Acetic anhydride preparation

The smell of AA is etheral in the first 2-3 second then the pleasant light smell turns into strongly acetic, and irritates the eyes and all your mucous membrane like hell.. I really fucked up the first time I smelled it

If you pour a little water(cold) + AA into a test tube then shook it, the mix quickly separates, my experiance is that the AA will be the upper layer in spite of the fact that its density is higher than that of water.

Also you can light it with a flame, while glacial acetic does not burn.

Another test is to boil it with ethyl alcohol, but do not forget to add a few drops of H2SO4 or you will get nothig.

If you ask me, the kete method beat the shit outta all the other methods mentioned here.. I mean.. It is nice to filter extract heat chlorinate fractionate etc.. to get a few ml of AA and get closer to chemistry, but if you want a decent quantity, ketene is the way to go.

I made pure/colourless ~95% AA by the ketene method several times ~250ml/run. One run takes me about 6 hours. and the yield was always more than 80%.

Quote: Originally posted by Jimmymajesty

I made pure/colourless ~95% AA by the ketene method several times ~250ml/run. One run takes me about 6 hours. and the yield was always more than 80%.

I will take a photo from the ketene generator when I got back my cam.. I am going to put a spline or something next to it for you to be able to take its measures by the picture. But easier to say that I followed the organic reactions vol 3 that is in the public library.

I could not follow all the instructions for obvious reasons, for example I cannot afford platinum wire.. But the lamp works well, and thats the point.

The main issue with the tube furnace method is the reflux, I use a two litre RBFL as a reboiler, and during the 6 hours, if I had to make a guess, I reflux the 1 litre acetone a hundred times. This cannot be done in case of tube furnaces.. I think.. but I never tried tube furnaces.

BTW carbonisation is not that big of an issue, after two runs the kanthal wire was still ok, and the reboiled acetone had only a yellow tint, also it can be reboiled to get rid of conjugated olefines which I think the main impurities in acetone after a couple of runs.

If you are seriously planning to bulid a lamp, I can advice you how to improve you filament and also plastic materials which are resist to ketene, but a lot of plastics resist to it.. actually all of the plastics I used till now resisted to ketene

See attachment for photos.

The tungsten rods were purchased from welding shop, their diamater=1mm

It was difficult make the upper part of the device for even an experienced glass blower.

And when I showed to him the original drawing, he said at first that theres no way that he could make it, so we discussed the possibilies, again, it works well and only costed me about 30 dollars not counting the tungsten rods which costed about 1 dollar each.

I can highly recommend to anyone who wants to make ketene or acetic anhydride to make this device, it was a first run success type synthesis, while with acetaldehyde I sucked alot.

P.S. Magpie seeing the apparatus you have, you should really give the lamp a try! I mean quartz tube with grounded joints etc... eh!

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Quote: Originally posted by Jimmymajesty

P.S. Magpie seeing the apparatus you have, you should really give the lamp a try! I mean quartz tube with grounded joints etc... eh!

Thanks Jimmy for the photo. It looks like that scale is about 13 cm long?

That's an impressive looking piece of glassware. Unfortunately I don't have a local glassblower that will help me. We have one but he has his head up his ass. He'll only work for businesses or educational institutions.

I can't believe that you got that put together for only $30. You must not live in any "Western" country. That would be at least $100 where I live.

The AA will sink to the bottom in cold water too.. sorry for my misleading information above. I checked it.

I also tried out the reaction with benzamide, I added AA to benzamide, as usually nothing happened, then a few drops of H2SO4 and heat, and the content of the test tube immediately turned into intense red, almost black.

Magpie yes 13cm long.
Here in my country.. In the heart of Europe I know at least two glass blower that would be happy to make such kind of useless stuff for almost nothing, Iam suprised that you do not have any..

It would be nice If you could make a similar lamp and calibrate it.. for reflux ratio, different pretreatement of the filament etc, and compare the resulsts with mine.

Thanx not_important,,, much appreciated information...as you say,,not too good to be true.....just a "little tricky!!!"
[Edited on 6-6-2010 by hypnos]

[Edited on 6-6-2010 by hypnos]

I do not really understand you with your tungsten plating thing, you have to buy pure tungsten, molybdenum or platinum, other metals cannot be wetted by melted glass. tungsten is easy to get and cheap while the others are not.

I am also prefer to see pictures than imagine the glassware by dud descriptions, so...

The second picture is of the ice cube maker that is necessary to prevent acetone from boiling over, It keeps the cooling water temp @ ~6-10°C.

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Densest is right, a kiln is necessary, otherwise the glassware will crack on cooling, I also cracked some glassware even after annealing, especially the grounded glass joints the weak points.

My glassblower only work with pyrex, i.e. borosilicate, and uses acetylene-oxygen torch.

To make an electrode you have to heat the tungsten rod first, then melt a glass bead (also pyrex) and rub it on the surface of the rod, it will cling to it, then you can melt it into a tube with grounded glass joint.

The glassblower knows me well, but sent me to hell when I asked him to make spare electrodes.. so everyone draw their own conclusion

Quote: Originally posted by Jimmymajesty

My glassblower only work with pyrex, i.e. borosilicate, and uses acetylene-oxygen torch. To make an electrode you have to heat the tungsten rod first, then melt a glass bead (also pyrex) and rub it on the surface of the rod, it will cling to it, then you can melt it into a tube with grounded glass joint.

Jimmy, I mean plating the tungsten with platinum, which could be done after the electrode was in the glass.

$30 is ridiculously cheap for something like that! Although, it depends what $30 means where you are I guess. If it's the US, it's not a lot.

I've also heard about the benefits of forming the oxide when producing hermetic seals with glass. I was heavily into Sam's Laser FAQ when I was about 11 (or something around that age) and they'd always be going on about glass work - amongst other strange (and very interesting to me) things, like high vacuum or high voltage gear.

I have a really nice oxy/acetylene torch that I bought when I was about 14, with all my pocket money. The whole kit cost something like $600 at the time. That was a lot of birthday and christmas gifts saved up over years. I've heard about using polarized filters for strain observation and annealing by hand, but even with the filters I wouldn't trust the latter.

So the main thing stopping me from having a go is the kiln. I could build one, as I've also spent years reading around casting metals (like iron) and have built a high temperature furnace before; the annealing temperatures for glass would be eeeeeasy (if you don't believe me, try cutting near pure alumina insulation first ). But I don't have anywhere to put one at the moment.

Just as I was feeling all sad about that, I had a brainwave. How's about blowing hot air through the glass with a modified heat gun? The glass could be wrapped in glass wool for insulation and the cooling period set by PWM of the coil. Or fill the glass with something that'll conduct heat, insert some nichrome wire and wrap in wool?

Either way, I doubt the owners of my current home would appreciate me firing up acetylene fueled welding gear at the moment.

Peach I see now.. but plating is not necessary since tungsten is inert enough, for such applications, even if the starting acetone contains some water, the forming acetic acid would not attack the tungsten (I think, I always use dry acetone though)

The glassblower did not used another type of glass to wet the electode, he showed some electrodes to me which was sold pre-wetted with some other type of glass, but he rather made new ones on his own instead of using the ones at hand, I do not know why.. maybe he likes challenge

Tungsten rod of 1mm diameter far enough for a lamp as far as current is concerned, but take care not to break it.. tungsten is rather fragile.

After the glasswork there was a rather thick oxide layer on the tungsten which was as solid as glass, also take care not to break the rod while you are removing it.

I know 30 dollar is not much, maybe I should ask him to make some for sale.. pity that there would not be a big market for them in my country

Quote: Originally posted by densest

@watson.fawkes - Schott 8448? Hmmmm.... thanks!

Quote: Originally posted by peach

You can't use acetylene even with the flame finely tuned?

Peach apart from my total inexperience in selling things, it would not be a bad idea after all. Selling glassware is not illegal, isnt it?

We should name the ketene lamp something else, I mean when I hear ketene immediately acetic andhydryde.. drugs and explosives springs to mind.. rather than amateur experiments. It should be noted however that it can open a new world for the home chemist, you can study a lot of catalytic reactions with it, e.g. dehydrogenating cyclohexane to benzene, or pyrolyse lighter hydrocarbons to aromatics, just to name some.

I am gona ask the glassblower when I meet him next time, if he made some spare lamps, should the need arise.

It would be nice to see other chem enthusiasts works, in pioneering home pyrolysis, I have not got much time to make experiments at the moment.. I never had though

Pyrolysis Lamp I would buy one.

Maybe some things could be simplified to make it easier/cheaper to make.

Quote: Originally posted by densest

@watson.fawkes - Schott has sent me to a fabricator. They don't sell in less than case or melt quantities which is not at all surprising. They do say that 8448 is very expensive. It sounds like it's about 10x - 20x borosilicate prices, which isn't surprising either, and if one only needs a cm or two per joint, 1-2m of small tubing goes a very long way. $3000 or so for a box of it is a bit much - I wouldn't use that much in several lifetimes, though I'd be willing to retail it for a suitable markup....

Quote: Originally posted by densest

"call for quote" = you can't afford it, you peasant... I hate "call for quote" - it usually means a company who wants to rape you for everything you have.

I have not been at him lately, and do not really know when I will.
Seeing that the acetic anhydride thread turned into a meeting place of glass blowers (and wannabees Why not make the whole upper part of a teflon block? This was my original idea in case of the glassblower could not make it out of glass. I would drill two small hole into the block which would be previously forged to fit in the large grounded female joint, then I would drill an another for a glass rod with a screwed end, it should work, teflon is smiling up to 450°C IIRC, keep the reflux high and It will keep smiling even at higher filament temps.

Teflon is an idea. I was just wondering about DIY'ing my own HF distillation setup using some.

I would worry about using PTFE around such a hot element however. It would need to be a decent distance from the walls to avoid melting them.

I just did some quick searching and found one place doing 1.5" OD, 1" ID extruded virgin teflon tubing, it's $47.43 per foot ($284.58 for 6). The molded virgin teflon tubing of 1.5"OD has an ID of 1.25" and is $34.08 a foot ($204.48).

The extruded tubes go up to 3" OD

...OD......ID......code......per foot
1.500 1.250 KM-1116 $34.08
1.750 1.375 KM-1117 $55.42
1.875 1.500 KM-1118 $59.30
2.000 1.500 KM-1119 $81.80
2.250 1.500 KM-1120 $125.74
2.500 2.000 KM-1121 $107.24
3.000 2.000 KM-1122 $234.40

They also do a recycled version of teflon tubing. For a 1.5" OD 1.25" ID tube it's $21.76 per foot ($130.56 for 6).

However, a foot length rod of 1.5" virgin rod is $25.40 ($152.40 for six). Which actually makes it almost as cheap as the recycled, molded stuff, and you have the option of leaving ends intact, varying the wall thickness and such. Teflon also cuts like butter, so machining it out is not a problem. You could clamp the rods and use a spade bit to make you own closed end vessels for less than the tubing.

Having read the threads on the ketene furnaces, I'm also not use how productive the lamp is going to be. It might be a better idea to work on producing a mini, high temperature, cheap furnace.

I was thinking something much smaller than those linear tube furnaces could be make by spiraling some quartz tubing into a coil - rather than having it as a long rod. I've already found silicon carbide elements that are small and coiled, so they've fit a decent OD tubing inside without being long. The quartz could sit inside there and be replaceable with different sizes of tube. Or a cup sized crucible for high temperature solid work. Plus aerogel for insulation.

[Edited on 6-7-2010 by peach]

Having read the thread on ketene furnaces was the main cause why I chose the lamp instead of a leaking makeshift furnace

If you can spiral a quartz tubing, then to make a decent ketene lamp would be a joke for ya!

The quartz tube with grounded joints that magpie posted would be my holy grail, it is definitely sg that I cannot afford, to a 1m long tube like that with ns29/32 grounded joints I would give the ketene lamp and my stock of platinum electrodes too! sorry for being off topic but quartz tubes are my wet dreams ever since I took up GP catalytic reactions

Literature suggests that with copper tubing the conversion to ketene is almost 100%, cataytic effect is not mentioned IIR, maybe it can be heated more evenly than any other metal tubes, unfortunately at those high temps, your copper tube turns into black flakes very soon unless you are using reducing atmosphere.

I can see many flaws with tube furnaces (apart from the lower efficiency, yield, purity and lack of reflux) the main problem is leaking, you cannot make a reliable connection between metal and glass, even if you can, it will leak after a couple of disassembling.

Quote: Originally posted by Jimmymajesty

you cannot make a reliable connection between metal and glass, even if you can, it will leak after a couple of disassembling.

The head of the lamp can be made of teflon. I seal all the glass joints of the lamp, and every glassware with grounded glass joints with teflon tape, in case of the lamp after 5 runs, the tape was still tape, not a decomposed holed mass.. you can quote me on this

I also distilled H2SO4 at atmospheric pressure at the weekend, and the teflon tape remained teflon tape.. again

Watson there must be a reason that I cannot see home chemists running around with house keeper seals

Attached image excerpted from
A Dictionary of Applied Chemistry Vol 1 - T.E. Thorpe
Sidebar reference cited , 4 th entry down here _
http://www.lambdasyn.org/upload/acetylchloride-thread/beills...
1111384; Patent; Hoechster Farbw.; DE 210805;
Farbwerke Hoechst Aktiengesellschaft (Formerly) Vormals Meister Lucius Bruning
Patent in German available here _
http://depatisnet.dpma.de/DepatisNet/depatisnet?action=pdf&a...
Click Cancel in the file download window then click - [ Volldokument laden ] - at the upper right
wait a moment , type in requested text ( case sensitive ) click - [ G O ] - to download the full document



[Edited on 5-8-2010 by franklyn]

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Franklyn thanx for the info on acetyl sulphuric acid! I made some by leading ketene into sulphuric acid with continuous cooling. It is indeed very viscous, I poured it into a test tube and it did not even flow out of it when I turned the tube upside down for a moment, it was of honey consistence.

Could one make nitromethane with sulphoacetic acid by sodium nitrite? sorry to be offtopic

[Edited on 4-8-2010 by Jimmymajesty]

an alternate design requiring one joint, this is more effective imho, hey jimmy whats the second photo in your 'lamp running' doc, of?

Hmmm, glycine, on chlorination in aqueous solution (pH dependent), gives theoretical yields of Cyanogen Chloride (useful bit of information, no?, more here & here, but it is all over the web if you look).

Cyanogen Bromide, in conjunction with pyridine & acetic acid in benzene (as a diluent/solvent) gives good yields of acetic anhydride (see the other paper attached).

Anyone got any ideas on how to utilize this without having to isolate the fucking cyanogen chloride? I don't want to breathe it, touch it, or even stare lovingly at it, I just want from the first to the second flask

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Nope.

Also, I should revise my previous idea to carry a harsher warning: it might explode.

Has anyone successfully tried using Acetyl Chloride with Sodium Acetate to make Ac2O, if you could you please take me step wise

Well I guess by using Acetyl Chloride + Sodium Acetate = Ac2O is the most common.

But what I did not understand was,why use H2SO4, wouldn't the Acetyl Chloride and Sodium Acetate react without H2SO4.

If H2SO4 is still needed, does anyone know how much to use in Lab.

Too much Googling is bad for health

I think you're more likely to just get a mess of aldol condensation products.

Quote: Originally posted by mr.crow

I had a crazy idea, maybe someone can tell me if its feasible or not. Vinyl acetate can be reacted with acetic acid to make acetic anhydride and acetalydehyde, which escapes and drives the reaction forward. There is only a few mentions of this reactions on this forum but it seems to be possible.

Quote:

Prepare 100g freshly fused NaOAc and 65g S2Cl2. A small quantity of NaOAc is placed in a thin-walled glass cooled in an ice bath. To this is added some sulfur chloride, the mixtr is vigorously stirred w/a wooden spatula, not allowing the temp to rise. Then some NaOAc is added again, and the process is repeated several times until all is mixed in. The semi-liquid mass is transferred into a 1 liter RBF. The previous operation is repeated 4 times, so that 400g NaOAc and 260 g S2Cl2 total are taken into work. The RBF is then equipped w/a reflux condenser and gently heated on a water bath to ~80-85C. As soon as the rxn starts, the heating is removed, and in case the rxn gets too vigorous it's cooled w/cold water. After 20-30 min SO2 evolution ceases and the mixture is heated for 10 more min's on a boiling water bath. The rxn product is then distilled off under vacuum, then fractionally re-distilled at ordinary pressure, collecting the fraction boiling between 132-142C.

Partial success with acetic anhydride synthesis and a question

With 2 simple chemicals: sodium acetate and ammonium chloride!

When you mix it up and do a dry distillation, then a aqueous solution of ammonia comes over first, with some acetamide in it. But if all water is boiled, temperature rises and the destillation apparatus is then filled with smoke: a oily liquid floating on the top will come over. This is ethanoyl anhydride.

I prepare it by incident - if you read my topic "Synthesis of propanamide" then you will see the yellow propanoyl anhydride.

By heating it up with NaOH, the mixture became a solid, waxy compound when cooled. This is sodium propanoate. Furthermore, it is very soluble in diethyl ether - like propanoyl anhydride. Also, the density was established.

I still have a sample of it.

[Edited on 30-7-2011 by Bitburger]

Quote: Originally posted by Waffles SS

Did you test your Acetic anhydrid?really that is acetic anhydrid or acetic acid? I confirm that dry distillation of sodium acetate and ammonium chloride produce acetamide but i Doubt acetic anhydrid may produce by this method

Quote: Originally posted by Bitburger

With 2 simple chemicals: sodium acetate and ammonium chloride! When you mix it up and do a dry distillation, then a aqueous solution of ammonia comes over first, with some acetamide in it. But if all water is boiled, temperature rises and the destillation apparatus is then filled with smoke: a oily liquid floating on the top will come over. This is ethanoyl anhydride.

A hypothetical consideration is the reaction between acetic acid and acetaldehyde in the presence of a base. The last step could be achieved by a mild oxidation.

Click on the picture to enlarge

Quote: Originally posted by Bitburger

A hypothetical consideration is the reaction between acetic acid and acetaldehyde in the presence of a base. The last step could be achieved by a mild oxidation. Click on the picture to enlarge

Quote: Originally posted by shivas

Quote: Originally posted by Bitburger   A hypothetical consideration is the reaction between acetic acid and acetaldehyde in the presence of a base. The last step could be achieved by a mild oxidation. Looks too good to be true...I think it is more likely to get just acetate salts and water from this.

Acetic anhydride

Quote: Originally posted by madscientist

I'm theorizing that concentrated acetic acid could be dehydrated to acetic anhydride by mixing with concentrated sulfuric acid; then heating, and condensing the vapors, yielding acetic anhydride. Any comments or additional ideas?

Acetic anhydride

Quote: Originally posted by Waffles SS

Interesting method

I have an old Russian-English technical dictionary hidden away somewhere so I'll see if I can pick out the odd useful word or phrase here and there when I get a chance.

The H₂SO₄ patent mentions 'Noyes and Gobel, Americ. Soc. 44, 1922' which is a reference to the method of acetamide production, described at OrgSyn, and the HCl one makes reference to 130-142° but this could be a boiling range or reaction temperature - who knows?

I'm hoping the percentages in the 90's are yields though

I found an interesting patent on the oxidation of acetaldehyde process, which makes use of paraldehyde and a depolymerizing agent which means the reaction doesn't have to be performed under pressure to keep the acetaldehyde from evaporating.

http://www.google.com/patents/US2405471

I found that refluxing the pyrosulfate/propionate mixture (prepared as described above) in a sand bath on high heat for 1-2 hours, and then distilling, gives a more satisfactory yield, around 70-80% .

There is definitely some subvalent sulfur products forming. A sulfurous stench was apparent during and after the reflux and a yellow deposit formed in the condenser. A post-distillation rinse in bleach removed most of the odor, but not the yellow stain. Something is reducing the sulfate.

[Edited on 1-11-2012 by manimal]

Quote: Originally posted by S.C. Wack

As promised, Gmelin. Its enthusiasm is indeed from that JACS article. Band 61 B5, Seiten 125-6. 2.2.7.2 Thermische Zersetzung Die Zersetzung von AgCH3COO, die bereits von Chevenix [1] beim Erhitzen über einer Kerzenflamme (starker Geruch nach Essigsäure) beobachtet wurde, setzt bei 210°C ein (Dunkelfärbung), erfolgt hauptsächlich zwischen 220 und 240°C und ist vollständig bei etwa 300°C [2]. Beim Erhitzen im offenen Rohr oder im bedeckten Porzellantiegel werden als Zersetzungsprodukte im wesentlichen Essigsäure und Ag neben wenig C02 und C beobachtet entsprechend 4AgCH3COO ->4Ag + 3CH3COOH + CO2 + C [3 bis 5]. Von Kachler [2] werden als Reaktionsprodukte gefunden (in Gew.-%, nach vorstehender Gleichung berechnete Werte in Klammern): 64.61 Ag (64.67), etwa 26 bis 27 Essigsäure (26.95), 4.09 bzw. 8.42 CO2 (6.59) und 1.21 C (1.79). Auch bei thermogravimetrischer Untersuchung wird als Zersetzungsprodukt (bei 280°C) metallisches Ag und kein Ag2O erhalten [6]. Erfolgt die Zersetzung jedoch unter streng wasserfreien Bedingungen, so werden als Zersetzungsprodukte nur Ag2O und Essigsäureanhydrid erhalten nach 2AgCH3COO -> (CH3CO)2O + Ag2O. Bei der Zersetzung von 2.1077 g trocknem AgCH3COO bei 300 bis 400°C in einem Quarzgefäß unter Argon (1 atm) werden nahezu quantitativ Ag2O (96% der Theorie) und Essigsäureanhydrid (93%) gebildet neben wenig Ag (0.012 g) und CO2 (0.016 g) [7]. Die primäre Essigsäureanhydridbildung ist bereits von Kanewskaja, Schemiakin [8] bei Untersuchung der thermischen Zersetzung von AgCH3COO (im Gemisch mittrocknem Sand) unter einem CO2-Strom von 20 bis 25 Torr angenommen worden. Zwar fanden diese Autoren nur wenig Essigsäureanhydrid neben viel Essigsäure (entsprechend den früheren Angaben von Kachler [2] und Iwig, Hecht [4]), doch ist dies auf die leichte Hydratisierung des Essigsäureanhydrids zurückzuführen, die sowohl durch H2O-Spuren in dem schwer zu trocknenden Silberacetat als auch durch H2O erfolgen kann, das beim teilweisen Zerfall der Essigsäure gebildet wird. Für die vollständige thermische Zersetzung von AgCH3COO in Gegenwart von H20 muß auf etwa 230 bis 340°C erhitzt werden. Abweichend von der trocknen Destillation wird neben den Hauptprodukten der Zersetzung Ag, Essigsäure und CO2, kein Kohlenstoff gefunden [2]. Über die Darstellung von Ag-Schwamm durch Erhitzen einer getrockneten Paste von AgCH3COO im Tiegel auf 400 bis 500°C s. [10]. ... [1] R. Chevenix (Ann. Chim. [Paris] 69 [1809] 5/58, 19, 22; Ann. Physik 32 [1809] 156/201, 167, 179). — [2] J. Kachler (Monatsh. Chem. 12 [1891] 338/49, 340). — [3] K. Birnbaum (Ann. Chem. 152 [1869] 111/21, 119). — [4] F. Iwig, 0. Hecht (Ber. Deut. Chem. Ges. 19 [1886] 238/42). — [5] J. Redtenbacher, J. Liebig (Liebigs Ann. Chem. 38 [1841] 113/40, 131). [6] D. A. Edwards, R. N. Hayward (Can. J. Chem. 46 [1968] 3443/6). — [7] A. D. Kirschenbaum, A. G. Streng, M. Hauptschein (J. Am. Chem. Soc. 75 [1953] 3141/5, 3143).— [8] S. J. Kanewskaja, M. M. Schemiakin (Ber. Deut Chem. Ges. 69 [1936] 2152/7, 2154). — [9] V. I. Yakerson (Izv. Akad. Nauk SSSR Otd. Khim. Nauk 1963 1003/11, 1007; Bull. Acad. Sei. USSR Div. Chem. Sci. 1963 914/21, 916). — [10] T. Yamanaka, H. Nidorikawa (Japan.P. 6720 [1956] nach C.A. 1958 10462). And now, quite possibly pages of off-topic prattle on subjects that have already been discussed elsewhere: