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Topic: Proposed mechanism for dealkylation using TMSBr?  (Read 13927 times)

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Offline Kaladiscope

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Proposed mechanism for dealkylation using TMSBr?
« on: August 01, 2012, 06:25:39 PM »
I am looking for the mechanism of the dealkylation of esters using TMSBr.

Anyone has any idea where can I find a good source?

Offline Dan

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #1 on: August 01, 2012, 07:36:41 PM »
Well, TMSBr is a strong Lewis acid. What do you think will happen first in the mechanism?
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Offline nox

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #2 on: August 01, 2012, 07:40:04 PM »
Hint: Si is strongly oxophilic

Offline Babcock_Hall

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #3 on: August 02, 2012, 02:46:10 PM »
Hint:  The dealkylation is really a transesterification.

Offline Kaladiscope

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #4 on: August 02, 2012, 07:06:18 PM »
I guess that Si-Me3 will bind to one of the lone pairs of the oxygen in the carbonyl group. Afterwards the Br- will attack the methyl group (nucleophilic attack) generating then Me-Br. Addition of MeOH or water will just react with SiOMe3 generating HOSiMe3 and dealkylating the corresponding ester.

Is that right?

Offline camptzak

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #5 on: August 03, 2012, 01:50:00 AM »
Heres my attempt

The carbonyl oxygen attacks the TMSBr by Sn2

The pi bond of the carbonyl comes up to become a lone pair on the oxygen

The oxygen attached to the carbon chain forms a pi bond as the other pi bond leaves (octet resonance)

The bromine attacks the backside of the carbon chain by Sn2 and the transesterification is complete with trimethyl silicon in place of the carbon chain. and the carbon chain has been brominated.


close? right? completley wrong?

why is do silicon and oxygen form such a stable bond? I dont understand that. is it because it is in the 3rd energy level with lots of electron density to donate to the electronegative oxygen?
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Offline discodermolide

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #6 on: August 03, 2012, 02:18:11 AM »
Heres my attempt

The carbonyl oxygen attacks the TMSBr by Sn2

The pi bond of the carbonyl comes up to become a lone pair on the oxygen

The oxygen attached to the carbon chain forms a pi bond as the other pi bond leaves (octet resonance)

The bromine attacks the backside of the carbon chain by Sn2 and the transesterification is complete with trimethyl silicon in place of the carbon chain. and the carbon chain has been brominated.


close? right? completley wrong?

why is do silicon and oxygen form such a stable bond? I dont understand that. is it because it is in the 3rd energy level with lots of electron density to donate to the electronegative oxygen?

In the deprotection of an ester with TMSBr, the oxygen of the ester group (COOR) is attacked by the Silicon to give a COOSiR+ species. Then the bromine, Br- attacks the CH group in the ester to give the alkyl bromide and the silylated ester.
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Offline camptzak

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #7 on: August 03, 2012, 02:28:36 AM »
Heres my attempt

The carbonyl oxygen attacks the TMSBr by Sn2

The pi bond of the carbonyl comes up to become a lone pair on the oxygen

The oxygen attached to the carbon chain forms a pi bond as the other pi bond leaves (octet resonance)

Thanks!

The bromine attacks the backside of the carbon chain by Sn2 and the transesterification is complete with trimethyl silicon in place of the carbon chain. and the carbon chain has been brominated.


close? right? completley wrong?

why is do silicon and oxygen form such a stable bond? I dont understand that. is it because it is in the 3rd energy level with lots of electron density to donate to the electronegative oxygen?

In the deprotection of an ester with TMSBr, the oxygen of the ester group (COOR) is attacked by the Silicon to give a COOSiR+ species. Then the bromine, Br- attacks the CH group in the ester to give the alkyl bromide and the silylated ester.
"Chance favors the prepared mind"
-Louis Pasteur

Offline discodermolide

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #8 on: August 03, 2012, 02:34:12 AM »
The Si-O bond is very strong, so there is your thermodynamic driving force.
have a look at this link.
http://www.minsocam.org/ammin/am65/am65_321.pdf
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Offline orgopete

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Re: Proposed mechanism for dealkylation using TMSBr?
« Reply #9 on: August 04, 2012, 07:48:55 AM »
The Si-O bond is very strong, so there is your thermodynamic driving force.
have a look at this link.
http://www.minsocam.org/ammin/am65/am65_321.pdf

This is a useful paper to read and at least in part to understand why Si-O bonds should be strong. I say in part, because I do not agree with Pauling on some of his explanation. None the less, there is data which shows the Si-O bonds are 20 pm shorter and as calculated by Pauling, contain about 50% double bond character.

For me, this is an interesting topic and one needing explanation. For me, protons are positive and electrons negative so the notion that silicon or oxygen contain partial charges does not explain how or why an Si-O bond should be stronger. The inverse square law and the bond angles are consistent with strong bonds. Since several third row elements have expanded octets, it appears consistent with this trend.

Let me further point out that H2S is more acidic than H2O. If this is a result of a greater nuclear charge effect, then how might silicon differ from carbon? (That is a rhetorical question for those willing to think outside of the textbook.)
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