All organic chemists have experienced it. Your reaction is done and your transfer it to a separatory funnel with an aqueous and an organic phase. You do your shaky, shaky bit and the phases separate but it is impossible to tell where the phase boundary is. The problem is most commonly encountered when very dark phases are obtained but it can also occur with perfectly clear phases (see picture). The solution to this problem is very simple. Simply tip a clean NMR tube cap into the separatory funnel and observe as it settles on top of the bottom phase. Problem solved. D!
This blog is devoted to the discussion of all aspects of synthetic organic chemistry and related sciences. Curly Arrow is run by a synthetic organic chemist based in Copenhagen, Denmark. Contributions from readers are always welcome and should be emailed to curlyarrow@gmail.com
Wednesday, April 09, 2008
Friday, April 04, 2008
Dry Column Vacuum Chromatography (DCVC) - revisited
I get a lot of questions about Dry Column Vacuum Chromatography (DCVC) so I believe it is time for another post on the topic. DCVC is really taking off and the paper now has >70 journal citations.
Firstly, let me reiterate that like most things in life DCVC is best learnt by doing. Some of the questions I get are very detailed and specific and I can't provide clear cut answers. With experience you'll have an idea what to do and you'll improvise along the way and get it right.
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Q&A session with the true believers:
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(1) ...did you know that your paper had the"honor" of being "html-ed" by Rhodium....
- I didn't know that. I guess that everyone is purifying their illicit drugs in the garden shed using DCVC these days.
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(2) ...searching for a good source for the silica gel, right now it is about 4-5 times more expensive than our flash gel source...
- That is a huge difference. You have a very sweet deal on flash silica. In my case it costs about 40 % more but considering how little you use compared to flash it works out as a big saving. If you find a cheap source of DCVC silica please let us know.
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3) ...In the comments, you mentioned that you have done DCVC with 50-100 mg, and I was wondering what size of fritted funnel (frit diameter) you would use for that. Just calculating the size using the approximate amount of silica gel gives me something ridiculously small...
- The smallest sinter I use has a diameter of 1 cm. I have run 20 mg columns with 5 ml fractions on this column with no problems. Smaller than that would be impractical.
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(4) ...Also, just to help me chose the size [Column] if I'd get one or two funnels made, what diameter(s) would you use for say 500 mg to 5 g?...
- I currently have the following four columns: 1, 4, 6 and 8 cm. My favourite (that I use 80% of the time) is 4 cm. It's a good size to work with and it's good for 20 ml fractions. I'll do anything from 100 mg and up to 5 grams or more (depending on the separation) on that column. For your requirements I'd say get a 4 and 6 cm column.
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(5) ...frit porosities - the notation 1 - 4 is what is used in Europe, here in the US they have C, M and F, which actually don't directly correspond to the 1-4 sizes. "3" is a size where there is no direct equivalent, which is too bad because it seems ideal also to have in a flash column. The actual numbers are below, and I was a bit surprised because it seems that the P3 should clog up with time when using the Merck 15111 silica gel with its size range of 15-40 micron.
American standards - (Kimble & Corning, ASTM) nominal pore size, in microns, Medium 10-15 µm, Fine 4-5.5 µm
European standards - (Robu & Schott, ISO 4793) nominal pore size, in microns, P3 (P40) 16-40 µm, P4 (P16) 10-16 µm
- I had no idea about all this. Why on earth can't we just standardise these things. Anyway, thank you very much. I have always wondered exactly what the pore sizes represented.
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(6) ...What is a least polar couple of spots with delta Rf 0.05 (often called "eight", "8") which you would separate via DCVC?...
- I only do DCVC. If it fails the next stop is prep. HPLC. Fortunately it still hasn't failed. As with all normal phase chromatography super non-polar compounds separation sucks. That said I have often columned stuff (not super non-polar) that appears to be one compound by TLC and managed to get two compounds of the column. Behold the power of slow step gradient elution. I have achieved truly mind boggling separations over only 20 fractions. The worst column ever occurred 1.5 years ago. I kept getting a fair bit of each diastereoisomer clean but it took 5 columns to get it fully separated. Still it was easily done in one day by using the same column 5 times and only collecting 30 fractions per column.
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(7) Do you always start from heptane even for very polar mixtures?
- Yes! It gets the stuff off the Celite on to the silica and wets the column so that it runs well. Generally I do 4 x hexane, heptane or pet. ether first.
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(8) ...can I use toluene/ethyl acetate, chloroform/ethyl acetate or chloroform/methanol mixtures successfully?...
- Yes! You can even use really low boiling solvents such as acetone, dichloromethane, ether etc. but due to evaporation it is easier to work with higher boiling solvents. Where I work now hexane and heptane has been replaced with 40-60 petroleum spirit which I use for my columns without too much difficulty. Remember to have the pump exhaust in the fume hood, especially with the low boiling solvents.
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(9) ...Does it work substantially better [with Celite] than preadsorbtion on silica gel?...
-Yes! Celite is easier to handle and it doesn't affect resolution.
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(10) ...Does this trick with Celite work even if a sample is only sparingly soluble in an eluent?...
- It doesn't matter what your eluent is. Dissolve your compound in something polar that is easy to get rid of, for example ethyl acetate or methanol. Add Celite, concentrate in vacuo and load it on the column. Ensure that you have removed all solvent prior to loading. A lot of say methanol in the Celite will compromise resolution.
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I hope that helps. If you are new to this area please read the previous post and check out the following paper (a copy can be supplied upon request):
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Dry Column Vacuum Chromatography, D.S. Pedersen and C. Rosenbohm, Synthesis, 2001, pp. 2431-2434.
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Let me know if you have more comment, suggestions or questions. D!