Ethyl/Isopropyl Bromide preparation

I prepared ethyl bromide last night. The synthesis was quick easy and efficient, so I thought I would post my results.

Procedure
To a 500mL RB flask filled with 42mL of azeotropic ethanol, there was added 45mL of sulfuric acid (rooto drain cleaner) portion-wise with stirring. After the flask had cooled somewhat, 33g of ammonium bromide (reagent grade) was added, as the contents of the flask were swirled. The flask was put into an oil bath and set-up for simple distillation. The receiver was a 150ml beaker which was filled with enough ice water to partially immerse the drip tip of the condenser under water. The flask was rapidly heated and shaken periodically; a nice red-orange hue from Br2 quickly developed. Soon HBr vapors began fuming from the condenser, at which time a damp paper towel was draped over the receiver to absorb any evolved HBr. The fuming ceased after a few minutes and ethyl bromide began coming over. The ethyl bromide was collected for about 25 minutes until only a water miscible distillate could be collected.













Results
In total, 20mL of ethyl bromide was collected, corresponding to a 75% yield based upon the ammonium bromide. This synthesis was quick easy and high yielding. Throughout the reaction not a hint of ethyl bromide could be smelled, although I got a few whiffs of it during clean up.

[Edited on 7-7-2008 by Polverone]

When i have prepared halides from alcohols, i have used excess HX source and a i utilize a NaOH trap. A rubber tube from the top of the condenser to the a beaker of NaOH solution, no nasty fumes

I suppose in this case, the EtOH is easier to get a cheaper than the Bromide source so thats why you used excess EtOH.

This method works for all primary aliphatic alcohols, even better with aromatic but gets complicated / hindered with secondary and tert. So yes, it works with MeOH, from memory vogel describes the same method for halides.

Bromoethane a la Vanino

Isopropyl bromide -- 2 ways

But what if it was the ether i wanted to keep?
Only joking, have you since found any browning/disscolouration in your ethyl bromide? On one run when i went far too hot i recall that even after fractionation it went brown after several days, a second sulphite wash cleared it up. Nice photo essay, that saucepan has seen better days. did someone large sit on while it was sideways?





[Edited on 10-7-2008 by Panache]

Will It Work?

Quote:

Originally posted by Panache Quote: Originally posted by smuv it's been covered; wash with H2SO4; it will absorb the ether via multiple reactions; namely formation of an etherate and ethyl sulfates. But what if it was the ether i wanted to keep? Only joking, have you since found any browning/disscolouration in your ethyl bromide? On one run when i went far too hot i recall that even after fractionation it went brown after several days, a second sulphite wash cleared it up. Nice photo essay, that saucepan has seen better days. did someone large sit on while it was sideways? [Edited on 10-7-2008 by Panache]

Ethyl Chloride Prep

This procedure is a re-worked methyl chloride preparation and has been adapted to yield ethyl chloride.

Reagents
30mL Ethanol
40mL 31.5% HCl
60mL H2SO4 (Drain cleaner)

The ethanol and hydrochloric acid were mixed in a 500mL rb flask, and cooled in an ice bath. The Ice bath was brought outside and the sulfuric acid was added with the evolution of quite a lot of hydrogen chloride gas, even with slow addition. Next, everything was brought back inside, put on an oil bath and setup for simple distillation with a 100mL receiver. The receiver was half filled with water and the outlet stem of the vacuum adaptor was extended with pvc tubing so it lay just below the water in the receiver (to scrub HCl gas). To the outlet of the vac adaptor where one would normally attach a vacuum pump, a piece of silicon tubing was affixed which connected to an efficient ice condenser.


(Condenser that was used to recover the ethyl chloride. It was made from 1/4" (ID) copper tubing and an old coffee can. The outlet of the spiral is soft soldered to the wall of the coffee can)


(reaction flask and condenser)


(The EtCl condenser. The receiving test tube has an atmospheric vent and is sitting immersed in a basin of ice cold water)

The oil bath was gently heated, I unfortunately neglected to take any temp readings. During heating it was ensured that the contents of the 500mL flask maintained a slow regular ebulation (nothing excessive) and that the receiver had constant flow of bubbles coming out of the extended vacuum adapter stem. The hose from the vacuum adapter was periodically removed and the gas it was emitting cautiously wafted; this helped determine if ethyl chloride was being produced (it smells like you may expect something like a milder chloroform) or if only ether was coming over. The whole operation after setup took about 1.3 hours.

Note: After reading about the toxicity of ethyl chloride and knowing its history as an induction anaesthetic for a long span of time, the wafting operation was judged to be safe.

Results
The yields were not great; I never quantified them but it looks like 2.5mL thereabouts. The recovered ethyl chloride burned with a characteristic greenish-blue flame and emitted HCl gas. I think there was a lot of holdup in my condenser and if that got worked out yields would be better. A fair bit of EtCl seemed to leave uncondensed, and sometimes condensed in and was pushed up the atmospheric vent tube. Also probably setting everything up for reflux as opposed to distillation would increase yields, as unreacted ethanol/ether would not leave the reaction vessel; in retrospect I am not sure what compelled me to setup for distillation.


(recovered EtCl...looks like some copper filings made their way over too.)


(Flame test. Performed by shaking ice cold test tube with my thumb over the outlet; after significant pressure built up my thumb was removed and the effluent gas ignited.)

Conclusion
I am sure the yields for this method could be improved with subtle changes although may never approach those of the standard methods. I believe this could be an efficient way of producing methyl chloride as methyls are more reactive via SN2 mechanisms.

@Nicodem
The only thread you posted that is pertinent to my question was the first one. In this thread 'Per' mixed hydrochloric acid with ethanol and concentrated sulfuric acid and heated everything up; then stopped the operation because HCl gas was being produced; this hardly proved anything.

Maybe for you're reading.

Methyl Chloride prep from which this was adapted

US 2153170 Continuous RCl from ROH HCl + H2SO4

US 2091986

US 2091686 states: 'It is known that ethyl chloride may be produced by various procedures involving the use of ethyl alcohol as a starting material, for example, by a batch process in which dilute sulfuric acid, sodium chloride and ethyl alcohol are heated together. According to such a process, the ethyl alcohol and sulfuric acid are slowly introduced into a mixture of sodium chloride and dilute sulfuric acid, and the ethyl chloride evolved is passed through a reftux condenser which prevents the alcohol from escaping unchanged from the reaction vessel. This type of process has the disadvantage that a considerable time, generally about forty to fifty hours, is required to finish one batch.'

[Edited on 26-7-2008 by smuv]

Ethyl Bromide synthesis

Molar Weights of reactants:

H2SO4 Molar mass 98.08 g/mol

NaBr Molar mass 102.894 g/mol

EtOH Molar mass 46.07 g/mol


Products
----------
C2H5Br Molar mass 108.97 g/mol * .5150 = 56.1195

H2O Molar mass 18.01528(33) g/mol * .5150 = 9.277

NaHSO4 Molar mass 120.06 g/mol

Reaction:

NaBr + H2SO4 = NaHSO4 + HBr
HBr + EtOH = EtBr + H2O

23.67ml or in other terms 30 grams of EtOH was placed into a cold water bath and 130 grams of 44% H2SO4(Liquid Lightning MSDS) was added slowly via dropper syringe over a 10 minute period in order to keep the temperature down.


While waiting for the flask to once again reach ambiant temperatures I weighed out 53 grams of Sodium Bromide(Brom Start MSDS) and prepared for addition.


After evolution of heat some 15 minutes later or so the flask was placed in an ice bath followed by the slow addition of Sodium Bromide. The mixture quickly took on a red orange color with some Sodium Bromide resting on the bottom.


The flask was allowed to set for 15-20 minutes and the arranged for simple distillation.



The reciever flask was filled about a quarter of the way full of cold spring water and as you can see in the picture above the recieving flask was placed in an icebath as to not allow the formed Ethyl Bromide to evaporate.
After reaching 58*C at the still head the formed Ethylbromide started to distill over pretty rapidly and the contents of the flask boiled rapidly. The EtBr droped to the bottom of the reciever with a milky white color. This was sustained for about 25 minutes at which point the rapid frothy boiling stopped and the color of the mixture was not noticebly darker. The sound the boiling made now was completely different and unusual. Everytime a bubble would form it would do so with a sharp tinny sound to it. It sounded as though it was being boiled in a metal container but I think this may due to the EtBr forming and rapidly vaporizing in the solution resulting in the strange sound because the bubbles where forming in the middle of the flask instead of around the sides like normal. It was at this point that the distillate started to take on a slightly orange tinge to it and the distillate took on a dirtier look to it no doubt carrying some EtOH with it as it made the top H2O layer slightly milky looking until more H2O was added to crash the EtBr out. The remainant of the reaction vessle has now lightened to a pale shade of yellow/orange and after cooling the Sodium hydrosulfate crystalized filling up the vessle.

After about 45 minutes to an hour the distilling was stopped because a bad lightning storm was comming and I am working right next to a large open garage door. The distillate was noticed to be only slightly more dirty the the first half of distilling so I just decided to mix both together. This is where one of the notable things happened. When the two distilling flask where added together as soon as the cloudy EtBr hit the air it would release puffs of dense white vapors with the consistancy of smoke. Im pretty sure that its HBr fumes after watching the final product clear up after sitting for an hour.

The yeild prepurification yeilded roughly 30ml or 44.1 grams equaling 78.5% yeilds with more then likely a small amount still in the mother liquid of slightly milky white EtBr with exact weight still to be determined.



I post more tommorow after I am hopefully able to purify it. But the initial conclusion is that this is a very easy synthesis to pull of and the yeilds are not bad either. As smvu said there was no hint of odor until the end and I started to move the contents between flask. After speaking with Arrhenius recently I decided to add excess H2SO4 and EtOH to the mixture to ensure complete digestion of the NaBr.

Sedit, are you sure you didn't get those images off a DEA website?

Save up for some glassware dude! EtBr is less toxic than MeI, but still...

I'm looking forward to your next installment: the beer bottle Grignard.

[Edited on 8-7-2009 by entropy51]

LOL, what are you saying entropy.

Brother im a single father with 3 young children that warrent my money much more then a set of glassware. I would have had one sometime ago but a hobby can never take precedence over them.

I started playing with chemistry when I was a kid unable to buy my own stuff so I chose to make what I needed and got pretty good at it. Now that im older its common habit and theres a good chance I would be lost with a good set of glass. The idea of toxicity may play into my favor because I am so worryed about it that someone using proper equipment maynot focus on safety half as much as I do. The synthesis was performed right next to a giant open garage door. Once every thing was running smoothly I kept my distance. Gloves and long sleaves where worn the whole time even though it was 97 degrees outside.

Thats the reason that I have never posted any pictures and such before because people have gotten in there heads that fancy glassware , rotary evaporator, ect... make you a great chemist. I do believe they can make you a better chemist due to ease of use but being able to afford Sigma Aldrich does not make someone a chemist. Being able to perform the work and idealize the synthesis before hand gives someone more of an advantage then money not to mention the amount of fun that you get along the way. Lets face it, Im not the only fellow here that don't have good glassware but I may be the only one that don't mind showing it.

Beer bottle Grignard eh... Hmm now thats an idea. I got the Ethyl bromide and if im able to get the Grignard to take off in my setting I don't want to here complaints from anyone how hard it is to work with a Grignard reagent.


Reaction note:

Overnight the EtBr cleared up nicely to a very slightly tinted yellow fluid.

Quote: Originally posted by Sedit

Does anyone know how much H2O this reaction can tolerate? It seems that the more there is the more the HBr will stay in solution but im sure there has to be a point where the dilution works against you more then the small amount of HBr loss right?

"I've shaken bromine with conc. H2SO4 in a sep funnel, it's really no problem."

You get the Great Big Brass Pair award for that GC

It's not cheap, but FEP tubing is magical. Resistant to just about everything. I've only seen it ruined by high temperature oleum fumes.

Fleaker will back me up on this

[Edited on 7-11-09 by UnintentionalChaos]

1-bromobutane

Yesterday I got 4 hours of free access to the school lab. I figured I'd make some 1-bromobutane (butyl bromide).

Pictures:

The setup. The addition funnel contains concentrated sulfuric acid.




You can clearly see the HBr fumes filling the apparatus and the deep red color of bromine, due to oxidation by the acid:





Here the two layers can be seen after the reaction. Top layer: BuBr and bromine along with unreacted 1-butanol. Probably some dibutyl ether too.
Bottom layer: H2SO4, NaHSO4, water.





I didn't have time for the workup, I'll probably do it on tuesday. The reaction mixture is sitting in a separatory funnel in a fume hood over the weekend.

[Edited on 8-5-2010 by Lambda-Eyde]

I never said the bottom was pure which given the densitys defined could account for the added bulk. Its easy enough to test. so ...... take it from there and prove me wrong. I more thne likely am... iv mastered being wrong

Quote: Originally posted by Sedit

I never said the bottom was pure which given the densitys defined could account for the added bulk.

Propyl Bromide synthesis

Well after re-reading this thread and seeing all the good work done I thought I would have a go at n-propyl bromide. My Inspiration for this synthesis was this thread, and it has been a while since I have contributed anything meaningful.

Before I start I feel I should post a brief waring.
Be careful propyl bromide is an alkylating agent, and probably carcinogenic.


Reactants

n-propyl alcohol 60.10gr
sulfuric acid 98.08gr
potassium bromide 119.00gr

So first I added the KBr to a 3 neck 500ml rbf. The KBr was really lumpy so I added 20ml of tap water to help break it up. Next I added all the n-propanol to the mix, next I took a 125ml addition funnel and placed it in the middle neck of the flask. I poured the H2SO4 into the funnel and adjusted it so that it took 1hr to add all of the H2SO4 into the mix. Once the acid was mixed in the solution sat for about an hour. Then I stoppered off two of the necks, and in the third I placed a 200cm vigreaux column. I only had time to run it for an hour which normally would be enough, but it was super super windy so the column got cooled really easily. Anyway the I ended up with 50ml of liquid, and I think there is about 2ml of water in it. So I may try see if I can distill any more propyl bromide from the original mix, but I doubt that will yield anything more.
So in conclusion I would say this works pretty well, but the yields are kind of low. It would probably work better with pure HBr, but that would require another step which can complicate things.
And now for the pics!





Here are the reactants from left to right, sulfuric acid, potassium bromide, and n-propyl alcohol.


Here is the finished product.


Sorry I dont have any other pictures, I actually took alot but for some reason they wont load into the attachment thing. These two were the only ones that worked. So use you imagination to get the rest.

When I made the EtBr I added the H2SO4 first which forms an exothermic reaction with the alcohol atfirst then after this calmed down and I had EtSO4 <=> H2O IIRC I slowly added the NaBr after chilling the -OH acid mixture. I know there was a reason for me adding the acid first but I can not for the life of me remember exactly what the mechanics behind it was but perhaps others could review my post or explain there own reason for why I did this

Sorry my memory these days is short lived to say the lest.

Quote: Originally posted by mnick12

Then I stoppered off two of the necks, and in the third I placed a 200cm vigreaux column.

Finally got done with the synthesis today. The result what somewhat disappointing, but not surprising.


Here's the reaction mixture in a separatory funnel after standing over the weekend. Note the large amount of crystals and the dirty upper (!) organic layer.




A picture of the first distillation setup.




Two of the receiving flasks.





Seems like I forgot to take any more pictures. They wouldn't have been any spectacular anyways.

Before beginning workup of the crude distillates I decided to add the batch that came over at 112-124*C to the total distillate anyways in hope of extracting any BuBr present.
The distillate was first washed with 100 ml of water, then 100 ml 36% HCl, 100 ml water again, then 100 ml sodium carbonate solution, and 100 ml water again. This was done according to Vogel's recommended workup method for BuBr synthesis.

To the thoroughly washed organic layer was then added about a teaspoon (I feel like a briton ) of CaCl₂. It was dried for about twenty minutes with occasional swirling; no clumping was observed. It was then filtered straight into a 100 ml round bottom flask and distilled in a dry, clean distillation setup into a 50 ml flask. The first distillate came over at 99-102*C. The distillation was stopped when the temperature rose to about 110*C, and it was cut off before any of it could contaminate the previous batch.

The distillate was perfectly clear and didn't smell too strongly. It was vaguely remniscient of methylene chloride, but had a more sickening smell. Not very sweet.

The distillate occupied 19 ml and weighed in at 23,5 grams, giving a specific gravity of 1,24. This is close enough to the specific gravity of 1-bromobutane; 1,27 (Wikipedia).

The yield, however, was rather lousy. Basing the calculations on the amount of 1-butanol used, 55 ml, or 0,6 moles, gives a yield of 29 %, not very spectacular. Vogel quotes a yield of 95 % for the same synthesis, although at a 2x scale.

I can already see a number of reasons for the bad yield. Firstly, I used equimolar amounts of 1-butanol and HBr (NaBr). I should have used an excess of NaBr when taking in consideration the losses due to evaporation of HBr during the synthesis and oxidation of the bromide ion. I rushed the synthesis too much. I was kinda in a hurry when I did it and used much heat and refluxed the reaction mixture for only 70 minutes. The addition of the sulfuric acid was done all to quickly during the synthesis due to the time strain, causing oxidation of bromide which could be observed. This probably resulted in some dibutyl ether too.

I had to rush the synthesis somewhat because neither leaving the setup hot nor missing my bus home were options I wished to go for.

[Edited on 11-5-2010 by Lambda-Eyde]

[Edited on 11-5-2010 by Lambda-Eyde]

Ethyl Bromide

I just ran vanino's prep for ethyl bromide. I ultimately intend to use it in a grignard reaction with ethyl acetate to prepare 3-methyl-3-petanol.

In a 500 mL roundbottom, I added a magnetic stirbar and 38 mL of H2O + 55 mL of 95% ethanol. This flask was submerged in a beaker with icewater and using an addition funnel I added 55 mL of concentrated H2SO4 with constant magnetic stirring. Upon completion I added 98g of NaBr. The flask turned orange upon the addition of the NaBr. I setup for simple distillation using a seperatory funnel containing about 20 mL of H2O as a receiver. I cooled my condenser with Ice Water.



I set my variac to 25% power and started to distill my product.



At the end of the distillation my flask filled up with a white gas (SO2?) and I dropped the mantle at this point.



Here is my seperatory funnel with a cloudy Ethyl Bromide on the bottom layer and H2O on the top.



Next step is a 3 step workup involving a shake with 10% NaOH solution, followed by a shake of 10% Sodium Thiosulfate solution and then a dry on CaCl2 to remove water and any ethanol that might have distilled over. I don't care about any ether as I am using this for a grignard and thus I am eliminating the concentrated H2SO4 workup described in Vanino.

Will report my yield when I finish the workup.

[Edited on 5-11-10 by rrkss]

I performed the bromethane synthesis about two weeks ago, and as of now it has all evaporated. It turns out my bottle didn't have a good seal. Damn!

[Edited on 12-6-2011 by redox]

The same happened to my EtBr even though the bottle had a seal I wouldn't store it unless the bottle has a pretty hefty cap/seal, the seal on mine was a normal seal coated in teflon tape because I was worried about it dissolving the seal. I'll use all of it next time I make it, EtBr isn't something I want leaking into the air, even if it does smell awesome

Quote: Originally posted by bahamuth

Haloalkanes should be stored dry in my experiance, makes it so much easier to use is one thing. Usually store them with a piece of silver wool or precipitate copper powder (after prolonged drying with CaCl2 and redistillation) to capture any free halognes, atleast the alkyl iodides (which is all those I have), as I have seen heavy decomposition if left without silver or copper metal for prolonged periodes, even as I store them at -20 all the time.

Quote: Originally posted by redox

You like the smell of bromoethane? It smells odd/bad to me.

Quote: Originally posted by spong

Quote: Originally posted by redox   You like the smell of bromoethane? It smells odd/bad to me. Ohh it smells so sweet! Like the sweet smell from methanol or chloroform but stronger.

Quote: Originally posted by Dr.Bob

For those interested in preparing alkyl halides, the father of some of this chemistry was Max Gergal, who wrote a great book about his company, Columbia Organics, which is hard to find, but sometime available via Amazon or other sources. He describes some of his experiences making them along with the joys or running a small company. It's a hoot. http://www.amazon.com/Excuse-Would-Like-Isopropyl-Bromide/dp...

Quote: Originally posted by rodanid88

I tried to synthesize BuCl from BuOH, 32% HCl and 96% H2SO4. At the end of the distillation i got black tarry remainder in the RBF. Anyway the yield was very low (~30%), but it is not the main problem, because the process was not the best. I can only imagine that the H2SO4 was not pure enough. Thanks