sample,
and that's the best way I could get it...So, methinks there are ways to store fluorine safely in a visible specimen tube; it just takes a great amount
of patience, diligence, safety-thoughts and equipment. |
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BromicAcid
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Quote: Originally posted by j_sum1  | I have no experience of this but am interested.
I am going to throw out a wild stab in the dark here and posit that the increased resistance would not be sufficient to make a person want to put HF
in glass. If it worked well, it would probably already be done. (The paper you cite is 45 years old.) |
Or there was just no incentive to develop it further since by that time HF manipulation was already established. The most recent citation of this
article was as recentat 2002 so there might be something good here. I love these little one-off comments like this that one can find in literature.
The idea is an interesting one. At one time I read that heating potassium in glassware replaces significant sodlium atoms in the crystal lattice,
this introduces stress in the glassware that leads to increased strength. The inital stage mentioned above sounds similar whereby the glass is etched
giving an increase in strength. But the remainder does seem worrisom that you have to keep cooking it from there the crystals begin to infiltrate the
structure of the glass. It does not sound like a homogenous process, the abstract itself says the deposits resemble 'barnacles on a ship' when they
are magnified. It would be simple enough to test this at home with some hydrofluoric acid, an accurate balance, and several treated samples. Would
make for a fun project.
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