Author Topic: direct transformation of aldehydes into nitriles  (Read 2252 times)

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Vitus_Verdegast

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direct transformation of aldehydes into nitriles
« on: March 25, 2003, 04:47:00 PM »
Direct transformation of aldehydes into nitriles using iodine in ammonia water


From Tetrahedron Letters, 42, 2001, 1103-1105:

abstract:
Treatment of aromatic, heterocyclic, aliphatic, conjugated and polyhydroxy aldehydes with iodine in ammonia water at RT for a short period gave the corresponding nitriles in high yields.

Formation of nitriles from the corresponding aldehydes is an important functional group transformation. Many methods involve the initial conversion of aldehydes to aldoximes, which are subjected to dehydration to give nitriles. Direct conversion of aldehydes into nitriles without isolation of nitrogen-containing intermediates has also been explored. In most cases, aromatic aldehydes are preferably converted to aromatic nitriles, whereas the transformations of enolizable aliphatic aldehydes often give unsatisfactory yields of aliphatic nitriles. The problem can be somewhat circumvented by using less available reagents (eg sulfimide) or unconventional approaches (eg microwave irradiation).

On the basis of NH3/oxidant protocols, we wish to develop a practical and enviromentally begign method for direct transformation of aldehydes into nitriles. We found that treatment of various aldehydes with iodine (1.1 mol proportions) in ammonia water (28% sol) at RT for a short period afforded the desired nitriles in very high yields (table 1).

According to previous reports we speculated that the reaction proceeded via oxidation of aldimine with iodine to give a N-iodo aldimine intermediate, which eliminated a HI molecule in ammonia sol. to afford the nitrile product. The aldehydes examined in this study included benzaldehydes, heterocyclic aldehydes, alpha,beta-unsaturated aldehydes, aliphatic aldehydes and saccharide aldehydes.


The following procedure is typical: Iodine (1.1 mmol) was added to a stirring solution of aldehyde (1 mmol) in ammonia water (10 ml of 28% sol.) and THF (1 ml) at RT. The dark solution became colorless (or light gray in some cases) after stirring for 5-73 min, an indication that the reaction was complete. The reaction mixture was charged with aqueous Na2S2O3 (5 ml of a 5% sol.), followed by extraction with ether (2x15 ml), to give a practically pure nitrile product.

CAUTION: It is known that iodine reacts with ammonia water under certain conditions to give a black powder of nitrogen triiodide monoamine (NI3.NH3). The dry powder explodes readily by mechanical shock, heat or irradiation. Although we did not have any incidents when handling the reactants in this study, one should avoid using excess reagent.  :P

In summary, a variety of aldehydes were succesfully transformed into nitriles by treatment with iodine in ammonia water. This method is simple, economic, and enviromentally begign. This method is especially useful for the transformation of water-soluble aldehydes such as carbohydrates.


Table 1


Substrate  -  Cosolvent  -  Reaction time (min.)  -  Yield

PhCHO  -  THF  -  30  -  96%
4-BrC6H4CHO  -  THF  -  45  -  95%
4-MeOC6H4CHO  -  THF  -  20  -  95%
4-O2NC6H4CHO  -  THF  -  30  -  96%
4-NCC6H4CHO  -  THF  -  10  -  89%
2-Furaldehyde  -  THF  -  7  -  88%
2-Thiophenecarboxaldehyde  -  THF  -  5  -  97%
2-Pyridinecarboxaldehyde  -  THF  -  15  -  85%
CH3(CH2)7CHO  -  THF  -  73  -  90%
t-C6H11CHO  -  THF  -  10  -  94%
Cinnamaldehyde  -  THF  -  5  -  96%
Crotonaldehyde  -  Et2O  -  60  -  57%
2-Deoxy-D-ribose  -  none  -  30  -  83%
Perbenzyl-D-glucose  -  none  -  30  -  85%




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Other than phenylacetaldehydes I don't know right away where it could be useful for, for our purposes, but it seemed such a beautiful and clean reaction, had to post it. You never know where it might come in handy.


Aurelius

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Ammonium Triiodide (misnomer)
« Reply #1 on: March 25, 2003, 06:09:00 PM »
As one with personal experience with this chemical, I cannot bring enough attention to the Caution portion of Vitus_Verdegast's post. 

CAUTION: It is known that iodine reacts with ammonia water under certain conditions to give a black powder of nitrogen triiodide monoamine (NI3.NH3). The dry powder explodes readily by mechanical shock, heat or irradiation. Although we did not have any incidents when handling the reactants in this study, one should avoid using excess reagent

just thought i'd include it in red to make it more noticable.  helps for those who like to skim and forget VERY important details.

lugh

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Easily Detonated Compound
« Reply #2 on: March 25, 2003, 06:15:00 PM »
Nitrogen triiodide can be detonated by a fly landing on the dry crystals  ::)


Vitus_Verdegast

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it's very dangerous when dry
« Reply #3 on: March 25, 2003, 06:36:00 PM »
Normally it shouldn't decompose when wet (still if handled carefully), but when filtered the solid dries out rapidly.


A friend of mine told me, when working night-shift in a lab, he and his collegues were getting bored and decided to make some nitrogen triiodide. They made at least half a pound of the stuff  8) . Not really knowing what do to next with it, they noticed that their solid was drying out fast, so they quickly placed it under the fume hood. It eventually decomposed violently, and the liberated iodine gave everything a nice yellow layer  :) . They had to spend the next hours cleaning everything with a thiosulfate solution. LOL!


Rhodium

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units?
« Reply #4 on: March 25, 2003, 06:40:00 PM »
Half a pound of that inside a lab would blow out the windows and damage the fume hood extensively... You don't mean half an ounce or something?

Vitus_Verdegast

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I thought he said half a pound
« Reply #5 on: March 25, 2003, 07:18:00 PM »
Thought he said half a pound,  it was most probably
weighed when wet, don't know much much it decreases in weight when drying .

They seemed to amuse themselves alot during these night-shifts, like sprinkling some sodium azide on the floor before the cleaning people arrived.

He also threw a sigarette away once in a sink where someone had accidentely poured away some CS2 (back in the seventies when smoking was still allowed).
::)


pHarmacist

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HAHAHA!
« Reply #6 on: March 25, 2003, 07:31:00 PM »
Was smoking allowed back then?? I thought that it was only allowed in the early 1900! When those old geezers from Astra that developed lidocaine smoked pipe at the same time as they poured Et-O-Et from a 10 L flask into a 5 L round bottom. Those were the times. I even have a picture of them pouring ether and smoking pipe! LOL!


Rhodium

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Self-experimentation leading to problems
« Reply #7 on: March 25, 2003, 08:02:00 PM »
Lidocaine? Is that Nils Lofgren? I've read some tales about his self-experimentation with lidocaine, he injected a dose into each of his fingers to see how large dose gave how much of an effect, and this resulted in ALL his fingers going numb, so he had to go home as he couldn't work anymore that evening... When he came home, he wanted to take  his keys out of the pocket in his pants, but he couldnt feel the keys, and even if he did, he couldn't grasp them tight enough to get them out with his limp fingers... This resulted in him having to take his pants off on the street outside his apartment and shake them out of the pocket. Naturally someone saw a him with his pants off in the middle of the street and called the police (this was in the 1950's or so), and he really had some explaining to do that evening...  ::)

pHarmacist

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Yeah, Nils Löfgren/Bengt Lundquist (1943)
« Reply #8 on: March 28, 2003, 10:55:00 PM »
a.k.a "Crazy Duo"  ;D

Especially "Nisse" always got in trouble. But he never menaged to blow up his own mustach with an classic ether explosion...